Classic Audiobook Collection - The Romance of Mining by Archibald Williams ~ Full Audiobook [history]
Episode Date: February 15, 2024The Romance of Mining by Archibald Williams audiobook. Genre: history Any writer on mining in its general aspect is, when casting about for a starting-point, driven to express what others have said b...efore him-that the history of mining is the history of civilization. The following pages, while touching on the chief branches of the mining industry, must necessarily omit reference to many of the great treasure-houses of the world. Special prominence has been given to the precious metals, because their discovery and working has witnessed the most stirring scenes in mining life. We have the whole world to roam over; so excursions are made into those spots where typical or prominent instances of mining of various minerals are to be found. For ad-free listening try our premium subscription Chapters (Approximate) (00:00:00) Chapter 01 (00:23:36) Chapter 02 (00:46:23) Chapter 03 (01:31:54) Chapter 04 (02:00:25) Chapter 05 (02:19:19) Chapter 06 (02:44:14) Chapter 07 (03:21:24) Chapter 08 (03:58:58) Chapter 09 (04:57:23) Chapter 10 (05:11:13) Chapter 11 (05:25:46) Chapter 12 (05:49:16) Chapter 13 (06:13:05) Chapter 14 (06:54:47) Chapter 15 (07:15:03) Chapter 16 (07:44:31) Chapter 17 (08:22:03) Chapter 18 (09:00:37) Chapter 19 (09:31:28) Chapter 20 (09:43:16) Chapter 21 (10:03:29) Chapter 22 (10:17:34) Chapter 23 (10:34:59) Chapter 24 (10:47:56) Chapter 25 Learn more about your ad choices. Visit megaphone.fm/adchoices
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The Romance of Mining by Archibald Williams
Introductory
Any writer on mining in its general aspect is,
when casting about for a starting point,
driven to express what others have said before him,
that the history of mining is the history of civilization.
If we try to penetrate into the period
when metals were unknown to,
or at least unused by man,
all we find of his arts is a few rough scratches on a cavern wall
and some stone implements of defence and offence.
So we call the era, covering thousands,
tens of thousands of years maybe,
during which the cave-dweller depended for his livelihood
on his power of fashioning flints,
the Stone Age,
synonymous in our minds,
with a dark, brutish existence of a creature
just sufficiently more intelligent than the beasts of the field
to survive their attacks and to live by destroying them.
The ancients who looked backwards rather than forwards
in search of an ideal existence
spoke of the dawn of history as the golden age,
the epithet being used metaphorically.
All was then peace, plenty and content.
Strife between man and man,
between nation and nation, had not yet arisen to mar human existence.
Arguing from the social deterioration of their own time,
they concluded that far back in the past, men must have been of a far nobler stamp,
and their lot cast in much more pleasant surroundings.
Today we know too much to take refuge in such imaginations,
while deploring the decay of time-ordered institutions,
and the virtues of the good old times, we look confidently forward,
and, were we given the choice, should not like to antidate our existence by even 100 years.
From the vantage ground of knowledge, we see that mankind has steadily advanced in spite of temporary setbacks,
fighting circumstances even more successfully by means of the weapons
which the arts and sciences enable him to forge.
The importance of metallurgy is shown by the very fact that,
when we wish to divide human history into a few periods,
we fly to the metals as the standards by which to measure man's industrial development.
The copper age succeeds the stone age, then tin is found, and the bronze age begins.
After the bronze, the iron age, and, last of all, we have the steel age, in which we live.
though even at the present day there are in different parts of the world,
race is still passing through the earlier ages.
The metals serve three important ends.
They supply man with the means of making life beautiful, secure, and comfortable.
The first metal to be discovered was probably gold,
which exists in its native or pure state in many countries,
lies on the surface, attracts the eye, and can be easily secured.
What nation first set value by gold we cannot say,
but we may reasonably conjecture that the primitive folk, even of the Stone Age,
may have beaten this metal, valueless for tools or weapons, into decorations,
so that, in one sense, the Golden Age was contemporaneous with the dawn of civilization.
The value of gold arose only when other metals had been added to the list of those mined and worked.
Copper, also found pure, though usually combined with other elements, must have been known to man at a very early date.
By itself, its uses were limited, but when tin was discovered and alloyed with it, the manufacture of bronze altered the history of nations.
The stone users were no match for invaders armed with bronze weapons tempered to extreme hardness,
and where stone encountered metal, metal won.
Civilisation had now taken a long stride forwards.
Bronze could be used for the arts of peace as well, being fashioned into tools,
agricultural implements, ornaments, and money.
So well did the alloy serve man that for long as well.
ages he was content with nothing harder and more stubborn. When the Spanish conquerors invaded
Mexico in the 16th century, they found the Aztecs quite ignorant of the uses of iron,
an ignorance which made possible the subjugation of a great race by a mere handful of bold adventurers.
After bronze came lead, silver, quicksilver, and zinc. Silver was probably discovered at the
same time as lead, since the two metals are often found together. This fact caused the alchemists
of the Middle Ages to regard lead as the mother of silver, and to endeavour to transmute the baser
into the more precious metal. Quicksilver, like lead and silver, is commonly found in combination
with sulphur, which can be driven off by heat. And, whether discovered accidentally or otherwise, was
used by the ancients as a solvent for gold.
Who first forged iron must ever remain a mystery?
Tubalcane is mentioned in the book of Genesis as,
quote,
an instructor of every artificer in brass and iron, end quote.
He may have lived 3,000 years BC.
The African natives seem to have been acquainted with the use of iron for time immemorial,
perhaps long before the days when, in Greece, iron was offered as a prize to the victor in athletic games.
The importance of iron, its utility for warlike, as well as peaceful purposes, soon won at recognition.
The early workers were defined under the names of Vulcan, Hephaestus, Thor.
Legends cling round the ancient smithes, associating the pioneer craftsmen in iron with supernatural,
powers. Wayland Smith of the Berkshire Downs has left behind him in the pages of Kenilworth,
a reputation for magic. The family names of Smith, smythe, Schmidt, Fabry, Lefevre,
and their equivalents in many other languages testify to the high rank of the armourer of the
Middle Ages. The late employment of iron is partly accounted for by the circumstance that,
Though one of the most widely diffused minerals, it is never found pure except in the form of meteorites,
lumps of iron which have suddenly descended upon the earth from the abysses of heaven.
The earliest iron tools were probably made from these gifts of the gods,
which have been found in various sizes ranging from a few ounces up to many tons.
Iron ore is so little suggestive of the metal it contains that an inextuals
an inexperienced eye would never connect it with the iron and steel of commerce.
And even when the relationship had been established by the ancients,
the extraction of the metal from its matrix was a matter of great difficulty,
on account of the numerous impurities of the ore and the high temperature needed for its reduction.
We may still see in various parts of the world,
China, Africa, the Malay Peninsula,
the primitive methods used to separate the iron,
a hearth blown by the winds or a pump of the simplest form,
and the beating on the anvil of a heated metal ball to squeeze out the impurities.
Iron thus obtained was very valuable.
Early warlike nations used it only for the business edge of their weapons,
which were otherwise of copper or bronze.
Just as bronze overcame stone, so iron vanquished bronze in battle.
The Romans, and later the alchemists, called iron Mars.
In the Bible, we read how the Philistines, after their conquest of the Israelites, carried off all the smiths.
Quote, there was no smith found throughout all the land of Israel, for the Philistines said,
lest the Hebrews make them swords and spears.
But the Israelites went down to the Philistines
to sharpen every man his share and his coulter and his axe and his mattock.
End quote.
Gibbon tells us that the Turks owed their position as a powerful invading nation
to the iron which, as slaves, they fashion for their lord,
the great Khan of the Geoogen.
To quote his own words,
Quote, their servitude could only last till a leader, bold and eloquent, should arise,
to persuade his countrymen that the same arms which they forged for their masters might become,
in their own hands, the instruments of freedom and victory.
They sallied from the mountains, AD 545.
A sceptre was the reward of his advice, and the annual ceremony in which a piece of iron was heated in the fire,
and a Smith's hammer was successively handled by the prince and his nobles,
recorded for ages the humble profession and rational pride of the Turkish nation.
End quote.
From that time onward, victory has declared for the nations
who have known how to combine discipline and strategy with invention in the employment of iron.
The Romans short-stabbing sword and protected shield against the shieldless barbarian.
the armor-clad Spaniard against the naked Mexican.
The firearms of Europe against the spear, arrow, and club of savages.
The armor-plated warship against the wooden walls.
In every case, iron suitably fashioned wins the day.
Even among highly civilized nations,
every advantage of metallurgical science is eagerly seized
to strengthen defenses and make weapons more deadly.
mere numbers do not now prevent defeat.
Steel plates must be of the toughest.
Cannon and rifles must belch out the greatest possible number of missiles
with the greatest possible accuracy.
The mechanism of war must be reliable in every way.
As Monsieur Simona wrote some decades ago,
quote,
In the contests which will unhappily long continue to take place,
Victory will henceforth generally remain with those who produce steel in the largest quantity and of the finest quality.
End quote.
Words which were echoed by Mr. Andrew Carnegie when he said that predominance must be in the hands of the nation which can manufacture the cheapest ton of steel.
Our age, the steel age, could not be better named.
whichever way we look steel confronts us we move over it shaped as rails or bridges it enters more and more into the construction of our houses the machinery which transports us from place to place clothes us feeds us caters for our luxuries is wrought from steel and the wealth of nations is derived chiefly from steel either directly or indirectly
hand in hand with steel advances coal, without which it would be impossible to make full use of the metal.
Steam power waits on both. In fact, the triumvirate of steel, coal and steam mutually support one another.
Steam raises coal. Coal smelts iron ore. Iron ore yields material for the steam engine, and so round the circle again.
So great is the part played by coal in modern civilization that the bottled sunshine of past ages
may claim almost equally with steel to give a name to the present period in the history of mankind.
Enormous, as has been the effect of iron on the fortunes of human society,
we cannot forget the importance of the intrinsically more precious metals.
Their unalterability, their beauty and their beauty, and their
variety have won them a place in our regard which, so far as we can see, nothing will ever be
able to diminish. Associated as silver and gold have been with princely magnificence,
they appeal to our aesthetic sense. The figures which stand out from history often,
in part at least, owe their fame to the glamour of great wealth. What more striking
personage has been immortalized by Holy Rit than King Solomon?
in whose days silver was nothing accounted of, whose palaces and thrones were decked with gold,
whose arguses sailed home laden with the gold of a fear. The precious stones and marvellous riches
which loom so largely in the Arabian Knights contribute as much as personal adventure to the
fascination of that book. Gold has been the magnet that has attracted the conqueror and the
explorer.
Time after time, India, the land of gold and diamonds, has had to bow to the invader,
informed through traveller's tales of the wealth of the country.
Gold took the Spaniards to Mexico and Peru.
Gold drew hundreds of thousands to California, Australia, South Africa, Alaska.
Unfurl the golden standard where you will, a huge army soon collects under the banner.
and, after exhausting the minerals, turns to the agricultural development of the country.
But for the reputed riches of Urmuz and of Ind,
exploration and colonization of the world by Europeans would have been delayed for centuries.
The advance of science has been so greatly stimulated by metallurgy,
and in turn metallurgy owes so much to scientific discovery,
that we can hardly conceive of the one without,
out the other. The alchemy of the Middle Ages, which vainly strove to change the baser into the
nobler metals, laid the foundations for modern chemistry, which helps, on the one hand, to trace
and extract metal from its ore, and on the other, shows how metal may serve mankind in a thousand
ways. The influence of mining on mechanical arts is no less striking. Out of the ladder and bucket,
has gradually been evolved the winding engine
which whirls men and oar at 20 miles an hour
from the depths of the earth.
The air or water-driven drill
has replaced the stone or bronze hammer
of the ancient miner.
Electric lamps have ousted, in large degree,
the candle and flickering oil boat.
Tramways do with ease
what once caused bucket-carrying men
much toil and pain.
The mechanical coal cutter
does the work of a hundred picks.
Dynamite blasts into fragments,
huge masses that formerly would have been cleft laboriously with wedges.
In spite of his conservatism,
the miner finally adapts to his use
any invention which has proved beneficial to those who work on the earth's surface.
And in return, he has shown how mountains may be burrowed through
for the passage of the locomotive.
The Simpland Tunnel and the prehistoric underground galleries of Italy and Spain
are more closely related than one may think.
To those who can see romance in industry, what a field does mining open?
The story of the metals is bound up with phenomenal individual success
and equally gigantic failures.
In a day, the pauper becomes a prince,
and he who fancied himself a prince finds himself a pauper.
A humanity which takes pleasure in risking wealth on the cast of dice,
on the running of a horse, or on the quotations of the stock exchange,
cannot be but enthralled by the sudden ups and downs inseparable
from the exploitation of new mines and virgin countries.
Who has not, at one time or another, felt the desire to take pick and shovel
and go on the trail of the miner in the hope that he may prove a marshal, a Hargraves,
a Godoy, a Gould, or a Drake.
From every corner of the globe come sensational, and often true,
stories of men who, in a lucky moment, have grasped a secret worth millions of pounds.
The world is large, and for every fortune that has been made,
a hundred still remain for the prospector.
Even when wealth has to be won by continuous and quite everyday work at the point of drill and pick,
the conditions of life are such as to appeal to the imagination.
The Great Brotherhood of Miners, the sturdy Cornishman, the lithe Italian,
the stubborn, superstitious German, the hardy sombreroed Asturian,
the Chilean Baratero, calm and impassive, the excitable Frenchman,
the thrifty, patient Chinaman, is surrounded by perils and hardships.
It was not without reason that the miners of the Haas peopled their minds with malicious gnomes,
and prayed to saints nickel and cobald before descending into the depths.
Fire, water, poisonous gases, falling roofs, breaking ropes and ladders,
other terrors which the miner faces without thought as part and parcel of the risks of his calling.
Yet for the outsider, the bravery and resource shown by the Toilers of the Deepest Deep
in the presence of disaster, helped to weave a romance as real as that of the battlefield.
And that, in spite of its hardships, mining has a fascination for the worker, is proved by the
unwillingness of a miner to relinquish his calling in favour of any other.
The following pages, while touching the chief branches of the mining industry,
must necessarily omit reference to many of the great treasure houses of the world.
Special prominence has been given to the precious metals,
because their discovery and working has witnessed the most stirring scenes in mining life.
As Mr. Fossett writes in his, Colorado,
quote,
There has been a fascination and romance attending the search of
the precious metals, and time intensifies rather than diminishes the feeling.
Under the magic influence of gold and silver discoveries, a spirit of enterprise has been engendered
that has brought about the accomplishment of results as unexpected as they were grand and wonderful.
The wilderness is peopled, states are founded, and almost an empire established where the
presence of civilized man was unknown but a few years ago.
The reader will also be glad to hear of the source and supply of some of the most valuable varieties of jewels,
round which romance clings even more abundantly than round the metals,
since individual stones have had their histories.
We have the whole world to roam over,
so excursions are made into those spots where typical or prominent instances of the mining of various minerals are to be found.
mining, here used in its widest sense, includes operations on the surface as well as those underground,
and extends to those substances which are extracted from the earth without recourse to shafts and tunnels.
Enter a jeweller's shop and take note of the minerals ranged around.
Could they speak what stories they might have to tell?
There is the gold of many countries, the silver,
of Mexico, Nevada, Spain, Bolivia, Mexico, the tin of Cornwall and Malacca, the copper of Lake Superior,
the platinum of Columbia or the Ural Mountains, the diamond of Brazil and Grecoaland,
the ruby of Burma, the turquoise of Persia, the emerald of Peru, the sapphire of Salon.
Even in an ironmongers, the metal displayed hails from many lands.
The British Isles, France, the United States, Germany, Austria, Sweden, Italy, Spain and Siberia.
In the stonemasons yard, English sandstone jostles Italian marble and scotch granite and Welsh slate.
On the grocer's shelves, English salt stands.
close to Sicilian sulphur.
Let us go and see how these diverse substances were discovered,
how they are one to the use of mankind,
how the people live who exhumed them,
and what are and have been the difficulties encountered
before nature's mineral riches are poured by land and sea
into the lap of civilization.
End of chapter one.
Chapter 2 with The Romance of Mining
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The Romance of Mining
By Archibald Williams
Ancient Mining
Features of Early Mining
Riches of the Ancients
The Egyptian Mines
the earliest European miner, the Etruscan mines of Campaglia, the Phoenicians, Zimbabwe, the Romans as miners,
the Romans in Britain, Aztecs and Peruvians, the development of mining methods, ventilation, gunpowder, hoisting devices,
comparative comfort of modern miners. Before embarking on detailed accounts of the various branches of mining,
As conducted today, we shall do well to consider briefly the earliest stages of the industry,
when it was being gradually evolved and organized by the old and great peoples of the earth.
Three facts seem to stand out clearly in respect of ancient mining.
One, that India was the center, at least in the old world,
from which radiated the first advances in the science of extracting minerals,
to pass successively through Egypt,
Venetia and the archipelago, to Greece and Italy, once they penetrated to Germany, Gaul, and the British Isles.
Two, that among the ancient's mining was not considered honorable toil, and therefore had to be performed by slaves.
Hence, a nation had to become a conqueror, before it could set up as a mine owner.
3. The gold was the medal to which the earliest miners turned their serious attention.
Copper mining second and tin third.
As we have already noticed, Iron made an appearance very late, when metallurgy had developed so far
that the Egyptians and other races were able to perform many operations with bronze tools,
which, for lack of knowledge, how to temper the copper alloy to a requisite hardness,
We could not imitate today without recourse to steal.
We may safely assume that mining was practiced in eastern countries
for three or four thousand years before the Christian era.
Gold, one from the earth by washing alluvial deposits,
just as is still done in many localities,
steadily accumulated in the royal coffers of a kingdom until,
in order to put it to some practical use,
it was fashioned into objects of worship or the paraphernalia of a court.
In Babylon, there were three great statues of beaten gold,
two of them 40 feet high, and the third probably of similar dimensions, though sitting.
Besides these, there was an altar, 40 feet long and 15 feet broad,
covered with gold plates and several massive bowls and sensors.
From the weights given, it has been calculated that the raw metal in these concerns,
constructions, weighed about 2,700,700,000 ounces, or about 11 million pounds.
We know, too, that Darius was able to ring a yearly tribute of over 2,500,000 pounds, out of his sap trophies.
David and Solomon devoted huge quantities of the medal to the adornment of the temple and the royal palace.
The Athenians reared over their citadel, an enormous golden,
ivory statue of the goddess Athene. In the new world, the same accumulation went on through the ages,
there being no gold currency to absorb the gold, so that the Spanish conquerors on their arrival
in Mexico and Peru found vast treasure with a desperate struggle for its ownership. It must not be
supposed that the old world as a whole, or even contiguous countries, kept abreast in the art of mining.
As we can see at the present time, some races have retained the most primitive processes, while others have advanced.
The Chinaman of the interior of China extracts his iron from its ore in the same way as his ancestors did before him for countless generations.
The rock drill and ponderous ore-crushing stamp exist contemporaneously with the stone hatchet.
Therefore, in speaking of ancient mining, we should remember that its development was local and spasmodic,
though the general tendency throughout the world was forwards.
We naturally look to the Egyptians for the earliest mining work that can be even approximately dated.
The copper mines of Sinai are the most ancient of which history makes mention.
According to documentary accounts, they were worked from 5,000 BC to about 1,200 BC.
There still exists the tunnels, furnaces, crucibles, and parts of the tools used by these toilers of the dim past.
That the Egyptians knew of iron thousands of years ago is suggested by sculptures of what are supposed to be iron smelting furnaces.
But as these particular sculptures do not date further back than 1500 BC, the introduction of iron wood, even if the treatment of that metal is indicated, still be very very very much.
greatly posterior to the mining of copper.
And we are left to wonder how the Egyptians carved the great granite blocks
that now attract tourists and crowds to the valley of the Nile.
The earliest European workings may have been the Spanish.
Among the copper loads of the Asturias,
human skulls of a prehistoric type have been discovered
near mining implements of Flint.
When metallurgy was dawning in the Italian peninsula,
The older Truskins drove galleries through the rocks of Campiglia in search of copper.
There are, says Monsieur Simonin, in underground life, excavations large enough to hold a six-storied house with ease.
These vast chambers communicate with each other by means of narrow galleries, or rather passages,
in which a person could scarcely crawl.
The barren rocks left as rubbish or waste in the excavations, have holdings.
hardened and become cemented together under the pressure of the overlying beds and by the earthy debris of the mine.
These artificial masses can only be broken by blasting, like those blocks of concrete which are thrown into the sea and the construction of breakwaters.
The wooden props are still in place, rotted or rather carbonized by a sort of slow decomposition of the vegetable tissue.
All the smell they give out may be recognized as that of the epicenter.
of green oak and the chestnut, which are always grown in the country. Fragments of vases,
lamps, and amphoree, which are found in the rubbish, are connected with the truscant art.
Wooders and bronze picks have also been met with, in the mines, affording proofs that these works
date from a period when iron was not commonly used for ordinary purposes.
Enormous masses of rubbish covered the flanks of the mountains when the ancient pits have been
opened, and over an extent of several miles follow two parallel courses marking the outcrops of the veins.
In the valleys there are still enormous heaps of cinders on the very sites of the ancient foundries.
Though these mines have not been worked for possibly 3,000 years, they show a comparatively advanced stage of mining art.
The very marks of the tools still remain in the rock, as fresh as if they had been made yesterday.
The Phoenicians played so important a part in the spread of civilization through the Mediterranean countries and even beyond the pillars of Hercules, as the ancients turned the Straits of Gibraltar by trading and exploiting the mineral deposits known to them that we may pay special attention to their operations.
Before the Phoenicians first visited Spain, the inhabitants had worked the silver, lead in copper mines of Welva, Clodova, civil.
and Balaga in the southern parts of the peninsula.
The Canaanites traders, getting access to the coast direct and to the inland regions,
generally called Tarshish by the Guadalcaver, drove a profitable trade with the natives in the
metals mentioned.
As soon as they had established themselves firmly, they either compelled the natives to work the
mines for them or imported slaves from their own territories bordering the Mediterranean.
They must have obtained huge quantities of metal if Diodorus of Sicily is not exaggerating when he states that even the anchors of ships returning from Spain were of silver.
A statement which reminds us of the silver cannon sent by Pizarro from Peru to Spain.
The historian says further that the avarice of the Carthaginians, Phoenicians, led them to seek for and work mines in all parts of the peninsula.
and that it was from this source they obtained the means with which to combat, and for a long period stubbornly resist, the ultimately superior forces of mighty Rome.
It is, unfortunately, impossible to distinguish the Phoenician from the Roman operations, which immediately succeeded them.
But we may be sure that many thousand tons of copper, tin, and silver, were extracted during the Punic occupation, the zenith of their activity,
probably being the period when Solomon sent his ships to Tarshish.
Naturally adventurous voyages, the Phoenicians coasted around the Atlantic shores of Spain and France,
and finally reached the westernmost part of England, where they did a brisk trade in tin with the savage cornishmen.
We shall refer to this fear of their activity more fully in a later chapter.
In Rhodesia, at Zimbabwe, are ancient ruins of great extent.
and old mines from which large quantities of gold were extracted by the people that raised the huge fortress there.
Legend has long associated this region with the Ophir of King Solomon,
and Mr. Ryder Haggard, in his King Solomon's mines,
has drawn an imaginative picture of the excavations driven through the mountains in the time of that monarch.
More recently, fact has succeeded fiction.
Mr. Theodore Bent, after a careful examination of Zimbabwe and its surroundings,
pronounced that during one period of its earliest history, the Phoenicians occupied Rhodesia,
and that to them are largely due the galleries and pits, which can be counted by the thousands all over the country.
The gold was not merely one from the outgrafts of veins.
Shafts were sunk to a depth of even 150 feet,
and levels were driven from there along the veins.
The Rhodesian miners also knew the use of fire to crack and splinter the rock,
before attacking it with tools.
They brought up the quartz, grounded in mills,
and washed particles of gold out of the rubbish and hollows,
still visible along the riverbed.
Bent found rows of crushing stones and water holes,
at which the African slaves were out their miserable lives.
The gold thus obtained was smelted in,
cast in soapstone molds for conveyance to the coast,
whence it probably went by sea to the Red Sea,
and overlanded to Palestine.
When at last the Phoenicians had to quit their South African colony.
They walled up the entrances to some of the mines before they went.
Outside others, heaps of courts stand stacked ready for removal.
Tools are found at the bottom of shafts, as if abandoned by the workers in a panic.
carries flint tools, stone axes, and wedges, as well as very ancient iron chisels, hammers, wedges, and troughs.
The quartz crushers are thrown down near their basins. A pile of skeletons at the Mundi ruins gives evidence of a flight or massacre.
Cakes of gold lying by their waist may once have been held in a belt.
In Europe, the Romans took up the Phoenician workings after the destruction of Carthage.
during their occupation of Spain, from 210 BC to about 425 AD,
they busied themselves with the mining of gold, silver, and copper.
Spain became the Roman Siberia,
to which slaves were sent by thousands to end their days in the mines.
Bolivius says that 40,000 men worked the mines of New Carthage alone.
From Pliny and Titus Livius,
we learned that 20,000 pounds worth of gold came annually from
the Iberian Peninsula. Little is said of the copper workings, though these, especially in the
Rio Tinto districts, must have been enormous. The heaps of slag and cinders which, near the
Rio Tinto and Tharsus mines almost rise to the dignity of hills, have been calculated to contain
upwards of 30 million tons of ore and rubbish. Gonzalo Taron, a Spanish expert, estimates that
took the labor of 10,000 slaves working for 45,000 days to amass this huge quantity of dump,
and that during the Roman occupation, over 10 million tons of copper were extracted from 12th mines.
The Romans drove miles of tunnels through the hills and hollowed our great chambers in the core body.
Their mining skill is suggested by the water wheels and other devices found in the underground workings,
and by the remarkable regularity of the excavations.
When Julius Caesar invaded England in the year 55 BC, he wrote,
They, the Britons, used brass money and iron rings of a certain weight.
The province is remote from the sea produced tin,
and those upon the coast iron, but the latter in no great quantity.
Their brass is imported.
After their experience of Spanish mines,
the Romans were encouraged to seek mineral.
treasures in Ultimatul. They had left traces of their activity in many parts of the kingdom.
In Cornwall, they extracted tin. In Northumberland, Derbyshire, Yorkshire, Cheshire, Nottinghamshire,
Shropshire, the wide valley, and the forest of Dean. They mined lead. Pliny, in referring to this
metal, says, it is extracted with a great labor in Spain and throughout the garlic provinces. But in
It is found in the upper straddle of the earth in such abundance that a law has been spontaneously made,
prohibiting anyone from working more than a certain quantity of it.
The mendip hills, Somersetshire, are pitted with Roman lead mines.
The slag left by the Romans has been resmelted in recent years and has yielded large quantities of metal.
Copper was raised near Oswestry, golden carmethyn,
iron in several counties. Rude furnishers and masses of iron slack have been found overgrown by peat or buried beneath
accumulations of soil. Roman mining in Britain reached a fairly high standard of excellence. In Cornwall,
there still exists an added or tunnel, driven from the bottom of a hill into a load to drain off the water.
The work is distinguished by the symmetry of the arch and the careful masonry of the stones which line it.
Passing to the New World, we find a few traces of distinctly ancient mining.
Until the coming of Europeans, the methods of extracting ore were mostly very primitive in both North and South America.
In the Copper Districts of Lake Superior, the Everritories used only stone hammers and perhaps bags of hide,
to remove the metal, hacked off the great lumps of it which here and there showed above the surface.
In Central America, tombs have been old.
containing stone chisels, awls, and polisher's, with which the old inhabitants of Panama
attacked the gold placers or surface deposits, ages before the arrival of the Spaniards.
The Aztecs of Mexico and the Peruvians had considerable knowledge of mining, though ignorant
of the uses of iron. With bronze tools, they borrowed into the hills and took out gold, silver,
tin, and copper in large quantities. Other peruvres,
Rubian methods, Prescott writes, they did not attempt to penetrate into the bowels of the earth
by sinking a shaft, but simply excavated a cabin in the steep sides of the mountain, or, at most,
opened a horizontal vein of moderate depth. They were equally deficient in the knowledge
of the best means of detaching the precious metal from the dros, with which it was united,
and had no idea the virtues of quick silver,
a mineral not rare in Peru,
as an amalgam to affect this decomposition.
Their method of smelting the ore was by means of furnaces built
in elevated and exposed situations,
where they might be fanned by the strong breezes of the mountains.
The subjects are the Inca's, in short,
with all their patient perseverance,
did little more than penetrate below the crust,
the outer rind, as it were, formed over those golden cabins which lie hidden in the dark depths of the Andes.
Both nations managed, however, to amass much treasure for their rulers.
When Cortez divided the spoils of Mexico, he had to deal with gold and silver plate worth
1,417,000 pounds, while Pizarro in Peru melted down 3.5 million pounds worth.
It is probable that the treasure is.
captured was but a fraction of the total, since the vanquished would have hidden many of their
precious possessions as soon as they found what the Spaniards came for. Under the conquerors,
European methods increased the yield of the mines so greatly that Spain took the foremost place
among the nations of the 16th century in wealth and power. The science of mining has advanced
gradually with the increase of mechanical knowledge, until the adventure of gunpowder,
and in many places for a long time afterwards, the shafts and levels were driven entirely by means of picks and wedges.
The labor must have been infinitely more tedious and painful than it is today, when, in spite of all our modern appliances, a minus life is one of the hardest possible.
As Dr. John A. Church has said, the old minds were horrible working places. The galleries were low, torturous, so poorly supported that accidents might be.
caving of the roof were probably frequent. They were lighted by pine knots or by lamps made only of
a clay saucer filled with ill-smelling vegetable oil or tallow, in which a bit of rush, pith or rag,
floating, served for wick, and they were without ventilation to carry off the dense smoke from these lamps,
and the effluvia arising from severe labor. Even after centuries of experience, when mining had become a great
industry, the condition of the mines was deplorable. One of the greatest hardships was the want of a
current of fresh air to reduce the heat of the galleries and provide pure oxygen for the workers' lungs.
In the 16th century, rough ventilating fans were constructed. The veins sometimes edged with feathers
to create a draft in the galleries. About the same time, pumps were installed to free mines of water,
a task previously only possible, and that on a very limited scale,
by the raising of buckets with windlasses or on men's backs.
We may suppose that gunpowder was not used below ground
until methods of ventilation were fairly perfect,
since its poisonous fumes would have rendered stagnant air,
quite unbreatherable for a long time after an explosion.
The latter still survives in many minds as the sole means of descent and assent.
involving an immense amount of extra fatigue.
Steam power only was able to give quick transit,
first in the man engine, such as still used in Cornwall,
and afterwards in the rope hoisted cage.
Steam was also harnessed to ventilating and pumping machinery,
and later to that for lighting.
Before explosives in steam,
modern deep mining would have been absolutely impossible.
Man now sinks shafts 5,000 feet down into the earth, and from the bottom burrows horizontally.
He sends copious currents of air to the lowest depths, pumps out the water, if need be,
and leads compressed air and electricity through a maze of pipes and wires to work machine drills,
which, in combination with high explosives, we lead the miner of a large part of the toil otherwise necessary to secure the minerals.
As we shall read in future pages, the underground workers of today have hardships and perils to encounter,
but in comparison with the surroundings of those who first explored the deep treasure houses of nature,
theirs is a comfortable and happy lot.
End of Chapter 2.
Chapter 3 of the Romance of Mining.
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The Romance of Mining by Archibald Williams, the El Dorado of the Great West.
The Sierra Nevada, the results of altering a mill race, first discovery of gold in California,
booty centered by the public, gold reached San Francisco, sudden rise in wages, scenes in
Frisco. Off to the diggings. The Mormons. The mining outfit. Scarcity of water. Disappointed hopes.
Placer mining. Pannning out. The sluice. Racial feeling. Hardships and disease.
Riotous extravagance. What the average miner got. Rough justice. Danger of wealth. Incredible selfishness. Trouble in San Francisco.
The Transcontinental Journey, what Mark Twain saw,
rapid increase in California's population,
the miners' restlessness, the sad results,
exhaustion of places,
hydraulic mining, gigantic flumes,
how gold is washed out by the hydraulic jet,
devastating effect on the country.
Parallel to the coast of Upper California,
at a distance inland of about 200 miles, runs the Sierra Nevada,
a continuous and lofty range marked by a line of dominant peaks,
many of which are over 14,000 feet high.
It has an average width of about 80 miles,
and its western slopes are more gentle than the eastern,
which abound in precipitous declines.
From the mountain's many streams hurry westwards
to join the main river called the Sacramento,
flowing into the San Francisco Bay.
On their way, these tributaries cut through mighty deposits of gravel,
which in the course of the ages have been detached
from the heights and distributed along the valleys.
From the latitude of San Francisco north to Oregon,
the strata of the range have received a liberal salting
with gold at the hands of nature,
and the water has separated to do that.
quantities of it from its bed, distrue it in the river courses and incultures through which streams no longer flow.
This huge or river is felt on the Sierra's western slope is the El Dorado of the West.
One January day in 1848, a Mr. Marshall was making alterations at his sawmill on the Americano's River,
which enters the Sacramento at a point where the town of the same name now rises.
The tail race of the mill, being too narrow to allow the water to run off in sufficient quantities to get full work out of the wheel.
He threw the mill wheel out of gear and suddenly let the whole body of water behind the dam loose into the race.
This operation considerably enlarged the narrow channel and a mass of sand and gravel was carried off by the force of the current.
Captain Sutter, a neighbor, thus related what followed.
to Dr. J. Turwood Brooks, one of the pioneer miners. Early in the morning, after this took place,
he was walking along the left bank of the stream when he perceived something which he at first
took for a piece of opal, a clear transparent stone, very common there,
glittering on one of the spots laid bay by the sudden crumbling of the bank. He paid no
attention to it. But while he was giving directions to the work,
having observed several similar glittering fragments.
His curiosity was so far excited that he stooped down and picked up one of them.
Do you know, said Mr. Marshall to me.
I positively debated with myself two or three times
whether I should take the trouble to bend my back to pick up one of the pieces
and had decided on not doing so.
When further on, another glittery morsel caught my eye,
the largest of the pieces now before you.
I condescended to pick it up, and to my astonishment,
found that it was a thin scale of what appears to be pure gold.
He then gathered some 20 or 30 similar pieces,
which, on examination, convinced him that his suppositions were right.
His first impression was that this gold had been lost or buried there by some early Indian tribe,
perhaps some of these mysterious inhabitants of the West.
of whom we have no account, but who dwelt on this continent centuries ago, and built those
cities and temples, the ruins of which are scattered about these solitary wiles. On proceeding,
however, to examine the neighboring soil, he discovered that it was more or less or riverous.
This at once decided him, he mounted his horse and rode down to me as fast as it would carry him
with the news. Captain Sutter was soon convinced that the specimen shown that an epic in California
history had been opened. Of course, the first thing for the two lucky men to do was to keep the
discovery to themselves. They visited the mill and poked about among the sand with such good results
that they soon had collected an ounce of the precious metal. The next day, they went further
up the stream and found that gold existed along the high.
whole course, not only in the bed of the mainstream, but also in the now dried-up
gulches and creeks leading into it. Indeed, gold appeared most plentiful in the ravines.
The captain's sutter picked out a dry gorge with his knife, a lump of solid gold, scaling nearly
one and a half ounces. Unfortunately for the discover and his friends, the mill workpeople
had sent in booty, a Kentuckian, suspecting that Sulfield.
something was up, talked the prospectors about, and searched for the object of their wanderings,
so that when they returned to the mill, they were astonished, not to say disgusted,
but the laborers running up with flakes of gold, which an Indian, who had previously worked in a mine in Lower California,
had immediately recognized as the true stuff.
The secret had thus become public property in a very few hours.
Such a piece of news soon spread and hard on its heels
came actual proof of its truth
in the shape of gold flakes sent down to San Francisco.
On May 8th, a man entered the town with 23 ounces of gold.
People at once began with one voice to talk of nothing
but the new places.
A Spanish term signifying spots
with gold is found mixed with alluvial deposit.
Parties were formed at once to visit the diggings
An individual started off alone with shovels, mattocks, and pans to dig the metal out.
The talks soon bred a perfect viewroar.
All the workpeople struck, out of 50 new buildings and course of construction,
only about half a dozen would not be roughed of artisans,
the majority of whom, together with lawyers, storekeepers, and merchants were bitten by the fever.
On many a door could be seen a paper bearing the legend, gone to the day.
diggings. Wages increased by leaps and bounds. The people who remain behind could ask their own
terms. Salesmen and shopmen got $2,300 to $2,700 a year, with board, and even boys received salaries,
which in the pre-mania days would have satisfied the heads of large departments. But while many
houses were being deserted, fresh inhabitants poured in by sea, many having come across the isthmus of
Panama to a point where they could take ship. Up sprang a host of canvas booths to accommodate
the newcomers. In the better parts of the town, stupendous taverns, gambling houses and other
buildings commanded huge rents, anything up to $100,000 a year. Skirting the beach,
writes an eyewitness, was a vast collection of tents called the Happy Valley, since more truly
designated the sickly valley with filth of every description and stagnant pools beset one at every
stride in these tents congregated the refuse of all nations crowded together eight people occupying
what was only space for two blankets firearms and cooking utensils were the only worldly property
they possessed scenes of depravity sickness and wretchedness shocked the moral sense as
as much as felt and effluvia did the nerves, and such was the state of personal insecurity
the few citizens slept without fire arms at hand.
The constant wearing of arms by such a disorderly set, amongst whom quarrels were frequent,
caused many disputes to terminate disastrously.
But the unsettled state of the country and the many desperate characters prowling about made
it necessary to be armed for self-protection.
The weaker party was only sheltered from oppression by a loaded revolver, as there was no assistance
to be expected from others.
Steel and lead were the only arguments available for redress, and bystanders looked on unconcernedly
at acts of violence, the cause of the dispute or the justice of the punishment inflicted
being seldom inquired into.
A poor man arriving in San Francisco as small chance of comfort.
even if he possessed a fairly heavy purse, it soon lost its weight in a city, where a good meal costs $3,
even if the owner kept clear of the many gambling hounds, which kept open house for the allurement of the greenhorns.
In the 50s, San Francisco was very inaccessible, as compared with its position today at the termini of several great transcontinental lines.
To get thither from the east coast, the traveler had a choice between the T-Denactivity,
sea journey round the horn, a partly sea and partly land route via the Panama Isthmus,
across which a road and subsequently a railway were driven, and a land march of some 3,000 miles.
Nevertheless, the distance the era soon teamed with the population of many thousands.
Most of the immigrants, at least during the first two years, came in from the coast,
while a minority worked across the trackless plains,
braving the hostility of the Indians and the many physical difficulties of a passage through a waterless, trackless, and arid region.
Many a bloody battle was fought between the white gold seeker and the scalp-loving crow, Pawnee, or Sue.
Though the light of color eventually prevailed, the natives, when skilled in the arts of treachery and ambuscard,
often murdered parties of their natural foes, and escaped with their gory trophies,
into the fastnesses of the mountains. Shortly after the discovery of gold, a large immigrant band
of Mormons entered California across the Rockies. Without wasting time, they made straight for the
Americano's River and began washing out the golden flakes and dust, which permeated the bed
of the stream. They did not have the valley to themselves for long, since the miners from San
Francisco were now on the march to the Mormon diggings, as they were called after the first
comers. The miners leaving San Francisco for the gold fields often banded together for mutual
protection and help. The perils of the journey was such as to render the passage of a solitary
person a terribly risky business. Before starting, the more prudent goal seekers equipped themselves
with an outfit. Viz, tent, spades, Maddox,
blankets, hides, coffee, sugar, whiskey, brandy,
knives, plates, forks, pots, and kettles.
If funds permitted, a horse or two would be added to the list as bruce of burden,
and anyone who could afford it purchased a mount for his personal use.
But some days the track up country laid through an undulating park-like region,
with sycamore, oak, and cypress,
offered grateful shelter from the burning sun.
Then the landscape changed,
and bare sandhills replaced the green vegetation.
Horrible dust storms filled the eyes and mouths of the travelers.
Hot winds parched their skin till it cracked,
and to these discomforts were added the pangs of thirst.
On one occasion, a party met a straggler
who offered them a flask of brandy,
priceless at the diggings,
in exchange for just a half a pint of water.
The barter was refused,
because water was excessively scarce among the party,
and the poor rich learned that the necessaries of life
are, after all, superior to its luxuries.
Here and there they fell in with men returning from the mines,
broken in hope and health,
who prophesied ruin to anyone who entered the diggings,
and advised a retreat before it was too late.
such advice as may be imagined was quite unheeded for the prospect of finding gold appeared to blind everybody who had not yet tried his luck at the game to all considerations of possible physical collapse travelers had to reckon with the indians ever on the alert to steal a horse or any other possession of the white invader at night watches were set and if the guard overcome by the fatigues of the day nodded
at their post, an animal or two would probably be missing when daylight returned.
The strains of such a journey often let loose evil passions, and men who had started from San Francisco
bound together by solemn pledges to stick to one another, would quarrel and separate, each
endeavoring to be first at the diggings. But the roughest path has an end, and at last weary eyes
were gladdened by the sight of tents lining the banks of a stream.
A canvas erection of unusual size indicated a store
We Indians, Oregon trappers, with skin tan to the consistency of a buffaloes,
Spanish dons of the old school, hatchet-faced Yankees, keen-eyed as the eagle,
jostled one another as they exchanged their coal dust for food and tools.
We may now turn our attention to the cold-saving methods employed at the Californian places.
At first, operations were confined almost entirely to the shallow or surface diggings, where the gold lay at or just below the surface.
Not until the superficial strata was pretty well played out, with serious attention paid to the deeper places, which could be worked only through long tunnels and shafts.
The principal implements used to shallow working are the pick and shovel, pan, cradle or rager, and the sluice.
The pan about 12 inches in diameter at the bottom is of stamped iron and much resembles the ordinary dairy milk pan.
To extract gold from the earth with which it mingles, the pan is filled with the dirt and taken into the water, a stream, tub, or pool, as the case may be.
It is submerged and the miner works the dirt with his hands until the lumps have crumbled, then holding one side of the pan rather higher than that.
the other, he gives it a peculiar circular motion, which produces a rotary current and causes
the lighter portion to pass over the lip, the heavier particles remaining behind. The earthy
element is thus gradually eliminated, and the pebbles are picked out by hand until only a small
residue remains, which is either pure gold or cold mixed with a small quantity of sand.
The residue is then carefully dried in an iron vessel, and the earthy dust can be blown away,
leaving nothing but pure gold.
Panning is slow and laborious work, so that those who had money or skills sufficient to provide
themselves with a rocker or gold canoe, as the Indians styled it, resorted to this less
primitive method of washing.
The rocker resembles a child's cradle, about six inches from the top is a dry,
drawer with a bottom of perforated iron. Earth is thrown by one man into the drawer, and well flooded
with water to break up the lumps. A second miner rocks the cradle backwards and forwards till the final
contents of the drawer fall through the sloping tray below, on which are crossbars, called ripples,
to arrest the gold. Much more scientific than either of these simple contrivances is the sluice,
A long, slightly inclined trough, through which water flows rapidly.
Its dimensions vary according to circumstances.
In some cases, only a single trough, 10 to 12 inches deep, 15 to 20 wide, and 12 feet long would be used.
But as each trough tapers towards its lower end, any number can easily be fitted one into the other
to form a continuous loose thousands of feet in length.
The trough bottom is well provided with ripples, sometimes charged with mercury to catch the particles of gold.
The more mercury being needed the find the separation of the metal dust.
Sluice washing is, if possible, carried on without interruption day and night, for weeks, even for months.
Then comes the cleanup.
The gold either free or amalgamated with the mercury.
It is carefully scraped from the ripples and washed clean in the water.
in a pan. Amalgam has to be squeezed in buckskin or canvas, which allows the liquid mercury to pass,
but retains the solid amalgam. This is put into a retort and subjected to great heat until all the
mercury has vaporized and been led into a condenser, where it resumes its liquid form. The cold thus
obtained is very porous or spongy, and must be melted down and run into bars to be fit for sale.
49 and 50, the rocker and pan did most of the work. The toil was severe in the case of the pan,
which required constant stooping, while the constant immersion of the hands rapidly macerated the skin
and made them very painful. The rocker saved the hands this injury, and, by employing several
sets of muscles, enabled the miner to keep on working without much physical discomfort. By a rule of the diggings,
when a party operated a cradle, a nugget weighing over half an ounce, was considered to be the private property of the person who found it, and was not added to the common fund of metal.
Since several nationalities occupied the diggings, race feeling became acute.
The Americans, who predominated numerically, showed their teeth to the colored miners, and if their property were worth the trouble, often drove them away.
These ejectments sometimes resulted in serious fighting, as the injured party was always ready to resort to stealthy retaliation under cover of night.
Nor was there much love lost between the white gangs.
At the Mormon diggings, a quarrel broke out over a sluice, which damaged the claims lower down the valley.
The sluice owners refused compensation to the injured diggers, who, accordingly, rated the aggressors.
knives, picks, rifles, and pistols were freely used.
Heads were smashed in, limbs lopped, bullets flew,
and in a few minutes the ground had all the appearance of a miniature battlefield.
No truthful picture of these early camps can, unfortunately, be a pleasant one.
Even in the hot season, the nightly dues was so heavy
that blankets would be saturated by the morning.
In the rainy season, a day luge fell,
against which the frail erections of earth and canvas afforded little shelter.
Owing to exposure, hard work, and poor food, disease stalked in many shapes among the miners.
The most prevalent complaints were dysentery, fever, and ague, for which little hope could be procured,
since the few doctors present charged exorvented fees, and medicine was practically non-existent.
Every now and then a poor rich, mad in the delirium of fever,
would rush frantically from his tent and attack anybody who came in his way one morning writes mr shaw i took a stroll round the tents a mosleous silence prevailed of the busy crowds not one was to be seen at work always as still as a hospital
we had not been the only sufferers sickness universally prevailed seemingly as infectious as the plague in every tent lay sufferers in various
stages of disease. Out of 200, at least 20 had died, and not more than 60 were able to move.
These convalescent would be seen gathered together in the stores. Those who were too ill to frequent
scenes of dissipation excited by compassion. They lay huddled together in tents, moaning and cursing,
many of them dying, with no one to attend to their spiritual or bodily wants. And I cannot but
think that many died from sheer starvation or mere want of attendance. Side by side with this
dreadful suffering existed riotous extravagance. The few fortunate diggers gamble deeply,
staking their bags of gold dust against the turn of the guards. Being men of no education,
they imagined that lavish expenditure or they easily won wealth would raise them in the estimation
of their less fortunate fellows. Accordingly, they might be seen see see.
on rough benches, breaking off the necks of champagne bottles, to quench that there is derising
from a diet of sardines, lobsters, and other luxuries, all, of course, purchased at famine prices.
Under the circumstances, it is not surprising that the storekeepers, who never did a hand's turn
of gold washing, made the largest fortunes. A spade which cost originally one dollar might fetch 30 at the
diggings. Thirty-four pounds of biscuits, salt beef, beans, and flour cost $50, and at one time,
when scurvy prevailed and fresh vegetables had run out, the lucky importer of some potatoes
sold them at a dollar apiece to be eaten raw like apples. With respect to the richness of the
diggings, many stories have been told which greatly exaggerate the reality. In a few instances,
immense fines were undoubtedly made by pioneers, but the average product of a hard day's work
would not exceed $15 to $18. Of the thousands who visited the places, only about one-third became
resident diggers. And higher up in the Sierra's, beyond what was afterwards recognized to be
the limit of the gold-bearing belt, the early miner made long and wittorsome journeys over the crests of
snowy mountains, and even into the arid deserts beyond, without ever seeing the color of gold.
Thousands worked like slaves, and won their ounce or so daily from the river deposits,
but living was so expensive that these returns only suffice to keep body and soul together.
Many diggers, hoping for richer vines, stayed on until their small stores of dust had vanished into
the store or saloon, and it became absolutely necessary to retire.
beaten from the struggle. Though robbery and violence were only too prevalent at the diggings,
a very rough justice awaited anybody caught committing a theft. The first dozen men who came
up constituted themselves into an informal jury and passed summary sentence, the loss of one or
both ears with hanging in reserve for serious offenses. Sometimes the Indians made a night raid,
massacred the occupants of outlying tents and decamped with their food, clothes, and other possessions.
A band of Avengers, having been collected, they went on the track of the depreditors, guided by some old trapper well-versed in backwoods craft.
As often as not, the Indians were run to earth and treated with the severity that instilled into them,
so wholesome would dread of the white man and his thunderstick, that the natives in certain districts ceased to race.
and entered the service of their former enemies.
Even if a man amassed wealth that was apt to be a source of great personal danger to him,
he was watched and followed about on the chance of an opportunity occurring
of putting him quietly out of the way.
Bands of desperadoes roamed the country, ready to swoop down on the lucky viner,
returning with his hoard to San Francisco.
Dr. Tyrewit tells of a big American who had a cum laude.
accumulated a very large amount of gold, and who suspected that every visitor to his tent was on robbery bent and acting as a spy.
Any harmless person who looked in accordingly received notice to quit in a few seconds if he did not wish to receive a dose of lead from the ever-ready rifle or revolver.
The gold fever bred a selfishness that sounds almost incredible.
Help was refused to the dying.
When death at last released the poor sufferer, his living comrades often refused to cease work for a few minutes, to give the corpse burial, referring to let it become the prey of the coyotes.
A visitor to the mines had good reason for arguing that when gold comes in at the door, all human sympathy flies out of the window.
After the lapse of a few months, serious trouble brewed in San Francisco. While labor was still scarce, wages reached.
fabulous figures, but with a great influx, at broken miners, these prices could no longer be
maintained, though the cost of provisions and other necessaries showed no sign of diminishing.
Discontent prevailed among the lower classes. Nightly meetings took place, at which agitators
made furious tirades against employers, and those foreigners, who ventured to sell their labor
at cheaper rates than the mob approved of, i.e., for less than
$10 a day. Poor fellows suspected of being black legs were taken to a high cliff,
called the Tarpini and Brock, and hurled onto the beach below, used as a common burying ground,
where the sand brought in by the rising tide, performed the office of Sexton. Yet, in spite of
all this inhumanity and villainy, the town was rapidly increasing and in the face of labor
troubles. Lofty warehouses rose to the very edge of the hills behind the towns. Fine hotels
used business houses and public offices were erected and eagerly rented by far-seeing people
who Sir Cassidy told them that the coal rush would be followed by occupations more steadily prosperous
than placer mining. For five years, the rush continued. Men poured in from all sides. The terrible
transcontinental journey was undertaken by thousands of immigrants who started from St. Louis or Omaha on the
Missouri, pushed along the Platte River, crossed the Rockies, encountered the horrors of the Great Salt Lake Desert,
and after a final struggle with the Sierra Nevada, dropped down into the land of promise.
Their numbers sadly thinned by wounds, accidents, disease, hunger, and thirst.
Mark Twain, writing of this route,
and the great desert in particular, said,
it was a dreary pull,
and a long and thirsty one,
for we had no water.
From one extremity of this desert to the other,
the road was white with the bones of oxen and horses.
It would hardly be an exaggeration to say
that we could have walked the 40 miles
and set our feet on a bone at every step.
The desert was one prodigious graveyard,
and the log chains, wagon trees,
and rotting,
wrecks of vehicles were almost as thick as the bones. I think we saw log chains enough rustling
there in the desert to reach across any state in the Union. Do not these relics suggest something
of an idea of the fearful suffering and privation the early immigrants to California endured?
It is impossible to say how many miners were actually at work in California at the time
of the greatest excitement. A 50,000 is the fifth.
is suggested for 1850. In 1852 and 1853, this number had probably doubled, and as the newcomers
found the rich deposits of surface gold ready to hand, the total output of these years marked the
highest level of the Californian output, some $65 million worth for annum. Memorable among the richest
strikes of those days are those of the Stanislaus, Americano's, Yuba, and
and feather rivers, where the fortunate owners washed out from $1,000 to $5,000 a day.
But such spots as these were limited in area, like the rich pockets found in the mountains,
were called that accumulated most amazingly. One of the pockets yielded $60,000 in two weeks.
Another just doubled that amount in three months, while smaller deposits laid bare in several
instances by rooting hogs, panned out $5,000 and upwards. As soon as the richest bars and
cultures had been worked over, a spirit of restlessness affected the miners. Who were, as Mark Twain
says, no simpering dainty kid-cliffed weaklings, but stalwart, dauntless young braves, brimful of push
and energy, and royally endowed with every attribute that goes to make up of peerless
and magnificent manhood, the very pick of the world's glorious ones.
Mr. Twain is evidently here referring only to the more respectable part of the population,
as the immigrants certainly contained a high percentage of thorough-going scoundrels,
who, if not villains to begin with, rapidly developed into such under the deteriorating influence of gold mining.
Yet in his pages, and in those of Mr. Brett Hart,
we are able to detect the kindliness that often concealed itself under a rough and forbidding exterior.
The man who is ready to draw his gun on little provocation could also lend a helping hand to a mate in time of need.
These folk, wrought to a pitch of nervous frenzy by the myriad reports flying about,
were only too easily induced to leave a locality of moderate wealth and to plunge into the unknown beyond the mountains.
After months of fruitless searching for the advertised, inexhaustible focus of gold, they would return, those who had not succumb to privation, poverty-stricken, and bragged, to find the claims they had left already occupied by fresh arrivals.
A great rush of this description took place in 1855 to the Kern River, 250 miles south of San Francisco.
Three years later, 20,000 men picked up their traps and stampeded to the Fraser River, denuding California of a large proportion of her workers.
The sufferings of this misguided mob were terrible. Their success, very moderate.
By 1855, the shallow places had been almost exhausted. The Pan and Rocker no longer brought out enough gold to render their use profitable.
There remained, however, the deeper places and the load gold, embedded in a quartz matrix.
So, while a thousand little mushroom mining cities, deserted by their busy population, crumbled into ruins,
amid the deathly silence of the valleys, a hundred more rows elsewhere, occupied by men bent on continuing
the search with a more scientific equipment and a different organization of labor.
We will therefore turn our attention to hydraulic mining, with which is connected the second chapter of California metallurgical history.
In some of the valleys, the prehistoric glaciers accumulated beds of gold-bair and gravel to a thickness probably unparalleled in the rest of North America.
Inasmuch as the greater part of the gold sinks to the bottom of a bed, it can be reached only by shafts and tunnels.
unless the whole mass is in some manner disintegrated, washed and carried off by water.
If you have ever watched a fire engine at work, you must have been impressed by the force
with which the water jet strikes an object, against which it is directed.
Imagine such a jet turned on to a bank of crumbling gravel, and you have the essential idea
of hydraulic mining.
In order to carry out such operations successfully, in a bunch of it.
supply of water under very high pressure is needed. To this end, special companies were formed in
California to bring water long distances from mountain lakes or rivers through ditches, troughs,
or pipes, to the scene of operations. As the channel is built on a much gentler gradient,
than that of the valley along the sides of which it runs, by the time it reaches the mine,
it may have a head of some hundreds of feet. From the end of the end of the,
channel, the water is led down through pipes of decreasing diameter nozzles, three to six inches
in diameter, which fired against the gravel bank with enormous power. An expert has stated
that a strong man could not possibly strike a crossbar through a six-inch jet of water,
coming out under a 300-foot head. This is extraordinary, though, a fact, and men and animals have
been killed by the jet at a distance of 200 feet or more from the nozzle.
The flume companies expended huge sums on this kind of work in the 60s.
In Nevada country, it's the Grand Trunk line of the Eureka Lake and Yuba Canal Company,
running from four small lakes near the summit of the Sierra to North Sandwan.
65 miles away, the Eureka Lake supplies most of the water.
A granite dam, 250 feet long and 70 feet high, was built across the valley to impound 930 million cubic feet of water.
The main trunk carrying the water to the mines is 8 feet wide by 3.5 deep and has a fall of about 1 foot in 100.
Now far away runs the South Yuba Canal, 16 miles of which cost about $600,000.
It passes through several tunnels.
One of these, writes Mr. T. F. cronies.
60 feet in length cost $6,000, another, 3,800 feet long, having cost $112,000.
The flume, seven miles long, runs for one and a half miles through a gallery, worked into the side of a precipice of solid rock, 100 feet high.
The cliffs being so impending that the workmen had to be let down from the top,
to commence drilling and blasting,
an expedient not all
and common in the construction of these works
in other parts of the state.
From the main trunk,
ditch branches ramify,
carrying water over an immense tractor country,
supplying a vast number of mills,
hydraulic, and sluiced claims.
This company has thrown dams across the outlets of four lakes,
situated near the summit of the Sierra,
using them as reserves of supplying their canals in the dry season.
One of these dams constructed of solid masonry, 42 feet high, and 1,100 feet long,
has increased the volume of metal leg more than tenfold.
This lake, formerly a mere pond, now being, went full,
more than a mile and a quarter long by half a mile wide.
This company spent $1,130,000 on their works, but in 12 years netted $1,400,000 in receipts.
Placer County boasts the Auburn and Bear River Canal, 290 miles long, which costs $670,000.
Amateur County has a $400,000 ditch of 66 miles.
Califaris County, a 50-mile ditch, which costs $350,000, and in Tulam County runs the 40-mile Big Oak Flat and the 35-mile county water company's aqueduct, costing $600,000 and $55,000, respectively.
Since 1870, even larger pipelines have been laid, in most cases with a very good result of the only only ones.
owners and users. Having secured water, the hydraulic miner has done only part of the work,
preparatory to an attack on the gravel bed. The whole of this must be detached, broken up,
robbed of its gold, and carried right away without any cessation of labor. When the mining ground
has been selected, a tunnel is driven into it from the neighboring ravine through the rock,
approaching the gravel on a steady upgrade of about one in eight.
The tunnel of a large working measures seven feet in height and as many in width.
Its length ranges from a few hundred feet to several miles.
In the latter case, it becomes a big engineering feat,
accomplished only by the help of scientific calculations
and proper rock-boring tools,
and necessitates a heavy capital outlay.
This will account for such task,
not figuring in early Californian mining days.
The upper part of the tunnel is so driven that its end lies 50 to 100 feet below the gravel bed.
A shaft is then sunk to meet it, and the way out is clear.
All along the bottom of the tunnel and far down the ravine and to which it empties is laid a large sluice,
two and a half feet wide, and of sufficient height to handle all the water that the hydraulic pipes can deliver.
Between the blocks the miners poor tons of mercury to catch and absorb the fine particles of gold.
The jet is now directed against the earth round the shaft's mouth,
which, under the continuous action of this enormous mechanical force,
quickly crumbles away and falls into the shaft.
Even big bulge is weighing half a ton of more are shifted,
and make the plunge, splintering themselves and anything on which they alight,
acting as an automatic crushing machine. A deep trench is gradually opened along the bed,
and then the walls receive attention. If very lofty, they are worked in two stages,
the upper crumbling easily, while the lower may have to be plastered with explosives before the
water can affect it. Tunnels are driven horizontally through it, and from them shafts right and left
to receive the explosive, which breaks off huge masses of the conglom.
and disintegrates them sufficiently to be affected by the jet.
Every month or so comes the cleanup.
In some cases, the returns are very heavy, averaging $1,000 at upwards per diem.
Cleanups of $100,000 are recorded, and the metal is won comparatively cheaply.
Each cubic yard treated costing but one hundredth of the labor bill for panning.
Of course, in hydraulic, as in other forms of coal,
getting, there are failures which are ruinous in proportion to the outlay on preliminary engineering.
The effect of hydrolycing on the country is, from the scenic point of view, appalling.
Tornado flood earthquake and volcano combined could hardly make greater havoc, spread wider ruin and wreck
than are to be seen everywhere in the track of the larger gold-washing operations.
None of the interior streams of California, though naturally pure as crystal,
escape the change to a thick yellow mud from this cause early in their progress from the hills.
The Sacramento is worse than the Missouri.
Many of the streams are turned out of their original channels either directly for mining purposes
or, in consequence, other great masses of soil and gravel that come down from the gold washings above.
Thousands of acres of fine land along their banks are ruined forever by the deposits of this character.
A farmer may have his whole estate turned into a barren waste by a flood of sand and gravel from some hydraulic mining upstream.
More, if a fine orchard a garden stands in the way of the working of a rich gulch or bank, orchard or garden must go.
Then the torn out, dugout, washed to pieces, and then washed over side hills,
masses that have been or are being subjected to the hydraulics of the miners,
are the very devil's chaos indeed.
The country is full of them, among the mining districts of the Sierra Nevada,
and they are truly a terrible plot upon the face of nature.
This picture is from the pen of an author who traversed the country in 1868,
and what he saw then can be seen today on a still larger scale.
Probably in no part of the world has what have been so extensively employed
to maltreat nature's arrangements as it was in California,
the home of hydraulic mining.
Of the quartz mines, nothing need be said here,
since the methods of separating gold from rock
will be fully treated in the following chapter,
except to refer to the huge amounts of metal
that the loads of the Sierra have yielded, especially the great quartz vein or mother load,
which has been traced for 80 miles and has been worked to an enormous depth.
End of chapter three.
Chapter 4 of The Romance of Mining.
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Romance of Mining by Archibald Williams, The Gold Fields of the Antipodes.
First discovery of gold in Australia. A convict's hard luck. Early discoveries hushed up. Hardgraves finds the New South Wales deposits. The rush. Melbourne folk alarmed. Gold found in Victoria. Huge nugget found at Merrew Creek. Its effect on the colony.
Victorian gold, wonderful pocket struck, overcrowding of Melbourne,
Canvas Town, rapid growth of Melbourne, ill-feeling aroused by mining fees,
Ballarat Riot, Goldfield Extravagance, Curious Plight of South Australia,
special measures for gold transport, the Great Nuggets of Australia.
A convict working in New South Wales during the 30s
produced one day a small lump of gold
which he professed to have found in the earth.
But being unable to point out the spot to the people,
he was hailed before a magistrate and awarded 150 lashes
as the penalty of having melted down a gold watch.
The magistrate apparently did not reason
that a man who had stolen a watch
would hardly be full enough to publicly
exhibit the gold of its case as metal discovered in its natural state. But those were days when
suspicion and punishment walked hand in hand among the ticket of leaves. Thus and especially began
the discovery of gold in Australia. In 1839, Count Straleski reported to Sir G. Gipps, the then-Governor of
New South Wales that in the Vale of Clodd, he had found a deposit of auriferous sulphurate of iron,
containing an insufficient proportion of the precious metal to repay the cost of extraction.
Two years later, W.W.B. Clark, a Sydney resident, detected gold in the vicinity of the New South Wales
capital. But, like the count, he was asked by the governor to keep the fine secret on account of the
difficulty of maintaining order among 45,000 convicts that would ensue were the news spread abroad.
At this time, Australians were occupied with the pursuits of sheep and cattle raising. They knew nothing
of gold fields, but the Californian treasures had not yet come to light. When, therefore, a shepherd now
and then walked into a town with a few ounces of gold which he had laboriously picked out of the
rocks. He was regarded in much the same light as the unfortunate convict and set down as a robber.
The better educated colonists, who owned large sheep runs, little knew that. As they went their rounds,
they were literally treading on gold. Eight years before the actual discovery of gold in 1851,
a Mr. H. Anderson while walking over his sheep station at Ballarat with the neighbor noticed a small
piece of shiny white quartz
streaked with a glittering yellow substance.
He is gold, he cried,
handing the lump to his companion
who said,
tut-tut, man, golden nonsense,
and made Mr. Anderson so mistrustful
to his own judgment
that he heaved the quartz
at a pair of laughing jackasses
nearby and thought no more
the matter. The scientific
statements made with regard to the existence
of gold by Count Stirlesky,
Dr. Clark and Sir Roderick Murchison
during the 40s might have produced no results for many a long day
had not gold been discovered thousands of miles away in California
whether a large part of the Australian population had migrated.
Among the gold seekers was a Mr. E. H. Hargraves
who noticed the resemblance between the geological formation of the Californian deposits
and certain districts with which he was acquainted in Australia.
In 1850, he returned home to prove whether the pickax and cradle could not be used with good effect in the antipities.
Working at Summerhill Creek, Neil Bathurst, in February 1851, he discovered gold
and applied to the authorities for a rewarding compensation for the hardships and expenses which he had had to meet.
The government, only too anxious to check the immigration to California, offered him a handsome
some if he would show the gold-bearing locality, and on his referring them to the Lewis Ponds,
Somerhill, and to the Macquarie River, a sum of money was given him, which two years later was
increased for 10,000 pounds and a pension. As in California, the first cent of a goldfield
was the signal for a rush. From Sydney, a mob of men, women, and children, trooped through
the Blue Mountains, leaving whole streets deserted, to be brought.
brought up by foreseeing speculators, who in a few months got their money back to end fault.
Sydney became a second San Francisco, with the same tremendous rise of prices for both labor and the necessaries of life.
Servants vanished into the back country. Government salaries were doubled to keep the various staffs from unavoidable debt and insolvency.
In short, only a few persons remained behind, and those few had to be well paid.
So great was the emigration from Victoria to New South Wales that the Melbourne authorities became alarmed.
Something must be done to check the draining away of all labor from the colony.
A reward was offered to anyone who should find gold within 200 miles of the capital.
People soon came to claim the money.
Gold had been discovered at the Plenty River on the Yarra and in the Pyrenees Range,
and finally in August 1851 at Ballarat.
Melbourne and Geelong were at once overtaken by the fate of Sydney in an aggravated form.
They became like deserted villages.
Geelong was so stripped of its males that women crowded to the doors to view any stray man
who might happen to pass through.
The case of California exactly reversed.
There, man paid heavily in cold dust with the privilege of a peep at a member of the gentler sex
through the cracks of a shanty.
In four months, the population of Geelong sank from 8,291 to 2,850 souls.
This state of things existed only for a short time, as immigrants from China, Tasmania, South Australia, and Europe soon began to pour into Melbourne at the rate of 2000 a week.
Of these immigrants, a large proportion were very undesirable, being ex-convicts from Tasmania.
Men returned from California and the scum of adjacent colonies.
Disorder grew rife at the cold fields where wild forest, honeycombed with hundreds of thousands of ready-made graves, tempted the villain who envied a lucky digger to hurl him, wounded to death, into the hole from which he had scooped a fortune.
Ballarat, Bendigo, or Sandhurst, and Mount Alexander with a grateful guy of attraction.
The terrible roads leading to these diggings turned into dust or mud beneath the tramp of tens of thousands of people, all on treasure hunting bent.
Accounts of huge jackets on earth from time to time kept the excitement at fever pitch.
Hungry crowds settled like locusts on claims, and without waiting, in many cases, to obtain a license, began digging for dear life, aided by the rocker or pan.
fortunes were made quickly as Australia, and particularly Balerat, is notable for the coarseness of its gold,
which seems in this continent who have largely escaped the grinding to powder, so noticeable in California.
One man, who had saved at 100 pounds, invested the sum in his many acres of land,
which two years later he sold to the diggers for 120,000 pounds,
and there are plenty of instances recorded in which a single stroke of the pickaxe or blow with a spade and rich the worker for life.
One of the most remarkable nuggets came to light very early in 1851 at Maroo Creek, New South Wales.
An Australian black, employed as a shepherd by Dr. Carr, amused himself with goals seeking while tending the sheep.
He happened to see a speck of some substance glittering on the surface.
of a quartz boulder and chipped off a piece with the storm hawk, and there, embedded in the rock,
lay a mass of gold which, when placed on the scales, weighed 102 pounds, nine ounces,
a value of over 4,000 pounds sterling.
The arrival of this nugget in Bathurst, the center of the New South Wales industry,
produced a furor, which has been thus described by a local newspaper.
Bathurst is mad again. The delirium of golden fever has returned with increased intensity.
Men meet together, stare stupidly at one another, talk incoherent nonsense, and wonder what will happen next.
Since the affair was blazoned to the world's several gentlemen of our acquaintance,
have shown undoubted symptoms of temporary insanity. Should the effect be at all proportionate in Sydney
to its population.
The inmates of Bedlam Point
may be fairly reckoned as an integral
part of the population.
Victoria has contributed
by far the largest proportion of gold
found in Australia.
The diggers got from the alluvial
workings no less than
2,738,404 ounces
in 1852
and 3,150,021
21 ounces during the following year.
To quote totals, between 1851 and 1895,
Victoria was responsible for 60,155,047 ounces.
New South Wales, 11,421,544 ounces,
while Queensland, which only entered into serious competition
as late as 1860,
came in a good third with 10,604,031 ounces.
For the first two colonies, 1851 and 1852 were the golden years,
since they witnessed the working over their rich alluvial deposits.
Probably the best record for washing comes from Mount Alexander.
A party of five men had sunk six holes to depths ranging from 30 to 60 feet without success,
and they were so disheartened that they determined to give up after one more attempt.
Before the seventh hole was three yards deep, they struck it rich with a vengeance.
In eight hours, one hundred twenty pounds, Troy weight of virgin gold, was amassed,
giving the lucky men five thousand pounds to divide between them.
Such strikes were, of course, the exception.
In October 1851, saw many folk returning disgusted.
to Melbourne. People who were unfit for the business, who had tried their hands and found that,
instead of getting gold easily by merely scratching the surface, they must work hard for it,
experienced, meanwhile, much hardship and probation. Yet even their dismal accounts did little to stem
the tide of immigration. Melbourne could not house all the newcomers, who poured in by every boat.
Hotels and lodging houses overflowed. A city of tents,
aptly named Canvas Town, rose on the south side of the Yarra-Yara. The scenes in Canvas Town were such as to jar upon
the feelings of even the unrefined. And in that huddled assemblage, there were many delicate and sensitive
persons plunged by circumstances into a vortex which the master of the Tenta Hut had not anticipated.
For the water police and the female immigrants who arrived under contract, Hulks were secured in the
bay. The hardships of this mode of life soon rendered it imperative to provide decent shelter
for those who needed a refuge. Public and private subscriptions were raised to build an institution
for homeless immigrants. The buildings, though rough, were at cleanly contrast to the disgusting
confusion of Canvastown and were gladly used by nearly 8,000 people in one year. All this movement
of population had lasting effect.
Before 12 months had passed, Melvin had doubled her numbers, and a decade she rose from a small town of about 25,000 souls, to a large city of 190,000 inhabitants.
Land, which before the rush, cost 68 pounds for acre, changed hands 30 years later, at 80,000 pounds, and today is scarcely purchasable.
A writer-speaking of the 1857 Melbourne says, only three children.
years ago. This undulating surface, North Melbourne, was covered with grass and dotted over with
gum trees. The traveler, as he sallied forth to the bush, in those days gone by, would turn his
nag one at the highest spot to take a last view with the thriving capital of Victoria and the bright
blue water beyond, with some considerable shipping already well attested the progress of a flourishing
young colony. Since then, however, all had been changed into a wild and tumultuous development.
The waters of Hobson's Bay were scarcely visible beneath the forest of five or six hundred vessels.
The grassy glades of North Melbourne were now a hard and dusty surface, cut up everywhere
with roads and disturbed with the incessant noise of the traffic to the interior.
Now country has been more opened up by its cold industry.
than has Australia. Gold brought settlers, who, after the first rushes, turned from precarious
metal-seeking to more monotonous, but at the same time was certainly productive pursuits.
Immense sums were spent on roads, railways, and other public works, which dotted the country over
with large towns distinguished by their fine buildings, streets, parks, gardens, and reservoirs.
The very areas on which a solitary shepherd earned a scanty meal by tending vagrant flocks,
and where the emu stalked, or the kangaroo listened for the approach of an enemy,
are now busy centers of industry, whose history opens with the word gold,
but now records the advance of many-headed industry.
An unfortunate feature of the early mining days was the ill-feeling aroused by the collection of digging fees.
feels swarmed with people only too ready to applaud the fiery eloquence of the professional agitator,
devoted to the breeding of quarrels between the minor and the government Goldfield's police.
Many men refused to take out licenses. Others grumbled at the amounts which they were called upon to pay.
And so acute became the excitement that in 1854, Ballarat won notoriety as the scene of a serious armed collision.
On the 6th October, a minor named Jane Scobie was killed in a scuffle,
and public suspicion fastened itself on one Bentley,
an ex-convict from Tasmania,
who kept a disreputable public house called the Eweka Hotel.
A mob burnt his house, and would have lynched the proprietor,
and not the police stepped in and rescued him,
to be afterwards tried and sentenced to three years penal servitude.
Three persons, who had been arrested,
on the charge of burning the Eureka Hotel, received much lighter punishments, but the Balauraat people,
considering the sentence unjust, demanded their release.
On this being refused, the agitators got to work in spread sedition,
which terminated in a conflict between the mob and the military forces under Captain Thomas.
Several prisoners were taken by the soldiers.
A mass meeting unanimously chose an Irishman,
Peter LaLore, as the popular chief, and on the 30th November all work was suspended preparatory
to a second attack on the government forces. The rioters fired into the camp. Three days later,
Captain Thomas took the offensive, carried the Eureka Stalkade, behind which the rebels had
entrenched themselves and made 125 prisoners, besides killing a few dozen of the defenders.
The prisoners were dispatched to Melbourne for trial, but instead of the people, but instead of
being awarded the penalties they so richly deserved, they were pronounced not guilty by the
twelve good men and true, who saw in their conduct not an act of treason, but the deeds of
heroes. So low had law and order fallen in Victoria. Goldfield history, like other history,
repeats itself. Melbourne and Sydney were formidable rivals to San Francisco and the inland
diggings in their scenes of extravagance. Though some miners quietly amassed wealth, the majority
of the lower class acted up to the saying, easy come, easy go. Mr. Rusden, in his interesting volumes,
gives us a vivid sketch of the Australian spendthrift. Fortunate gold scrapers flung their money
broadcast in scenes of luxury and debauchery. Stories were told that many of them, scorned to take
change from a barber when tossing him a pound sterling, that a roughly dressed man called a cab,
which he required for the day, that when the driver replied that the man could not have it,
unless for more than he would like to pay, seven pounds. The novice homo threw him ten pounds,
and told him to light his pipe with the difference, and that, in the very drunkenness of enjoyment
of their wealth, many diggers lit their pipes with banknotes. The shopkeepers did a roll,
trade, especially with men about to be married, whose one ambition was to deck their brides
in the most expensive silks, satins, and laces that money could buy. The more civilized
criticism, that is very dear, gave place to the complaint, haven't you anything dearer than
that? And the shopman was, of course, equal to the occasion. One of the most peculiar features
of the Australian Goldrush, the strenuous efforts made by the different calling.
to keep their population at home, has already been hinted at. Adelaide, the capital of South Australia,
was deserted by thousands who were 1851, started for the Victorian diggings. Houses were abandoned,
property became unsaleable, and business of all kinds was utterly strangled.
As the emigrants carried with them all the cash they could raise,
the banks drained of gold had to contract their circulation.
and when some miners returned with 50,000 pounds worth of the metal,
they found themselves in the extraordinary plight of being unable to sell it,
because there was no money available for its purchase.
The government, to cut the Gordian knot,
authorize the issue of notes against the ingots,
at the rate of 71 shillings to the ounce,
the notes to be legal tender,
and in the following year, permission was obtained from England,
to coin gold token,
of five pounds, two pounds, one pound, and ten shillings respectively. Paper money then decreased,
while credit and confidence were at once restored. To facilitate the return of the population
and to ensure the influx of gold by South Australians into their own colony, the authorities
cut a road through the scrub for a hundred miles and organized a system of convoys to escort
gold from Victoria to South Australia.
Crowds of immigrants willingly paid a 2% charge, made for transport.
The first convoy returned was 6,000.
The second was 19,235.
The third with 28,206 ounces, so that this colony, which in 45 years mined only half a million
ounces from our own territory, quickly amassed wealth which, when the rush was over,
led to a rapid development of the country.
Australia is as rich in load gold as in free gold.
The quartz of the mountains has yielded very remarkable returns
ever since the miners overcame their antipathy
to improve machinery.
Occasional veins carried so much metal
that the use of a mere handhammer proved remunerative.
The Mount Lyle loads contained from 15 to 20 ounces to the ton of
rock. The quartz quarried on the surface was not at first sent to mills to be crushed, only fragments
from which gold peeped received attention, and even after mills were erected, the methods of
treatment were so imperfect that only the richard's quartz yielded a profit. But with improved
processes, as much as 4,000 pounds a week, became quite ordinary earnings for a well-situated
mill. Australian gold mining owes so much of its romance to large nuggets, which, especially in
Victoria, brought sudden fortune to some miners, that a page or two will be devoted to these
interesting masses of metal. The formation of nuggets has been explained in various ways. Some authorities
suppose that they have grown in the alluvium, and have been gradually increased by deposits of metal
from the chemically charged water, which for ages percolated the stratum.
Others are unwilling to accept this theory,
preferring to believe that nuggets are the result of fusion.
The problem has not yet received a definite solution.
It is certain, however, that Australia's nuggets are never likely to be surpassed in size.
Appended is a list of the largest specimens,
the date and place of their discoveries, and their respective weight.
Chart, columns, Nugget, date of discovery, place, weight in ounces.
The Welcome Stranger, February 5, 1869.
Donnelly, Victoria, 2,268 ounces.
Welcome Nugget, June 15, 1858, Ballarat, 2,217 ounces.
Blanche Barkley, August 27, 1857,
King Gower, Victoria, 1,741 ounces.
January 31, 1857, Valerat, 1,619 ounces.
1857, Donnelly, 1,363 ounces.
November 1, 1858.
Bursadong, New South Wales, 1,286 ounces.
July, 1851,
Bathurst, 1,272 ounces.
September 8, 1854, Bala Rott, 1,177 ounces.
January 20th, 1853, Bala Rott, 1,117 ounces.
June 1855, Mariborough, 1,534 ounces.
January 22nd, 1853, Bala Rott.
1,011 ounces.
Heron Nugget, March 29th, 1855, Mount Alexander,
1,08 ounces.
August 1860, Balauret, 834 ounces.
March 1857, Kengawa, Victoria, 810 ounces.
1860, Kangawa Victoria, 805 ounces.
February 1861, King Gower, Victoria, 782 ounces.
October 22, 1856, Daisy Hill, Victoria, 715 ounces.
May 1856, Taradale, Victoria, 648 ounces.
October 22, 1855.
McIver, Victoria, 645 ounces.
1st, 1854, Bala Ratt, 625 ounces.
April, 1860, Castle, Maine, Victoria, 600 ounces.
October 1852, Bendigo, 573 ounces.
March 6, 1855, Balauret, 571 ounces.
Nile Desperatum, November 1857, Balarat, 540 ounces.
January 15th, 1858, Mariborough, 537 ounces, 1856, Taradale, Victoria, 524 ounces. March 1855, Belarot, 480 ounces.
1853, Balerot, 371 ounces. February 1853, Ballarat, 368 ounces.
Hethurst, 366 ounces. Dascombe, January 1852, Bendigo, 338 ounces. 1854, Bendigo, 338 ounces.
1860, Castle Main, 304 ounces. 1852, Bendigo, 288 ounces. May 1860, King Gower, 230 ounces.
compiled from a list made by Mr. William Berkmeier.
It is unnecessary to describe life in the gold fields,
because what has already been said at the Californian diggings
applies on a large degree to their Australian counterparts.
The parallel is continued into the later history of the two countries,
for a large proportion of those people,
who came to seek gold,
remain to take up sheep farming and agriculture,
on which the real prosperity of both,
Eldoradoes ultimately rests.
End of chapter four.
Chapter 5 of the Romance of Mining.
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The Romance of Mining by Archibald Williams.
Australia
Sterile Character of West Australia.
Gold at Cool Garde.
A lucky find.
Another lucky find.
The luck of Hannan's.
The Australian Fields.
Cool Garty.
Wind and dusk.
Want of water.
Dry blowing.
Hannan's Brownhill and Great Boulder.
The Cool Garty water supply.
A pipe 328 miles long.
Description of the pipeline.
Effect of Gold Discoveries on Australia.
Rapid has been the development of Eastern Australia
since the first discovery of gold,
an even more remarkable way of progress
is transforming the, till comparatively lately,
waste expanses of the most western colony.
At the time when diggers first swarmed into New South Wales and Victoria,
West Australia was a mere no-man's land,
uninhabited except by aborigines and a handful of convicts, and probably only of very few people
ever suspected that among the sand hills lay treasure which, 36 years later, should open for Australia
a second era of gold mining. The Kimberley Field, in the most northerly part of the colony,
was located in 1882 and proclaimed in 1886, but it was not till May or June of the colony.
of 1892 that messrs. Bailey and Ford, starting from Southern Cross, set out on their memorable
journey which resulted in the discovery of the Colgarde Goldfield, where they obtained 2,000 ounces
by merely smashing up the quartz with rude implements. Though their search was deliberate,
the actual find was, as so often happens, in the history of mining, a matter of pure accident.
Bailey had long prospected without success and was returning to Perth, the capital, very much down in the mouth, when the lucky moment arrived.
His horse became restless in the night and began to kick and plunge so vigorously that Bailey went out to coax the animal into quietude.
Whilst on his way he stumbled over what he had first thought to be a stone, but which proved on examination to be a huge mass of
pure gold. A claim was at once pegged out, and in four weeks, 10,000 pounds had been realized.
This claim stands near the center of the town, which, after the inevitable rush, sprang up like
a mushroom and was christened Cool Garny, a name familiar to the ears of many people,
who take little interest in mining affairs. The Pilbara gold fields, halfway up the west coast,
all their origin to an equally trivial incident.
It appears, said Mr. A. G. Charlton, in the engineering magazine,
that a discerning youth of tender years picked up a stone to throw at a cow.
Some say a crow.
And, noticing that it contained gold, reported the fact to the warden.
This gentleman was so excited at the news that he flashed the intelligence by wire
to the then-governor of the colony, informing him that a ladder
picked up a stone to throw it at a crow, but forgetting to add that he had seen gold in it.
The governor, much surprised, but moved with curiosity wired back. Yes, and what happened to the crow,
or cow? This solicited explanations which led to the proclamation of the district as a gold field,
and in consequence of the rush that followed, in the same year, 1888, 3,493, um,
ounces of gold were obtained. Twenty-four miles from Cool Garty is Calgorely mine, otherwise known as
Hannan's, the scene of many wonderful finds, notable among which was that of a man who to while
away his time one Sunday began to prospect under his tent and struck a rich pocket. Unfortunately for
him, he was so excited that he gave away the secret before he had pegged out his claim, and therefore
forfeited all rights to ground other than what his tent actually covered. Through accidents such
as these, West Australia, shut off by the desert from the eastern diggings, came into her own,
despite the prophecies of geologists that the colony could not, according to scientific laws,
contain any gold whatsoever. There are now 17 recognized fields in West Australia. Kimberly,
Pilbara, West Pilbara, Ashburton, Gascoigne, Peak Hill, Murchison, East Murchison,
Mount Margaret, Yalgoo, North Colgarde, Yilgarn, Coolgarde, Broad Arrow, East Colgarde,
North East Colgarde, and Dundas. Each field contains many mines in between them. They cover
a total area of 324,569 square miles.
Eight times that of England.
So much for the geologists.
The Cool Gardy fields on which our attention will be centered in the following pages of this chapter,
lie about 350 miles east of Perth,
on a plateau elevated more than 1,200 feet above sea level.
The plateau is crossed by a succession of sandy ridges,
their crests separated by shallow valleys running north and south.
Sandstorms and flies are its,
chief drawbacks. Whirlwinds called Willy-Willies, by the Aborigines, spring up suddenly,
spin madly along, seizing in their vortex dust, paper, and any other small objects which they may
meet, and as suddenly die down. Unpleasant as they are, the high winds which flow continuously
for weeks together are worse. An idea of their effect on the population may be gathered from the fact
that fences four feet high
have been completely buried by the sand particles.
They sweep along in less than two years.
The great need of West Australia is water.
The annual rainfall averages but a few inches.
Hence, mining has in many districts
to be carried on in a fashion
accommodated to natural conditions.
Water being absent, but wind very present.
The shallow diggings have worked by the dry blowing method.
after the alluvium has been well shaken to bring the larger lumps to the surface for removal the workmen pours a pantful of the dirt from a height of four or five feet into a second band on the ground at his feet he stands edgeways to the wind which blows away some of the dusk
but allows the heavier gold to fall perpendicularly.
The process must be repeated until only a little rubbish containing the gold is left.
Then the miner begins to blow with his mouth,
and as soon as he was removed what he can in this manner,
he finishes all the separation with a little of his precious water.
Corresponding to the cradle of river gold washers is the dry blower,
consisting of a couple of slanting frames fixed on,
legs so that the miner can shake the contents backwards and forwards, like a servant, sifting ashes and
cinders. The dirt, fed into a harbor having a bottom pierced with large holes, passes down the inclined
screens, on the way losing its finer particles, which fall through. The coarsest stuff passes over the end,
while the gold flakes and nuggets collect behind the ripples, place to catch them. The fine matter is treated by
hand in the manner already described.
Twelve hundred weight of dirt can be treated by a dry blower of this kind in one hour.
More elaborate patterns fitted with bellows to produce an artificial air current, handle several tons in the same time.
Hannan's Brownhill and Great Mulder are two of the principal load mines.
Their yields have been prodigious.
In the land of gold, Mr. Julius Price describes these two properties.
as he saw them a decade ago, when operations had only recently been begun by the proprietary companies.
He descended the main shaft of Hannan's Brownhill, and he says,
I was astonished to find that the whole place was positively sparkling with gold.
I had often pictured to myself what a gold mine would be like,
but in my wildest dreams I had never imagined anything to equal this.
The man, a miner, must have knocked out at least a hundred pounds worth of ore
During the few minutes I had been watching him in this veritable Aladdin's cave.
It absolutely made my mouth water to take up some of the lumps of stone,
lying loosely at my feet,
whilst I could not help trying to realize the feelings of this poor digger,
finding himself quite alone and surrounded by all this untold wealth,
which he was getting out for the benefit of others.
whilst he himself was only earning three pounds, ten shillings per week.
At the time of his visit, the manager had under lock and key from 20 to 30 tons of pure gold.
This brief account of West Trale of Mines, brief it must be, through limitations of space,
may fitly conclude with a glance at a huge engineering feat,
which has been performed in the interest of the gold fields.
In almost all of the gold-bearing districts of the world, the metal has been found not far from a stream or natural reservoirs.
We have already alluded to the great Californian system of pipes and flumes, and the reader will remember that some of these aqueducts are of great length.
Unfortunately, for Western Australia, the climate and configuration of the ground are such as to make it impossible to store rainwater,
insufficient quantities within easy reach are the mining centers,
but separating gold dust from gravel and sand, wind may serve.
But the quartz-crushing mills cannot do their work without a plentiful supply of water.
Furthermore, whereas scarcity prevails, disease, especially typhoid fever, is rampant.
The government therefore determined to fetch pure water from the nearest copious springs.
These happen to be in the Darling Range, near the coast, 330 miles distant.
The difficulty of piping the liquid is seriously increased by the fact that the cool-guarded district lies very high,
practically a thousand feet above the source of supply,
not to mention the existence of intervening belts of even greater altitude.
Truly an immense undertaking, the execution of which ranks among the greatest,
engineering feats of an engineering age.
The contract for the piping, which figured at 1,025,124 pounds, went to two Australian firms,
Mr. Mason of Melbourne and Messrs. G.N. C. Hoskins of Sydney.
Mr. Ferguson invented the locking bar pipe used throughout on the scheme.
The peculiarity of this form of pipe is that it is made of
steel plates of semi-circular section fastened together along their sides with two longitudinal locking bars
of soft steel, the flanges of which are pressed onto the edges of the plates until a tight
joint is affected. Owing to the absence of rivets and overlapping plates, this type of conduit is
quickly made and offers remarkably small frictional resistance to water passing through it. In comparison with
cast iron of built-up pipes, it also scores under the heads of water tightness, strength,
and economy in hauling and handling. By the courtesy of the proprietors of Cassius magazine,
we are permitted to quote the following description of this colossal work. The Holana River
was the site chosen to provide the supply for the fields. The flow being impounded at a point
five miles from Mung Daring Station and about 25 miles from Perth.
Seventeen localities that all were inspected and the position of the present dam site
where the hills converge to a narrow space and the country for miles round is flattened out
was apparently the best.
The top of the dam is 753 feet in length, traversed by a neat iron lattice bridge over the crest,
which is 100 feet about the bed of the river.
The dam tapers in thickness from 75 feet at the river bottom to 10 feet at the top.
As a maximum, the sheet of water will be thrown back six or seven miles.
The quantity of water is set down at 4,600 million gallons.
Alongside the dam is a tower which gives access to a number of valves,
allowing the water to be drawn off at various levels,
while at the foot of the wall, a scour valve permits the removal of any silt, which may accumulate.
Exterior to the dam and a little lower down the gully is the first pumping station,
and the second one is only a mile and a half from it, but 400 feet above it.
Here is situated a receiving tank with a capacity close to half a million gallons.
In all, there are eight pumping stations and 11 tanks or reservoirs.
with capacities from half a million to 12 million gallons.
The main service reservoir is 308 miles from the dam,
and its capacity is 12 million gallons.
The minor service reservoir at Cool Gardeau holds a million,
and the Mount Charlotte Reservoir at Calgoorley, 2 million gallons.
Receiving tanks of 1 million capacity were built at five of the pumping stations.
A reserve tank for railway purposes,
was also built at a point along the route, and there are two regulating tanks holding 500,000 gallons.
The level of the water at the lowest offtake at the dam reservoir is 340 feet above the sea,
but so rough is the country in rising that within a little over 3 miles, an altitude exceeding
a thousand feet is reached. 24 miles from the dam, the regulating tank is 1,00065 feet of
above sea level, and then it gradually drops 100 feet in the 12-mile interval.
The next regulating tank is only 476 feet above the sea.
After this, the water flows by gravitation for 42 miles until it empties into the reservoir,
which is 700 feet above the sea.
The next pumpkin station, 63 miles away, is 980 feet above sea level, and 32,000,000.
and a half miles farther on is number five pumping station, 1,293 feet above sea level.
The level varies only 32 feet within the next section of 46 miles, which terminates at number
6 station. In another short length of 32 miles, a rise of 56 feet is experienced over the last.
Number 7 section is 45 miles and finds a rise of only 26 feet.
to number 8 pumping station.
12 miles farther is the site of the main service reservoir
at 1,610 feet above the sea
and 1,270 feet above the lowest takeoff
at the Mundaring Reservoir.
From there, the Cool Gardeau Reservoir is 10.5 miles
and the level 1,515 feet above the sea
so that the water will drop 95 feet,
to Gould Gould.
And from there to Mount Charlotte at Kualh Gourley,
27 miles away.
There is a further drop of 160 feet,
for the last reservoir is 1,325 feet above the sea.
Here, at a distance of 325 miles from the dam,
the pipes at present terminate,
but before long, they will be extended farther east.
Through the 30-inch pipe, the longest in the world,
5 million gallons flow daily into the heart of the sandy desert.
We shall hear no more of cool guarding folk,
paying two shilling six pence per gallon for their water,
or of storekeepers guarding the water bottle more jealously than the whiskey jar.
Abundance has been brought from a distance equal to that separating London from Burwood-on-Tweed,
not to a huge metropolis, but to a mining town of a few thousand inhabitants.
And what was the wizard which conjured up the scheme?
Gold, already the creator of railways from the coast into the far interior.
The magnetic influence of the precious metal has in half a century opened up Australia
in a manner even more striking than the development of the Great West
after the Californian discoveries.
Open your map of Australia and trace the railways.
You will then follow in the steps of the gold seekers, who will be able to be able to be able to,
plotted painfully on foot where the iron horse now snorts with its heavy burdens.
End of Chapter 6 of the Romance of Mining. This is a Libervox recording. All Liverwax
recordings are in the public domain. For more information or to volunteer, please visit
livervox.org. The Romance of Mining by Archibald Williams. The Gold Mines are the Witt
waters rand.
Gold in war.
Value of these mines.
Nature of transfowl deposits.
The Witts Waters Rand.
Banquet.
Value of the Banquet reef.
The gold output.
The essential kaffir.
The labor supply.
Recruiting.
China men imported.
How the mines are worked.
How the ore is treated.
The cyanide process.
difference between Rand and other gold mines.
South Africa.
These words spell two things for the world in general,
and for Englishmen in particular.
Gold, the producer of war.
War, the consumer of gold.
Search the pages of history through and through,
and where will you find a conflict approaching the Great War War in magnitude,
which can be directly traced to the hatred,
bred between nations by the rich treasures that have for ages laying hidden beneath the earth.
The rights and wrongs of that dreadful struggle between the unprogressive,
but by no means despicable, trans-fowled farmer,
and one of Europe's greatest powers we are not called upon to discuss here.
Both nations fought with the courage of their convictions,
determined to decide whatever might be the cost.
whether South Africa should belong to the Boer or to the Englishman.
The wounds, physical and mental, received by the combatants, are scarcely yet closed.
Severe commercial depression has followed behind the chariot of the war god,
and years must still pass before the echoes of the contest have died away.
For the regeneration of exhausted South Africa to what do we look?
To agriculture in the future, but to gold for the present.
At the outbreak of the war, the capitalization of the Witswater ran gold mines, total 70 million pounds, at par, and at market prices more than double that value. During 1898, no less than 4,295, 609 ounces of gold were mined, representing 15,141,376 pounds sterling.
While the fighting lasted, these wonderful minds lay idle in most cases.
The prey of in-leaking water, which there were no pumps to stem,
for the workmen had either fled from the country or were carrying rifle and banderlere in its defense.
Dividends fell to zero point.
Thousands of shareholders found themselves forced to sell their script at a ruinous loss.
But with the advent of British rule, the pumps got to work again.
Stamps were repaired and added too.
All available labor.
Its amounts sadly diminished by the wealth
that the kaffirs had accumulated as camp followers,
collected, and the Transvaal Goldfields
entered on the second era of their history.
The Transfile mines are practically all reef mines.
We have, therefore, no romantic stories of wonderful finds,
such as play,
so large a part in the annals of Orange Land,
of the Antipodes. The Lindenburg District first attracted notice in 1876. The Decapped
Goldfields were discovered in 1884, and in 1885 a man named Arnold, working on the farm Langlatti,
broached the riches of the marvelous Whitwatersrand deposits. Johannesburg City of Dust and Gold Dust
was founded the following year, and in one decade of community.
community of a few hundred people, at swell to a large town, which the census returns estimated
to contain 107,000 inhabitants. Land increased prodigiously in value. Boys who had hitherto
lived frugally on their farms suddenly blossomed out as the favorites of fortune. What then
is this district with a long name? The Witt Watersrand is a range of hills running east and west,
which separates the Limpopo Basin on the north from the Valle Basin on the south.
At some period, early in the Earth's history,
subterranean agencies heaved up the surface of the plateau,
until the strata were broken and so much bent that their edges were exposed.
The strata consisted of quartz, sandstone, and igneous rocks,
sandwich between which are layers of conglomerate,
which from their appearance the Dutch named Banquet or almond rock,
the conglomerate contains very finely divided gold,
are riferous iron pyrates, copper sink, and antimony.
At the outcrop, i.e. the points at which the edges of the sandwich are exposed,
the conglomerate is easily reached, and surface working is possible.
But the farther than the miner gets horizontally from the outcrop,
the deeper he must go before he strikes the gold-bearing deposits.
Owing to the bank had strata being fairly close together,
a single vertical shaft may cut through several, in succession, at various depths.
For the first year or two in the history of the Rand Goldfields,
deep-level mining was practically ignored,
because the orb was not considered to be worth the expense of sinking deep shafts.
Accordingly, attention was confined to close,
claims within a few hundred feet of the outcrop. But when the conglomerate proved very rich,
and when, in January 1890, the made deep level shaft struck the main reef at a considerable
distance from the outcrop. The price of deep level claims rose rapidly, and the dividing
line between valuable gold mining claims and valueless belt receded farther and farther from the
outcrop. Experts have estimated that at 5,000 feet from the outcrop, the vertical depth will be only
2,000 feet, at 8,000 feet, rather more than 4,000 feet, and at a distance of 3 miles about 7,000 feet.
The simmer in jack sunk from a point 4,000 feet deep horizontally from the outcrop of the main reef,
struck it when the shaft had reached a depth of
2400 feet, or rather less than half a mile. As conditions in the transvaal appear to be very
favorable to deep mining, there are no physical difficulties to prevent the sinking of shafts
one and a half miles deep. So far as operations have been carried, the reef has proved very
reliable, being struck within a few feet of the calculated depth. Mr. Hayes-Hamond, one of the
greatest authorities on the metallurgy of the transvao contributes the following opinion to Cassius' magazine.
It is estimated that for every mile in length, along the course of the reefs, down to a vertical
depth of 1,000 feet for the dip of these reefs, gold to the value of about 10 million pounds will
be extracted. This is a conservative estimate, at least is applied to the central section of the
If we assume these conditions to obtain to a depth of 6,000 feet vertically, we have the enormous
sum of 60 million pounds for each mile in length.
It is not unreasonable to suppose that these conditions will be maintained along most of the
central section, save for a distance of 10 miles, in which case we would have in oriferous
area, where practical mining depths containing upwards of 600 million pounds value of gold.
It is less safe to make any prediction of the gold product to be expected from the east and
west sections, but it is perfectly safe to say that the output of these sections would very
greatly augment the amount I have named. Messrs. Hatch and Chalmers, well-known engineers of extensive
of South African experience.
Compute the available gold
from these portions of the rand
at 200 million pounds.
A treasure well worth winning.
During the eight months preceding the outbreak
of the World War in 1890,
the Witt Waters Rand produced
12,4005,032
sterling. But for the
necessary stoppage of the mines,
the year's take would have touched
20 million sterling.
a figure that rivals those of the most palmy days of California and Australia.
No less than 71% of the yield came from the central Johannesburg section of the Rand,
and 24% was raised from the deep-level workings.
The total gold product of the Rand in that year
represented a quarter of the gold mine throughout the world,
and with a steady development,
South Africa will undoubtedly take first place among all,
El Dorados. For other gold fields, those of the transval differ in one important particular.
Fizz, in the labor used. Here, all purely manual, and some skilled work is performed by natives.
The kaffirs or boys, as they are universally called in South Africa. Drills, shovel, lay tracks,
do the timbering, tramming, or sorting, stoking, etc. Skilled laborers, such as fitters, carvers,
His engine drivers are of white nationalities and command very high wages.
The essential Kaffir well deserves his adjective.
Without his help, the gold mines could never have been developed.
As the climate, though healthy, soon tells upon the European or American
who has to do hard physical work below ground.
There is the further difficulty that where white and colored men are engaged on the same job,
the nature of their respective duties must be clearly separated, the white directing, the others obeying.
If well supervised, the kaffir can use the pick or drill, as effectively as he did is assegai,
before the white man put a stop to intertribal raiding.
A problem which African mine owners have had to face from the beginning is that relating to the supply of labor.
By nature the gaffir is a lazy fellow, well-content to till his little maize plot, or rather let his wives till it, sit in the sun and smoke.
His one incentive to labor under the sway of the white man is the desire to accumulate wealth, which will enable him to buy wives, or more wives, if he be already married.
An estate, in the finery in which he loves to deck himself out, the top hat.
of civilization, forming an important item in his wardrobe. Before the war, over 100,000 natives
were at work in the mines. The war either frightened most of these away or gave them
employment as bullet drivers. Those who went stayed away. Those who remained in the
Transvaal earned sufficient money to retire for a long time to their crails, so that when
the fighting was over, labor became very scarce.
Experts estimated the shortage of hands for the mines alone to reach 129,000, and agriculture to be proportionately handicapped.
It had been found necessary as early as 1893 to establish a native labor department for providing an adequate inflow of workmen.
The northern parts of the Transvaal were first tapped by white men, who traveled about engaging kept years to work under contract.
for stated periods of service.
A depot was established at Pete Potkeeter's Rust,
another at Sanfontein, and a third at Pretoria.
The intervals being broken by buildings to service shelters and rest houses
for the gangs traveling south.
Every recruit had to be vaccinated, fed and housed.
From Pretoria, the Cafiers were carried by train to the Rand,
where they occupied the compounds adjoining east.
mine. The system worked very well as it protected the natives both on their journeys and when
in residence at the gold fields. But unfortunately, licenses for the sale of alcoholic drinks were
freely granted by the poor authorities to traders in the compounds, who did a brisk business with
the kaffir, to whom fire water is the sombulum of life, and to be indulged in as freely as funds permit.
So, while on the one hand some men made fortunes out of the traffic, on the other the efficiency
of native labor was so much impaired as to provide the woodlanders with a genuine grievance
against the Boer executive, which looked callously on. The recruiting system had been reviled,
but not with its former success. For two years, depression reigned supreme in Johannesburg.
The mines were many, but the laborers were.
review. At the end of December, things have become so desperate that Sir George Farer moved a resolution
in the Transvaal Legislative Council to the effect that the government should introduce an ordinance
for the implant of indentured, unskilled, colored laborers to supplement the labor supply of the Witts
Waters Rand. The matter was referred to the home government, and after warm discussion in the
House of Commons, the Transvaal received.
permission to introduce Chinese labor under certain restrictions.
Round the question of the yellow invasion, violent controversy has raged.
Those favoring the importation of Celestials, urging that without some such measure,
the transvalmus lapse into bankruptcy, and the supply of African labor could not possibly
meet the demand. Their opponents warmly upholding the view that with time Kaffirs would
flock in, and that in the meanwhile much greater use might be made underground of labor-saving machinery,
which is strikingly absent from some South African mines. Anyhow, a batch of 1,047 Chinese arrived
on June 10, 1904, en route to the new Comet Mine, and before the end of the year,
19,44 pigtails wagged in the compounds of the rand.
There is no workmen in the world to beat the Chinaman for docility, quickness, and industry.
He has already made his mark on the output, and very probably the kaffir, seeing that he no longer
has the mine owner at his mercy, may become scared and seek a job before other berths are filled up.
From the labor question, which has become the peg for partisan orators, do hang up their wares on.
let us divert our attention to the actual working of the mines.
The Rand is dotted over with tall chimneys, huge wheels and ugly buildings containing mills, hoisting engines and pumps.
These indicate the mouths of shafts, which are vertical or inclined according to the position of the property.
We will suppose that the particular mine take it as typical of the Rand propositions, as a Yankee would say, is at a distance of
500 feet from the outcrop of the reefs, runs 2,000 feet east and west, and 1,000 feet north and south.
Being so near the outcrop, the portion of the reef underlying the property dips at a big
angle to the horizontal. The manager, therefore, sinks a vertical main shaft near the boundary
vertically nearest to the reef. And when the reef has been struck, continues the shaft parallel
to the reef in the stratum beneath it.
From the shaft, at different levels, usually 150 feet apart,
cross cuts are made north and south into the reef,
and from these again drives are cut east and west through the reef itself.
The drives are connected by windses,
which, together with the drives, divide the reef into blocks,
called stoops of ore.
The operation of cutting out the block,
removing the valuable parts and filling in the cavities with the rubbish or with material lowered from above is termed stoping.
Underhand stoping signifies the method of working downwards from an upper drive to the drive below,
while overhand stoping expresses the reverse process. In the first case, underhand stoping is most usual on the brand as being more easily learned by unskilled laborers.
The oar is shot down the nearest winds to the level below, where it is caught in cars,
and transported through the cross-cut to the shaft.
The latter has a section varying in dimensions within timbers,
from 11 feet by 5 feet to 26 feet by 6 feet,
is strongly timbered at the sides,
and divided into several compartments with skips and cages.
Should overhand stoping be adopted,
the roof at the level is strongly timbered,
or protected by a strip of reef left over it.
The miners then get to work, hacking at the roof,
passing good stuff through a vertical oar pass,
into the cars in the level below,
and building up a sloping bank of rubbish,
which has its upper face parallel to the lowest surface of the stope.
Sometimes breast stoping is preferred,
i.e., attacking the block almost vertically,
so that it may be termed a very perpendicular variety.
of the underhand method.
Or is loosened with the aid of dynamite
placed in the bottom of holes
drilled by hand or machinery.
The high price of this commodity,
when the Boers held the monopoly of supplying it,
was one of the chief causes of friction
between the Woodlanders
and the Vittorian government.
The Banquet is made of white quartz pebbles,
cemented together by a bluish substance
containing iron pyrites and gold.
In the beginning of things, the three materials were probably merely mixed without adhesion.
But at some time later, when the granite pushed up the reefs, great heat forced and combined them into their present condition.
When a reef is very thin, sometimes it dwindles to a few inches.
The miners are obliged to hack away a sufficient amount of the native rock on both sides to give them room to work in.
A part of this useless material serves to form stulls or supports between the walls of the load.
From the mines, the ore is wound up in skips and dipped automatically into ore bins or trucks, which carry it off to the sorting house.
There it is fed into a hopper, washed and dropped a little at a time, onto the sorting table or sorting conveyor,
according to the practice of that particular mine.
The former is a circular revolving counter, 30 feet or more, in its external diameter,
the center being open space six yards in diameter.
Boys stand all round on both sides, and as the table slowly revolves, pick off all the rubbish.
A scraper is continually shooting what passes their inspection into a crushing machine,
which pounds it into lumps about the size of roadmending granite.
In some minds, the table is replaced by an endless conveyor belt, an American invention.
After the preliminary crushing the ore is transported by trucks or India rubber belts to the mill,
where great stamps stand in a double row, each stamp fed by its own bin.
A heavy vertical bar shot at the bottom with a steel shoe nine inches in diameter,
and furnished with the projection near the top, is raised and dropped nine.
90 times a minute by a cam on a horizontal revolving bar.
It falls about nine inches and crushes the ore, fed by a hopper,
against a steel die of equal diameter.
Altogether, the pestle weighs upward of 2,000 pounds.
The pulverized material called pulp passes through fine screens onto incline copper plates,
coated with mercury, which swallows most of the fine gold,
and when fully saturated, it is retorted to separate the metals.
About 40% of the gold stays in the tailings, which have to be treated chemically.
They are first shaken in a frou vanner, an endless belt which is given a lateral
and a progressive motion simultaneously, while a stream of water passing over the stuff
removes the lighter portions called slimes.
The concentrates are heavier parts,
I now lifted by buckets on the circumference of an enormous wheel into a trough,
through which they flow into the cyanide vats,
of a capacity of some hundreds of tons each.
The vats are filled with a solution containing 2.25, 2.0, or 1.0% of cyanide of potassium,
which, like mercury, has a great affinity for gold.
After soaking in this solution for a week, the concentrates are drained, the solids being cast out onto the tailing heaps, which plagued Johannesburg sadly during high winds, and the solution is taken to the precipitation boxes.
The gold must now be separated from the cyanide, with which it has chemically combined, so to the potassium is thrown food, which it likes even better than gold.
Zinc. And as it absorbs this, it lets go of the more precious metal. The gold settles in a shining
deposit, which is dried and melted in crucibles, and so at the end of several days,
there is seen a solid ingot containing 80% of gold and 10% of silver. This short account
shows the reader how vastly more complicated reef mining is than placer mining. The simple pan,
rocker or sluice have been replaced by machinery of a high order and by chemical processes,
discovered after much careful laboratory research.
The prevalence of machinery, the absence of the individual miner working for his own hand,
the good supply of water, the abundance of provisions and other necessaries, all distinguish
the which waters ran from the gold fields of Australia and America.
Almost from the very first days, the trans-found gold has been attacked by companies backed up by capital,
under conditions which lack the usual hardships of the gold-seekers lot.
End of Chapter 6
Chapter 7 of the Romance of Mining
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The Romance of Mining by Archibald Williams,
The Eldorado of the North.
The Excelsior arrives in Frisco Bay.
California upset.
The Yukon District.
The early approaches thither.
Forty Mile.
George Carmack's Find.
A unique episode in gold mining history.
The reward of laziness.
Wonderful earnings.
melting the ground, the cleanup, fortunes made, a rush to the Klondike, the Chalcute in
White Passes, down the Yukon, terrible mortality among baggage animals in the White Pass,
growth of Dawson, high prices, Dawson of today, the Klondike Placers, Mining Laws, How Alaska
is Being Opened Up, The White Pass Railway,
Alaska's Future
1 July Day in 1897 a small steamer, the Excelsior steamed into San Francisco Harbor
with a cargo that should have shamed many a Spanish galleon of old times.
The passengers were minors, their faces scarred by much hardship and privation.
About their personal appearance, there was beyond this nothing remarkable.
But they brought with them, tied up in sacks, skins, old clothes, tins,
jam pots, and every imaginable article that would hold it. Gold dust, precious gold dust and nuggets
of full tongue in weight. From that moment, millions of tongues began to wag about the marvelous Tom
Tiddler's ground in Alaska and Northwest Canada, where gold could be got almost with the trouble
of picking it up. So the report ran, and gossips whom bred a fever which caused men of all classes,
to quit their work and hurry off to secure in the distant gold fields.
After a few months labor, enough wealth to furnish them with a comfortable livelihood for the rest of their lives.
The rushes to California and the Australian gold fields in the middle of the century were paralleled,
even if not surpassed.
Physical obstacles could not deter the adventurer, clerk, mechanic, government official, or aristocrat.
The thirst for the precious metal blinded his eyes to the coming and well-known terrors of precipitous, snow-clad mountains.
Off he went, full of hope, but often miserably supplied with a proper outfit, destined in most cases to leave his bones in the passes, or at the bottom of the swirling Yukon.
The lucky few made their fortunes in these early years of the boom, but they were the few.
Before proceeding to an account of the Yukon gold fields, as they are today,
lettuce plants at the early history of the discovery of the vast gold-bearing gravel regions
which cover many thousands of square miles on both banks of the mighty Yukon,
a river ranking very high among the great streams of the world in point of both length and volume.
For 1600 miles, the Yukon is navigable by craft to the size of the largest Mississippi state.
and for 500 miles above that, by boats of half that size.
Rising in the lakes on the north flank of the St. Elias Range, at about the 60th parallel
of north latitude, the river makes a huge sweep northwards. At Fort Yukon, 350 miles north,
just touches the Arctic Circle and bends southwards again to its mouth. About 1,600
miles up from the sea is the great gold-scattered track to which makes me.
men are hurrying.
300 miles near the pole, then St. Petersburg.
At midsummer, 22 out of the 24 hours are brightened by the sun,
shining down with almost tropical heat.
At midwinter darkness claims an equal proportion of the day,
and cold lays an icy grip on the country, which is not slackened for months.
Herein lies the main difference between the early Klondike and the other great goldfields of the world.
A man might be lost in California, Africa, or Australia, and yet managed to find his way out,
but not so here.
Once in, always in, after the winter had commenced, and to lose one's way was to perish.
Until recent years, the Klondock region, as large as France, was practically a terra incognita,
traversed by a few Esclimarchs, Indians and half-breeds, and here and there,
a white fox hunting trapper. The bears had the district pretty well to themselves. In or about 1878,
the first gold prospector entered the country, and from that time onwards, small parties of miners
made their way into the Klondike, over the Chilkoot passed from Daya, at the head of the Lynn Canal.
From the outset, gold was found in the bars of the Luz River, the upper Yukon, and its tributaries,
but generally in unremunerative amounts,
considering the conditions under which mining had to be conducted
in a region so remote from civilization.
In 1881, however, paying placers were discovered on the Big Salmon River,
and five years later, the cassia bar was tapped.
In the autumn of that year, mine struck coarse galled on 40-mile creek,
a feeder of the Yukon, which enters it just to the east of the,
the boundary line between Canada and Alaska.
The gold, wrote Dr. Dawson, who afterwards gave his name to the chief city of the region,
varies much in character, but is quite often coarse and nuggety,
and very large amounts have been taken out in favorable places by individual miners.
Few of the men, mining here in 1887, were content with ground yielding less than $14 a day,
and several had taken out nearly $100 a day for a short time.
A city quickly sprang up at 40-mile,
with a 200 out of 250 miners of the district hastened,
and another at Circle, 100 miles lower down in Alaska.
These soon expanded into places more worthy of their title.
A year which will always remain famous in mining history is 1896,
one of a miner named George Carman.
who had been diligently searching for 11 years,
tapped the riches of the Klondike River.
While roaming about with his Indian relatives and friends,
he started digging on the banks of the Bonanza Creek,
and so found enough gold in his pan to convince him that here was a fortune.
He at once hurried off to 40-mile to register his claim,
and after giving some old acquaintances the hint, he started back.
This was in August, just as the way.
winter, which would effectively bar the people of the outer world from entering, had begun.
In a few days, all forty-mile was on the way, and soon 350 men, who had the place all to
themselves, were shoveling at the richest known gold deposits in the world. Never had minors had
such a chance. They knew that for several months no one could arrive to share the spoil.
Fortunes were made at an astounding rate. Carmack and the
three companions washed out $1,200 at eight days, while on the same creek, two other men,
took $4,000 in two days. Newcomers staked out creek claims farther and farther from the
mainstream of the Klondike, until the people from 40 Mile had all been served.
Presently, the Yankee miners from Circle City got wind of the find and rushed up,
suffering terribly on the way from cold and hunger. One of the most key.
curious things connected with this strike was the rich reward that attended an act of sheer laziness.
An ex-partender of 40-mile, who is too sluggish to go off to the top of the Bonanza Creek,
turned aside into a subsidiary creek, the famous El Dorado, out of which he made nearly
600,000 pounds. So rich was the pay dirt that as much as 160 pounds was taken out of a single
pan. On one claim, a nugget was picked up worth 51 pounds, on another one worth 46 pounds.
The cold took a lot of getting out, however, the ground being frozen hard as iron, yet the
digging must be done in winter, since after the spring thaw set in, every shaft became a well,
owing to the leakage from the upper gravel stratum, and because, though it would be impossible to wash
the dirt when the thermometer was many degrees below zero, the abundance of summer water would make
the clean up an easy matter. While sinking the shafts, the miners had to use big fires to soften
the gravel. By the time a fire had burnt out, the ground below it was thawed to a depth of several
inches. Pick and shovel remove all the loose dirt, which was thrown onto the dump, ready for washing
in the spring. Alternate firing and digging, gradually.
penetrated the crust of gravel to within a few feet of the unworkable bedrock below.
And then the real excitement began, but the rich pastry rests on the rock, which has caught
all the gold wash through the ground by centuries of rain and movement. The last 18 inches
of gravel is laid by itself on the dump and treated with special care, that the dust
and nuggets which it contains may be secured. In deeper claims, i.e., those where the rock is
overlaid by very deep gravel, it would be too troublesome to dig out all the super-incumbent
poor dirt. And small shafts are sunk to the rock, and horizontal drifts run from the bottom
through the rich strata. The frozen condition of the earth here aids the miner,
by saving him the labor of supporting the roof of a drift with timber props.
All the winter long the miners burnt and dug, piling up great heaps of the precious dirt.
With the spring began the cleanup, which yielded most sensational results.
Some men made money at the rate of $17 a minute, and fortunes of hundreds of thousands of dollars
came out in a couple of months.
One miner was found looking very disconsolate, and on being asked what ailed him,
he replied that for the last day or two, he had been making only six.
$60 per pan washed, in place of the $100 that is earlier washings produced.
Of all the 300 claims staked out on Bonanza Creek, not one proved a failure.
Many fortunes were found in the sluces and pans, and even among the refuse thrown away,
enough gold remained to bring wealth to anyone who cared to work it over again.
At the end of the cleanup, a large proportion of the miners were made men for life.
Yet, by a strange irony of fortune, they were so pinched by want of food that one man offered half his wealth in exchange for a single good square meal.
The first steamer down the river carried on board nearly a hundred lucky miners, who, as mentioned above, reached San Francisco safely with their spoil.
As the United Statesman was closed for the day, writes a witness of the scene in the New York Tribune.
When the miners arrived, they packed their sacks of gold dine.
to Selby's office.
They were a picturesque collection of bags was produced.
Some were made of deer hide and held as much as 2,500 pounds.
Several of the miners ran out of even canvas bags
and were forced with their gold in tumblers and fruit jars,
which they covered with writing paper.
They looked like fruit or jelly put up by country housewives.
All the bags were weighed, and then, as fast as the weight was recorded,
They were slid open with a sharp knife, and the contents poured upon the broad counter, which had a depression in the middle.
The heap of gold dust looked like a pile of yellow-shelled corn.
Thousands of gold-seekers of both sexes and all classes were soon hurrying to Pacific ports, bound for Klondike,
not caring how they should reach the happy hunting grounds as long as they got there.
The mining towns of Colorado and California were just certain.
by their inhabitants, who turned what they could into money and joined the rush.
The fever spread rapidly to inland towns, even to Europe and Australia.
Men of all ranks threw up their ordinary occupations and shipped for Alaska.
At Seattle, Washington, half the police force resigned, and the street cars had to cease running for lack of drivers.
By every mail came in fresh accounts of the Klondike wonders.
some doubtless, very greatly exaggerated. The following, which appeared in the Manchester Guardian of October 17, 1897, is, however, the statement of a responsible person, Mr. William Ogilvie, a Canadian government surveyor, and as such may be trusted.
Talking of the reports of wonderful accounts of gold taken out in a single pan, Mr. Ogilvie came some of his own experiences.
He went into one of the richest claims that asked to be allowed to wash out a panful of gold.
The pastryque was then very rich, but standing at the bottom of the shaft,
looking at it by the light of a candle,
all that can be seen of the pastry was a yellowish-looking dirt,
which here and there the sparkle of a little gold.
Mr. Ogovee took out a big panful and began to wash it out,
while several miners stood about guessing as to the result.
$500 was the top guess of the miners, but when the gold was washed, dried, and weighed, it came to a little over $590.
How were the gold seekers to reach the land of promise? Though no fewer than nine routes were practicable in the summer, three only were generally employed.
The easiest and longest was an all-water route by steamy to the mouth of the Yukon and thence of the river, a distance of four.
thousand miles in all. This occupied any period up to a month, though if the river steamer were
unlucky, a much longer time might be required to pilot her through the many snags and sandbars
lurking in the unsurveyed journal of the Yukon. Impatient people therefore preferred the
overland route, some 2,500 miles shorter, via the Chilkoot and white passes of the St. Elias
range. If he meant to utilize one of these, the adventurer booked a passage to Juno,
where the outfit, mining tools, cooking apparatus, clothes, guns, and large quantities of
provisions sufficient to last for six months must be purchased. Having laid out his money to the best
advantage, he proceeded to Daiya or Skagway at the head of the Lynn Canal, according to whether
his choice was the Chilcote or the White Pass. At either place, owing to the shallow anchorage,
the traveler often had to wade ashore. Then he raked up a tent and sought porters to carry his goods
to the foot of the paths. We will picture the fortunes of an 1897 goalseeker in the Chilkoot.
First came a nine-mile tramp over very rough ground to sheep camp at the rate of a mile and hour.
He had to make several journeys over this piece.
if carriers were few and is baggage bulky.
This took about four days.
At sheep camp, wood was scarce and a fire sorely needed.
Portals having been engaged, the mountains proper must be tackled.
Absolutely no vestige of a trail existed over the snowed plateaus,
which rose in front, cut across by deep crevasses,
the work of some raging mountain stream.
If a blizzard overtook the party, as very often happened,
They had to stop, roll themselves up as best they might, and wait until the storm abated.
The last part of the ascent was terrible, an almost perpendicular climb up rocks,
where a balder might easily be dislodged and sent crashing down on some luckless person below.
I have rupt it, said Mr. Harry De Wint, for the past 15 years in Siberia, in Borneo, and in Chinese tartary.
But I can safely describe that climb over the Chile,
as the severest physical experience of my life.
In 1898, an aerial wire rope trainway was established to transport baggage up this precipice
at the rate of ascent a pound. From the top, the descent inland was so precipitous that slaves
had to be given their head as it was impossible to hold them back. Then came a succession of journeys
to Crater Lake, from which place Lake Linderman,
The first of a chain was soon reached, and a couple more days brought him to Lake Bennett.
The traveler's troubles were by no means over, for he must now build a boat, raft, something to carry him 500 miles through lakes and rapids.
This was a difficult job even for a professional boat builder, as trees must be felled and cut into planks before he could think of beginning work on his craft.
If fortunate, he might possibly pick up a ready-made skiff for $100 of so.
Ten chances to one there was not such a thing for sale.
Of course, if the outfit did not include all proper tools and materials for clocking the boat seams,
in advance became almost impossible.
Here is a picture of Lake Bennett in June 1898.
It was a busy shipbuilding port, turning out more boats in a given time than probably
any other town in the world, large or small. The skilled and the unskilled were hewing and
clocking, all bent upon the one common theme of having a boat, and by means of it reaching
Dawson, or someplace in near proximity to the gold fields. No more inspiring lesson
teaching man's ingenuity and determination could be found in this one of nature's shipyard.
One and all seemed to have got suited and fitted, and within a period of some two months, not
less than 2,000 craft, sailboats, scows, and canoes, many of the lighter ones brought bodily over
the passes were launched upon the still icy waters of Lake Bennett. Leaving the lakes, the voyage
entered the upper Yukon and soon reached the Grand Canyon Rapids, nearly a mile long, where the river
is suddenly contracted to a width of 100 feet. The waves run high, and if the boat should be swamped,
there is little chance of getting out as the sides of sheer rock.
From here to the White Horse Rapids, known as the Miner's Grave,
from the many casualties that have taken place in their turbulent waters,
is very bad going.
At the Rapids, a portage must be made.
Lake La Barge is next reached,
a lovely piece of water with practically no current flowing through it.
Then the river again, and its strong stream carrying the boat,
60 to 70 miles a day. On pass little salmon ribbed to five-fingers rapids,
rush rapids, and brink rapids, after which the dangers of travel are pretty well over,
and the Klondike is reached at last. Should the white pass have been chosen, the difficulties of
the mountains were lessened, partly because the gradients are not so severe, partly because
it has an altitude of over 1,000 feet less than the Choucout.
The distance, about 40 miles from Skagway, the port of landing, could, under favorable circumstances,
be covered in a day and a half. From Lake Bennett, the route is the same as that already described.
During the rush of 98, this pass was largely used, and sad traces of man's cupidity remain to mark the event.
The Desert of Sahara, writes Mr. Helparton, after crossing the pass in 1898, with its slidstance,
lines of skeletons can boast of no such exhibition of carcasses. Long before Bennett was reached,
I had taken count of more than a thousand unfortunates, horses, whose bodies now made up part of the
trail. Frequently we were obliged to pass directly over these ghastly figures of hide,
and sometimes indeed broke into them. Men whose veracity need not be questioned assured me
that what I saw was in no way the full picture of the life of the life of the
trail. The carcasses of that time were less than one-third of the full number, which in April and May
gave grim character to the route to the new El Dorado. Equally spread out, this number would mean
one dead animal for every 60 feet of distance. The poor beasts succumbed not so much to the
hardships of the trail as to lack of care and the inhuman treatment which they received
at the hands of their owners. Once out of the line of the mad rush, perhaps a
able to extricate themselves from the holding meshes of soft snow and of quagmires they were allowed to remain where they were a food offering to the army of carrion eaters which were hovering about only too certain of the meal which was being prepared for them
oftentimes pack saddles and sometimes even the packs were allowed to remain with the struggling or sunken animal such was the mad race which the greed of gold inspired after the eighteen
In 1997, Rush Dawson, the Frisco of the North, as it has been called, sprang up on the right bank of the Yukon, in the angle between that river and the Klondike.
On the opposite side of the Klondike is the town named after it.
Early in 1897, Dawson was only a small group of huts, housing a few hundred miners.
No less than 5,000 entered the Yukon country in the summer of that year, and about 40,000 in the summer following.
By the autumn of 1898, Dawson counted at least 20,000 inhabitants, and at all the usual features of a boom town.
That is to say, most of the buildings were of a somewhat ramshackle nature, and prices ruled high.
Supplies came in very irregularly by steamers from St. Michael's.
The population was not a mere horde of prospectors intent upon acquiring gold at all costs,
but a medley in which counts, naval and military officers, scientists, lawyers, pressmen, and storekeepers jostled one another.
You had your choice of three weekly newspapers, several theaters of a sword, an almost unlimited number of saloons, and a couple of banks.
The insecurity of life and property usually associated with mining towns did not exist here, thanks mainly to the efficiency of the Canadian Mounted Belief.
So much did people trust one another that if a purchaser entered a store, he said what he wished to have
through his bag of gold dust on the counter and turned his back while the storekeeper waded out.
To watch him would have been flagrantly bad form as implying mistrust of his honesty.
One storekeeper did take a mean advantage of a customer, and he was promptly removed in a manner
resorted to in communities where rough justice and revolvers formed judge and executioner.
A Dawson Hotel was not much to look at in those days, but what it lacked in comforts,
it made up for in-charges. A guest room was generally innocent of looking glass, washing apparatus,
candlestick, window panes, replaced by canvas. But for what it could boast in the way of a bed,
26 shillings a night might be asked. Board cost about 20,000.
Quinty shillings more a day. Yet, as regards the commissariat, the figure is not excessive in view of
current prices. Mr. Heilbrun details some of these. Oranges and lemons, 75 cents apiece. Apples 25 cents,
potatoes and onions, 75 cents the pound. Butter, one dollar to pound. Eggs, presumably fresh,
but ordinarily with a stale inheritance, two and a half dollars for dozen. Basses, ale,
2.5 dollars a pint. Sugar, 30 cents a pound. Watermelons, for which the Yankee has a loving
tooth, could not be bought for less than $25 each, and in scarce times, a cucumber fetched $5.
Haye touched tremendous prices, $1,400 per ton. All this has, of course, been changed by the
improvement in methods of communication, from the middle of May to the middle of October,
about 55 stern-wheel steamboats ply between Dawson and St. Michael's.
The pilots know the snags, bars, and channel waves of the Yukon, as well as those of the Mississippi.
As the river in its broader parts has a current of only three miles an hour,
the powerful engines drive the boats up to 1600 miles in about nine days,
and down in a much shorter time.
When the river freezes, the sleigh traffic begins over the smooth ice at the sea.
its edge, both from St. Michael's and from the Upper Lakes inside the passes.
Marvelous indeed is the change that has come over the township. It has as a writer in the world's
work. Speaking of the year 1903, a splendid system of waterworks, a local telephone system
and long-distance connection with the principal minds, telegraphic communication with the world,
churches of every denomination, large federal and municipal buildings,
and good schools. The streets are all thoroughly lighted by electricity. Lines have steamboats along
the wharves, loading and unloading, and steam dredges at work in the river, give an animated
aspect to the waterfront. Three years ago, the inhabitants of Dawson lived principally on dried
and canned meats and German sliced evaporated potatoes. Today, fresh meat is brought in,
frozen in winter, and in refrigerated cars to white horse in summer.
and all vegetables are grown in market gardens nearby.
Nothing pleases the Dawson citizen,
more than to entertain a skeptical visitor from the south,
at table with lettuce, asparagus, green peas, or celery,
cauliflower, cabbage, and carrots,
according to the season, grown in his own breered yard.
About three miles of the Klondack River from Dawson
is the Bonanza Creek,
the scene of the first important finds.
Following the Bonanza 13 miles of so, the El Dorado Creek is struck.
The trail formerly used by the miners was much impeded by morasses,
through which the pedestrian plowed his way,
trusting to his high waterproof boots to keep out most of the wet.
But matters have been much improved since then,
and the claim owner reaches his property without much trouble.
In winter, slays are largely used, over the streams,
up which a good dog team will make the journey to El Dorado in three hours.
A few words about the conduct places or surface claims.
Due to the prospect, the El Dorado looked on promising enough,
with its dense alvecroft of bushes, trees, and moss.
He might easily have passed through the valleys without suspecting
that under that shaggy mantle lay vast quantities of gravel.
Pebbles chipped off the rocks of the region,
but water and water.
worn to smoothness, among which lurk mingle clay and gold, the latter increasing in bulk
at bedrock level. A creek claim, i.e., one including a length of the stream, is 250 feet long,
measured in the general direction of the creek. The breadth varies with the nature of the slopes
on either side. If the slopes are gentle, the line drawn horizontally at a level three
feet above the edge of the water, may run several hundreds of feet before the rim rock of the slopes
is reached, so a maximum breadth of 1,000 feet has been fixed by the mining laws. A river claim can be
staked out on one side only of the stream, and has the same maximum area as the creek claim,
and a hill claim is similarly restricted. All other place of claims are 250 feet square.
The Canadian government reserves every Alder.
10 claims, which can be disposed of in the way most advantageous to the authorities.
Any trespasser upon the Crown claim loses such rights as they may have secured previously in private claims.
To encourage discovery, any minor or party of minors who strike a new mine get claims of double-size up to two members.
Though no minor can receive a grant of more than one claim in one district, he is at liberty to purchase the claim.
of other people, and many fortunes have been made by individuals who bought with the previous
owners considered to be worthless properties. In order to prevent useless occupation of a claim,
it is stipulated that if an occupier fails to work his claim for 72 consecutive hours,
he forfeits his rights to it, unless the satisfactory reason can be assigned for his absence.
It would be tedious to enumerate the dozens of other rules and regulations prevailing in the district,
and it must suffice to add that illegal jumping of claims, an unsavory feature of the Californian and Australian gold fields, is unknown in the Klondike.
On the Bonanza and El Dorado, which by now had been largely worked out, the primitive method of panning has been replaced by scientific sluicing and high pressure hydrolyzing.
The output of the Klondike regions showed, at least until 1902, some fluctuation, but very large totals.
In 1899, the miners won $16 million, in 1900, 22 and a quarter millions.
In 1901, 18 millions, and 20 millions in 1902.
Doubtless the time will come when more capital than at present will be spent on large dredgers
to scoop up the deposits of the sandbars and river beds
and pass them through sluzing boxes with an effective bucket tracker.
A very small yield of gold per cubic yard more than repays the cost of working.
The method has been used, as we have seen, very successfully in California.
Miners, gold miners, have always done more than any other class of people
to are developing the resources of the West.
Weren't for the discovery of gold in California of 18,000.
They would not have been built a transcontinental railway until many years after 1868, and today, much of the great country west of the Mississippi River would be practically a wilderness.
These words, written of California, apply equally to northwest Canada and Alaska.
The development of the huge tract, as large as all Europe, Russia excluded, during the last decade, has been nothing short of phenomenal.
Alaska, like other sub-arctic countries, is subject to great extremes of temperature, 95 degrees Fahrenheit in the summer, 70 to 80 degrees below zero in the winter.
A person traveling up the Yukon in the warmer months would be astonished by what he saw after what he had read.
Not a vestige of snow in sight, but flanking the river matted, luxurious vegetation.
Wheat, a fine quality, is now raised in Alaska.
also stock. Besides gold, there are rich deposits of iron, nickel, copper, coal, only awaiting the advent of the railway to be mined in large quantities.
Already the iron horse has arrived. In June 1898, a syndicate of English capitalists began work on what is now known as the White Pass and Yukon Railway,
running from Skagway through the mountains to Lake Bennett, though its length is but 112 miles.
It ranks high as an engineering achievement.
Possibly, it was the most difficult bit of railway work ever performed.
While clearing the trail for the track, the navvies had to collect about 2,000 dead horses into heaps and burn them with kerosene.
Parts of the railway cost 50,000 pounds a mile.
The total expenditure reaching 1 million pounds.
So much needed was the road, however, that the first two years running,
showed profits of 400,000 pounds,
and shares, which at one time had been going begging,
at $6.5,000, sold at $750 a piece.
The track builder is hard at work in other parts of Alaska.
From Nome to Anvil Creek, a five-mile line has been laid,
the Wild Goose Road, which in spite of its title,
has also proved a very good dividend earner.
Suez Peninsula, on which Nome,
a city of 25,000 inhabitants is built, will shortly be grid-eyed by railways leading to and from
the principal gold mines and forming the western feeders of a main trans-Atlaskan system.
In 1902, a track 82 miles long stretched from West Dawson to Stewart River, from which point
to the lakes, the iron horse will probably soon be running. A railway has also been planned from Valdez,
the most northerly ice-re port of Alaska to Tanana on the Yukon, 430 miles away,
and more ambitious still, a great artery running southwards to join the Canadian transcontinental
metals. When these schemes are completed, it will be possible to travel continuously from
Ottawa or New York to Nome and on to the westernmost point of Alaska, once a submarine tunnel
under the Bering Streets, would provide a still longer run of seven thousand miles to Paris.
Alaska may be cold, mosquito-infested, fly-bitten, but she is well worth the 1,430,000 pounds
paid by the United States to Russia in 1867. A great future lies before her, one of which the gold
industry may eventually recede into the background. Yet the day, when George Carmack
lit his campfire, burnt away the moss, and discovered the rich gravel, is that from which the
new era will be dated, as California and Australia were boomed by their gold rushes, and have since
gained the larger part of their wealth from agricultural and grazing pursuits. So may the Yukon
District be known to our descendants as one of the great wheat and timber-producing countries
of the world. And a chapter 7. Chapter 8 of the Romantic
of mining. This is a Librivox recording. All Librivox recordings are in the public domain. For more
information or to volunteer, please visit Librivox.org. Read by Jennifer Beckett Wood. The Romance
of Mining by Archibald Williams. Diamond Mining
Round No Substance Woveen itself more thickly than round the diamond. The mere mint
of this precious stone, the unconquerable, conjures up thoughts of royal jewels, of glittering
assemblies where the rich vie with one another in the splendour of their ornaments, of the marvellous
Arabian knights, of Sinbad, rock-borne into the valley where riches gleamed on every side,
of the battles and struggles from which an historic jewel has emerged to be lost, maybe, in obscurity.
The diamond has taken such a hold on the popular imagination that, were the stories collected which have the fortunes of this precious stone as their theme, a small library would be the result.
No wonder then that ignorant folk have attributed to it many curious properties.
In his natural history, Pliny writes,
The most valuable thing on earth is the diamond, known only to kings, and by them imperfectly.
It is engendered in the purest gold only.
Six different kinds are known,
among these the Indian and Arabian
of such indomitable unspeakable hardness
that when laid on the anvil
it gives the blowback in such force
as to shiver the hammer anvil to pieces.
It can also resist fire,
for it is incapable of being burnt.
This superiority over steel and fire
is subdued by goat's blood,
in which it must be soaked when the blood is fresh and warm.
Then only, when the hammer is wielded
with such force as to break both it and the anvil,
will it yield.
Only a god could have communicated
such a valuable secret to mankind.
When at last it yields by means of goat's blood,
it falls into pieces so small
that they can scarcely be seen.
Behind these curious ideas,
there is a modicum of truth.
Exceeding hardness is the most peculiar quality of the diamond,
which can be scratched by no other substance,
while it will make its mark on any body over which it is drawn.
As regards its unbreakableness,
we can only say that many a fine gem has been spoilt by the anvil and hammer test,
and, so far as its heat-resisting properties are concerned,
a diamond soon crumbles to ash if submitted to the temperature,
of the electric arc.
Its combustibility was first established in 1694
by some Florentines
who directed on some small specimens
that concentrated heat
of very powerful burning glasses.
Later scientific research
has clearly established
the chemical character of the stone
as pure carbon,
a cousin of coal,
which is consequently termed
black diamonds.
The extreme hard
of the diamond has made it an extremely useful ally to the geologist and engineer, who arm with
it the tip of the circular, hollow, boring tool, which eats its way through thousands of feet of
the toughest rock before any replacement of the stones becomes necessary. In a more humble way,
the glazier uses a tiny splinter of diamond mounted in metal to cleave the surface of glass.
this very property militated for centuries against the estimation in which the diamond is now held.
Until its surface has been shaped into those wonderful facets which sparkle with refracted light,
the gem is not much to look at.
Only after Ludwig van Bergen discovered in 1476 the method of polishing and grinding it by means of its own dust
did the diamond step into the foremost place
which it now occupies among jewels.
Not that it is the most valuable
weight for weight,
since the Oriental Ruby far transcends it in this respect.
Amsterdam is the great centre of diamond cutting and polishing.
That town contains over 60 factories.
Every diamond passes through three processes
before it is fit for sale as a jewel.
Viz, splitting, performed quick,
by very skillful workman with a diamond knife,
cutting off the sharp angles in a similar manner,
and polishing by machinery.
A brilliant is given 58 facets,
a rose 24, the workman pressing it against a wheel,
coated with oil and diamond dust.
All three processes demand great care,
for a false stroke might reduce the value of a stone
to but a fraction of its original worth.
The word carrot, signifying a standard of weight for precious stones,
will be used so frequently in the following pages that a few words about it are necessary.
Carrot is probably derived from the name of an African bean,
which, when dried, is very consistent in its weight,
and therefore was employed in remote times by African gold merchants as their standard.
The English ounce Troy is equivalent to 151,000,
and a half carrots, so that a single English carrot equals about 3.174 grains.
In foreign countries, the weight varies from 105 milligrams in Spain to 206.13 milligrams in
Vienna. For our purpose, the English carrot is always used. In its purest condition, the diamond
is quite colourless and transparent. If slightly tinted with yellow,
green, blue, red, or brown, its value decreases, but deeply coloured gems are very highly prized.
From Borneo come black diamonds of great beauty and such hardness that ordinary diamond dust will not polish them,
and the adage, diamond cuts diamond, holds true only if their own dust be used for the purpose.
For many years India was practically the sole source of diamonds.
The eastern side of the Decan, Madras and the country round Nagpur have yielded most of the finest Indian specimens, including the individual jewels which have each a romantic history of its own.
The great mogul, the Kohinur, the pit, the Nizam, the great table, the Orloff.
Most of these have been won from alluvial deposits by poor miners of a very low caste working for the princes.
of the land. Goldconda, a name associated with the diamond, is an ancient fortress to which the miners
brought their fines to receive some trifling reward in return. Presently a rival country appeared.
In 1727, a Brazilian Bernadino Lobo, who had seen rough diamonds in India, was struck by the
resemblance between these and little hard stones which the gold diggers of Minas Gerais,
Brazil, occasionally found, and used as counters for card-playing. He took a number of them to Portugal
for sale, and their valuable nature was established. The European merchants, frightened,
lest the new discovery should prejudice their trade in Indian gems, industriously spread the report
that the Brazilian specimens were only the refuse of Indian stones imported into Brazil for subsequent
export. In reply, the Portuguese sent their gems to India, where they were labelled as
Indian stones, and obtained Indian prices. In two centuries, Minas Gerais produced nine
million pounds worth of diamonds. The discovery of these precious stones, writes a great authority,
in 1746, proved a great curse to the poor inhabitants on the banks of the diamond rivers.
Scarcely had the news of the discovery reached the government,
ere they tried to secure the riches of these rivers for the crown.
To affect this, the inhabitants were driven away from their homes
to wild, faraway places, and deprived of their little possessions.
Nature herself seemed to take part against them,
for a dreadful drought, succeeded by a violent earthquake,
increased their distress.
Many of them perished, but those who lived to return were bened,
evidently reinstated in their rightful possessions. Strange to say on their return, the earth seemed
strewn with diamonds. After a heavy shower, the children would find gold in the streets,
and in the brooks which traversed them, and would often take home three or four carrots of diamonds.
One negro found a diamond at the root of a vegetable in his garden. Poultry, in picking up their
food, swallowed diamonds, so that their viscera required searching before, being.
being disposed of.
Attention was presently diverted from Minas Gerais to the rich diamond fields of Bahia,
the old capital of Brazil.
A Minas Garayas Negro, employed as a shepherd, noticing the similarity of the soil to that
of his native place, searched the sand for precious stones, and soon amassed 700 carrots,
which he took for sale to a distant city.
Such wealth led to suspicion, and the negro was arrested and returned to his master,
who had him watched and learned his secret.
Before a twelve-month was out, twenty-five thousand people had flocked to Bahaya,
causing a panic in Minas Gareas.
Business there ceased, and the price of diamonds dwindled to one half.
But Bahaya's evil day arrived also, when the precious stone was first found in 1868,
in South Africa, henceforth the chief source of the world's supply.
The story of the wonderful Kimberley deposits begins with the action of a little Boer child,
which amused itself by collecting pebbles from the river.
One of these was so bright that it caught the eye of the child's mother,
who took it indoors and showed it sometime afterwards to a neighbouring farmer,
Shalk van Nierkirk.
He, not knowing its true character, but thinking that it might have,
some value, offered to buy it. The woman laughingly said he was welcome to have it for nothing.
Neerkerk, in turn, submitted the stone to an English trader, Mr. J. O'Reilly, who offered to take it down
to the coast and let the experts have a look at it, he to share any profits with the owner.
O'Reilly, while passing through Colesburg, cut his initials with the stone on one of the hotel windows
and pronounced that he had got a diamond. But the people put him.
present were so incredulous that one of them took the thing and threw it into the street,
whence it was recovered only after a long search.
At Grahamstown, scientific tests revealed a genuine diamond.
The stone, which weighed 21 and 3.16th carrots, was sent to the Universal Exhibition in Paris,
and afterwards found a purchaser for the sum of £500.
We may only hope that the poor Dutch Vrao never,
got to know the full history of the pebble which he had so light-heartedly given away.
This stone was discovered at Hope Town on the Orange River in the district named Greco Land West.
Many seekers soon began to turn over the Velt's surface and to paddle in the Vile River.
An organised party under Mr. J.B. Robinson established themselves at Hebron
and systematically set to work to trace the stray stones to their origin, which was ultimately
established near Kimberley in the dry diggings known as Du Trois Pan, De Beers, Boulfontein and Vesselton.
But this happened by accident. A farmer, named Van Vique, was surprised to find diamonds embedded in the
clay of which his house walls were built. Arguing that the place from which the clay had come might
reasonably be expected to yield more stones, he began to dig, and so opened the famous Du Bois Pan,
14 miles south of the Vile River.
The discovery of the diamond-diferous nature of the Du Troyes-Pan
caused an immediate rush to the farm,
now surrounded by a suburb of Kimberley,
a town 650 miles north of Cape Town,
supplied with all the comforts and luxuries of life.
In Kimberley itself are the Kimberley and De Beers mines.
The Du Trois Pan and Boulfontein mines lied two miles south,
and the premier mine, formerly Vesselton, is three miles to the southeast.
Geologically, the diamond mines are unique.
Volcanic action has burst open the overlying quartz shale, an igneous rock,
and squirted up a chimney of diamond-diferous rock called Blue Earth,
though it is extremely hard.
The chimneys, or pipes, are roughly elliptical or circular insection,
their area varying at different depths.
Some are thousands of feet across.
How far down they reach is uncertain.
Very probably they extend to the fiery core of the earth.
Some pipes are absolutely barren of diamonds,
but those named above have proved themselves so rich
that they now supply nine-tenths of the world's annual yield
and completely control the market value of diamonds.
In 1872, miners began to peg out claims in the Kimberley pan,
30 feet square and each man dug where he felt so disposed.
Between the claims ran roadways for the purpose of transporting the dirt.
After a very short time it became evident that the roadways and also the less energetically mined claims
would prove a danger to the workers on claims which had been sunk to a considerable depth.
Every now and then there was a landslip, burying tools, machinery and sometimes human beings.
resulted in endless lawsuits, the one party asking compensation for the entombment of his property,
the other seeking damages for the undercutting of his higher ground.
As the general level of the excavation sank, the difficulty of removing the earth increased,
and, the roadways being useless, platforms were established on the rim of the crater to which
buckets could be transported on wire ropes.
This got over the trouble to a certain extent.
but when water appeared in large quantities, the miners were confronted with an extremely
awkward problem. It was at once nobody's and everybody's business to pump out the intruder,
which distributed itself impartially among the claims, and, as is usual in such a case,
nobody took the matter in hand. The workings fell in, and today there is a crater 650 feet deep,
which, as Mr Stafford's ransom remarks, is probably the largest open hole ever made by man.
During the claim-working days, the CAFIA labourers pilfered stones in great quantities
and sold them to that obnoxious individual, the illicit diamond buyer, known for short as
IDB. It is said that at least half of the diamonds found were thus disposed of, so that mining,
which otherwise would have been profitable, soon proved a dismal failure.
The individual miner therefore sold his rights to syndicates or small companies,
these in turn amalgamated into large companies,
to be finally all swallowed up by one gigantic concern called the De Beers Company,
which controls the industry to an extent unparalleled in other branches of mining.
At the De Beers, Kimberley and Bulfontein mines, the blue ground is worked by deep shafts,
driven down through the rock outside the pipe.
The Premier Mine has already reached the stage when open mining ceases to be advisable,
and too soon will have its shafts.
About the process of getting out the dam andiferous rock, little need be said,
as it resembles coal mining in most particulars.
We may notice, however, that,
Owing to the huge capital possessed by the company,
every improvement in machinery is eagerly adopted.
Out-of-date tackle soon finds its way to the scrap heap,
which to the uninitiated eye might suggest a terrible waste of good stuff.
The shafts are so deep, 2,000 feet and more in some cases,
that high-speed winding becomes important.
Skips fly up and down with four-ton loads at nearly 25 miles an hour,
and automatically discharge their contents into the headgear bins,
from which they pass down shoots to the ground level.
The method of separating the diamonds from their matrix is most interesting.
Fortunately for the proprietors, blue ground rapidly disintegrates
when exposed to the action of heat, cold and water.
So before introduction to the crushing mills,
the material is spread a foot deep over rectangular areas,
known as floors, measuring 400 by 200 yards, previously stripped of all grass, bush or loose stones.
A harrow is occasionally drawn backwards and forwards over the rock by steam engines to aid the crumbling,
water being squirted freely if the weather remains dry.
At the end of a year, the ground, now fit for crushing, is washed and churned in a mill which separates the heavier from the lighter portions.
The concentrates are taken to the pulsator, an automatic diamond finder, and from it are allowed to drop by means of a carefully regulated feed onto the highest of a series of inclined trays arranged in the form of a shallow ramp or staircase.
These trays have a pulsating or vertically vibrating movement, which gives its name to the machine.
The upper surfaces of these trays are covered with a thickish layer of stouther,
lubricant, which has for its object the retention of any diamonds that may come into contact with
it. The important discovery of sorting diamonds by adhesion arose from noticing that the
stones stuck to any grease that fell into the old-fashioned washing pans. A test was made with
very small stones aggregating 6,601 carrots, out of which only 111 carrots escaped the grease.
With coarser material, only 40 and a quarter out of 19,031 carrots got away,
which proved that the larger stones are less likely to be lost than the smaller.
Apart from its effectiveness, this system does away with native labour
and the need for a great amount of supervision.
The grease and its adherents are scraped off the trays and consigned to a melting pot,
which quickly sends the stones and the rubbish to the bottom.
The grease runs off, leaving the deposit free for inspection and sorting, done by highly trained experts.
The stones are then washed in sulphuric acid and sent to the head office in Kimberley to be more perfectly classified and stored ready for sale.
The sorters here work in a carefully locked office to which the visitor is only admitted on production of a pass,
and after being scrutinised suspiciously through a little grill in the door.
And when he gets inside this holy of holies,
he finds himself railed off from the counters
on which the piles of gems are being sorted,
in case the sight of such vast riches
should cause his cupidity to get the better of his morality.
About 15,000 kaffirs and 2,500 whites are employed in the mines.
The nature of their words,
necessitates a strict guard being set on the kaffirs for there are the expertist of thieves to let them go in and out of the mines would mean the loss of many valuable stones they are therefore obliged to sign a contract for a period of at least six months work during which no egress from the mine compound is permitted once in always in till their term has been completed not that they fare badly since stores in the compound
furnish anything they may wish to buy. They have clean, neat houses, a hospital,
swimming baths, and a chapel where a native preacher holds forth on Sundays, helped by an interpreter
who translates his dialect into one more readily understood by the audience. It is to the credit
of the De Beers Company that intoxicants of all kinds are rigorously forbidden on the premises. A great
contrast to the drink-sodden compounds of the Rand before the war.
With no less than four million pounds worth of diamonds lying in the disintegrating blue ground,
some theft occurs in spite of the utmost vigilance. Guards are always patrolling the boundary,
strongly fenced with barbed wire entanglements. At night, strong arc lamps light up the floors,
so that any would-be pilferer may be seen by the watch. The Kimberley-companes,
are covered with a wire netting
to prevent the throwing out of diamonds
it being found that old tins
and similar articles were
utilised for this purpose
on the chance of picking them up outside
the walls after dismissal.
The amount of material
raised from the diamond mines
is astonishing.
Up to May 1, 1883
10,3,3,325,9
loads of 16 cubic feet
each had been removed from the Kimberley mine alone, equivalent to 3,824,440 cubic yards of
solid rock at a cost of 1,545,358 pounds. In 1883, 1,688,914 loads of reef were removed.
In 1884, 711,33 loads from this one mine.
An idea of the work done in the Debeer's mine in one fortnight may be obtained from the following figures.
During the first two weeks of November 1897, there were used 8 and 3 quarter tons of dynamite,
65,100 feet of fuse, equal to 12 and a third miles, and 32.3 miles, and 32,000.
thousand five hundred blasting caps, and during the previous month the record hoisting was made of
182,040 loads, or 1445,632 tons through one shaft and from the 1200 foot level.
The boys work below ground in gangs of 30 or 40 under the direction of a white miner or boss.
The mines being well lit and ventilated, and the drives of large size, their work is not unpleasant,
but there is one thing which they fear, as a coal miner fears fire damp, a mud rush.
The huge open excavations made in the early days form natural reservoirs for spring or rainwater,
which, together with fine particles of matter, sinks down through cracks in the form of a thick paste.
If this is tatt, it rushes with terrific force and speed through the galleries,
carrying trucks, rails and timbers before it irresistibly.
Sometimes there is loss of life,
and the authorities have now instituted a system of draining the overlying stratum
by means of pumps so as to prevent the accumulation of water.
From the De Beers mine, 5,000 gallons per hour are pumped.
From the Kimberley, double that quantity.
and the gradual decrease in the amount proves that the method is efficacious.
Reference has already been made to the control exercised by the De Beers Syndicate over the diamond markets of the world.
It has been shown by statistics that about £4.5 million sterling are spent yearly on this class of precious stone.
If all the year's product were suddenly offered for sale,
there would probably follow a slump or general fall in prices. Then again, the fashion changes from time to time. Now,
single big brilliance costing hundreds of pounds each are in demand. Now much smaller stones set closely together
in large numbers, while in bad times people will not invest in very costly jewels. But there is a
considerable public who do not mind the expenditure of a few pounds on cheaper stuff.
So the De Beers people carefully regulate the supply to meet the demand, keeping stored away under lock and key, huge quantities, tons, in fact, of jewels, and waiting for the moment when any one kind may be needed.
If the reserve becomes unwieldy, they simply decrease the number of their employees. Hence the syndicate has a unique and at present unchallenged position, an ideal one from the seller's point of view.
The nearest approach to arrival is the Yagas Fontaine mine, notable for having produced what is probably the second largest diamond ever mined by man, a monster of 971 carrots, or about six and a half ounces. It is a flat, almost rectangular stone, about two inches long and from 7 eighth inch to one and a half inches thick, of a blue-white tinge, a very fine colour, and of a value,
which cannot be computed. By the end of 1904, the total value of diamonds exported from South Africa
reached nearly £90 million. How much this amount will be increased before the mines stop working,
we cannot say. The blue ground may prove poor in stones as the mining proceeds,
or the depth to which it can be profitably worked may turn out to be more limited than at
at present appears probable. Or, and this,
is the most uncertain element of all to reckon with, mines of even greater richness may be
discovered elsewhere in the unexplored parts of Asia, Australia or America. For all we know,
wild animals may be browsing on land far away in the Pamirs or Andes, which in time will see
the rise of Diamond cities even greater than Kimberley. This chapter would not be complete
without a short reference to the siege of Darmondopolis during the war.
From October 1899 till February 15, 1900,
it stubbornly resisted all efforts of the Boers to reduce it.
Large numbers of the inhabitants took refuge from shells
in the old workings of the mines.
The De Beers Company, headed by Mr. Cecil Rhodes,
did its utmost to relieve the distress caused by scarcity and bad quality of provisions.
and also took an active part in the fighting their workshop staff under the supervision of mr labrum built the big gun named long cecil as a reply to the long tombs of the besieging force and with it hurled shells into the boer trenches
before quitting the fascinating subject of diamond mining some historic stones may be fitly passed in rapid review the great mogul this magnate
This magnificent stone was discovered about the middle of the 17th century.
Its weight of nearly 800 carrots places it next to the Gagas Fontaine and Cullinan jewels.
Tavernier, a French traveller, was shown the jewel by its owner, Shah Jahan, at Agra in 1665.
The first piece that Achaed Khan, keeper of the king's jewels, placed in my hands was the great diamond,
which is rose-cut, round, and very high on one side.
On the lower edge there is a slight crack and a little flaw in it.
Its water is fine and weighs 319.5 ratis, which makes 280 of our carrot.
In the rough state it weighed 787.5 carrots.
It was Hortensio Borges who cut it, for which he was also badly paid.
when it was cut he was reproached for having spoilt the stone which might have remained heavier
and instead of rewarding him for the work the king fined him ten thousand rupees
and would have taken more if he had possessed more
after the sack of Delhi by the Persian Nadia Shah
the stone disappears from history probably it was stolen during the sack or at the death
of Nadia and split up into a number of smaller stones
the koinor the most romantic of all diamonds its early antecedents are unknown but tradition mentions it as the property of a prince who lived in fifty seven b c
like the great mogul it had a place in shah jahan's treasury and subsequently in that of arun zeb nadia shah on entering delhi could not find the gem until a woman betrayed the secret that the emperor wore it concealed in his turn
How could he get hold of it? Mr Edwin Streeter thus tells the story. He skillfully availed himself
of a time-honoured oriental custom, seldom omitted by princes of equal rank on state occasions.
At the grand ceremony held a few days afterwards in Delhi for the purpose of reinstating Muhammad,
emperor of Delhi, on the throne of his Tatar ancestors, Nadia suddenly took the opportunity of
asking him to exchange turbans in token of reconciliation, and in order to cement the eternal
friendship that they had just sworn for each other. Taken completely aback by this sudden move,
and lacking the leisure, even for reflection, Muhammad found himself checkmated by his wily rival,
and was fain, with as much grace as possible, to accept the insidious request. Indeed, the Persian
conqueror left him no option, for he quickly removed.
his own national sheepskin headdress,
glittering with costly gems,
and replaced it with the emperor's turban.
Maintaining the proverbial self-command
of oriental potentates,
Mohammed betrayed his surprise and chagrin
by no outward sign,
and so indifferent did he seem to the exchange
that for a moment Nadia began to fear
he had been misled.
Anxious to be relieved of his doubts,
he hastily dismissed the Durban,
with renewed assurances of friendship and devotion.
Withdrawing to his tent, he unfolded the turban to discover,
with selfish rapture, the long coveted stone.
He hailed the sparkling gem with the exclamation,
Coenure, signifying in English, mountain of light.
But possession brought misfortune to the possessor.
Nadia bequeathed it to his son, Roch,
who was overthrown by Aga Muhammad,
and tortured to reveal the hiding place of the stone.
All sorts of ghastly devices failed to extract the secret.
Roch, brinded and maimed, gave up the great ruby which Arung Zeb had worn in his crown,
yet he clung to the diamond as to life itself.
Before he died, he gave it to Ahmed Shah, founder of the Durrani Afghan Empire,
as a reward for help against Mohammed.
from Ahmed it passed to his son Taimin, from him to his son Zayman, deposed and blinded by a brother Shuzha,
who got hold of the stone by the merest accident. While in captivity, Zaman concealed it in a crevice
in his cell and covered it with plaster. The plaster fell off, a glittering corner protruded
and scratched a courtier's hand, and the jewel came into history once again. Shuzha was in
turned opposed by a younger brother and withdrew to the court of Vrunjit Singh, the lion of the Punjab,
who at first received him kindly, but later tried to extort his treasures from him,
especially the Coenur, and at last succeeded. He wore it on all public occasions.
When the English, in 1840, took possession of the Lahore treasury, the Coenure became the
property of the East India Company, and was sent to England.
as a present to Queen Victoria.
Its transference from east to west
appears to have changed its power for evil
into one for good,
as it arrived during the early years
of England's most glorious reign.
When it reached Europe,
it scaled 186 and 116th carrots,
subsequently reduced by recutting
to 106 and 116th carrots.
And now it is preserved
among the royal jewels at Windsor,
a model in the dual room of the tower acting proxy for exhibition purposes.
The pit, or regent, found in 1701 in the Partiel mines on the Kistner by a slave,
who concealed it in the hole, made purposely in his leg.
He escaped to the coast and gave it to a sea captain,
on condition that he should transport him to a free country.
The captain took the jewel and threw the poor slave into the sea.
Eventually it came into the hands of Thomas Pitt, who paid £20,000 for it, and afterwards sold it to the French regent, the Duke of Orleans, for £135,000.
With the great profit, Pitt restored the fortunes of his ancient house, which afterwards gave England two of her most distinguished statesmen.
In 1791, it was valued at £480,000. During 1792, it disappeared. During 1792, it disappeared.
from the French Royal Treasury, but was recovered and pawned to the Dutch government by Napoleon
to raise money. Afterwards redeemed, it found a last resting place in the now disused crown of France.
The Orloff, said originally to have formed the eye of an idol in a temple at Brahma at Srivangam
and to have been stolen by a French grenadier who sold it for two thousand pounds to an English sea captain.
He in turn sold it for 12,000 pounds to a Jew, who disposed of it to Prince Olaf, a courtier in the household of Catherine II of Russia, for 90,000 pounds.
Orloff gave it to Catherine, and it afterwards became the chief ornament of the imperial scepter.
The Cullinan discovered early in 1905 in the Premier Mine, Transvile.
The stone, which is by far the largest ever found, weighs 3,000.
32 carrots or nearly one and a half pounds of Wadupeau.
It measures four and a half inches by two and a quarter inches.
Its value is incalculable.
End of Chapter 8.
Chapter 9 of the Romance of Mining.
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The Romance of Mining by Archibald Williams
The Story of the Comstock Lode
Discovery of the Load
Henry Comstock
Silver ore cast aside is worthless
An assay proves its value
Rush to the mines
Difficulty treating the ore
Paul's Reduction Mill
The Timbering of the Mines
Litigation
Bonanza Times
Mark Twain
The Sanitary Flower Sack
Extent of the Mines
The Overland Telegraph
The New High Road
Its Maintenance
Rivalry between stage drivers
accidents
Depression
Labor Troubles
Water inroads, the Sutro Tunnel, a marvelous engineering feat,
hardships of tunnel driving, John W. McKay, the Virginia Consolidated,
perseverance brings fortune, the big bonanza, huge yields, wild speculation,
seen in the mines, high temperatures,
a sad contrast, the fate of the Comstock.
To a few barren acres, on the western slopes of the sterile Sierra Nevada,
belongs the honor of having yielded mankind, a greater bulk of riches
than any other area of equal size on the Earth's surface.
The great Comstock load is synonymous to those who know its history
with enormous fortunes, wild speculation,
heroic struggles against adverse circumstances,
Aladdin's cave realized, hopes disappointed,
chagrin unfathomable,
the lowest depths of commercial trickery,
gigantic games of chance,
marvelous feats of engineering,
money spent like water,
water in rushing like a flood, labor conducted under terrible conditions. All these ideas flashed through
the mind at the mere mention of the silver seam, which for 20 years was the sign assure of the
world's money markets. The Comstock load revealed itself very quietly. Just a decade after the
discovery of gold in California when men were penetrating the Sierra to seek new Eldoradoes.
Two miners, Patrick McLaughlin and Peter O'Reilly by name,
dug a waterhole in a gulch of the Carson River Valley.
The earth thrown out was a yellow sand mingled with small lumps of quartz and friable black rock,
which they were unable to recognize as stuff of any value,
and cast carelessly aside.
However, with the instinct of the prospector and from habit rather than any definite hopes,
they washed out a panful or two of the dirt, and to their surprise and delight saw the welcome
color. Again and again they washed, gold accumulated in their wallets. They were on the high road
to fortune. They had knocked at the doors of the Comstock's treasure house and found riches,
even on the scraper. Notice this, that while the great Nevada deposit is renowned chiefly for the
silver it has produced, it was the intermingled gold which brought it to light. But for those
superficial specks of gold, the millions of tons of silver ore might have lain under
discovered for many years to come. Nature had, as it were, scattered a trail of recognizable
metal to lead men into a branch of mining hitherto unpracticed in the United States.
While McLaughlin and O'Reilly were hard at work, there stumbled upon them one Henry Comstock,
whose otherwise contemptible personality will go down to history because it gave its name
to this wonderful mine.
An ex-trapper and fur trader,
restless yet lazy,
he had wandered about for years,
taking up a claim here and there
to soon quit it and resume his prospecting.
One evening he chanced to find the two Irishmen
cleaning up their rocker for the last time
before stopping work for the day.
His practiced eye took in the situation at a glance.
With matchless effrontery, he informed the lucky pair that they were trespassing on his land,
and by sheer talking prevailed upon them to concede his claims.
Thus it was that, though the true discoverers have been forgotten,
the name of Comstock has survived.
Other prospectors soon arrived and pegged out their lots,
while McLaughlin and O'Reilly opened up the pocket.
They were much hindered by a seam of black rock, which made its appearance at a depth of three
or four feet, and increased in width as the trench deepened. The looser earth on each side yielded,
however, sufficient gold to keep them at work. Presently curious visitors began to carry off bits
of the black rock, and in due course some specimens got into the hands of a Placerville assayer,
whose test showed a value per ton of 600 pounds in silver and 175 pounds in gold,
and the tidings spread that a load of silver sulfurettes had been struck on the eastern slope of
Mount Davidson in western Nevada.
Though silver mining was a new thing to the California miner, the Sierra passes became more and more
thickly choked by a stream of fortune hunters.
Quote,
rough-haired Mustangs,
gaunt mules,
and sure-footed little burrows
climbed the sierras loaded with sacks of blankets,
bacon, flour,
kettles, pans, shovels,
and other articles of a miner's outfit.
The ravines and brown hillsides
were dotted with a restless swarm.
Thin reaves of smoke,
rose from hundreds of little campfires on the hills, and the sharp strokes of falling picks
startled the lizards from their hiding places in the rocks.
End quote. Footnote. Monograph of the United States' geological survey.
California was on its way to grasp the treasures of Nevada, hitherto missed by the thousands
of immigrants who had trampled them unawares. In their
haste to reach the gold deposits of the Sacramento River.
This happened in the fall of 1859.
Not much prospecting could be done that year, and the early arrivals spent a cheerless hard winter
waiting for the time when work might begin in earnest.
Fierce whirlwinds howled through the gorges and down the sides of Mount Davidson, unroofing
the miserable huts and sweeping off flimsy te
tense. The occupants swore and erected other dwellings. What were the cold, hunger, and fatigue of
today? By comparison with the coming riches of tomorrow. Meanwhile, the exhibition of silver bars in
San Francisco had rekindled the fever of 1849 and 1850. The treasures of Patasi, the ransom of Montezuma,
The deep-laden galleons of Spain and a host of vague memories were awakened by the sight of
these masses of bullion.
The fever spread rapidly.
Merchants closed their counting houses and clerks left their desks.
Sailors deserted their ships and mechanics, their workshops.
The ranchmen from the plains and the restless swarm of gold placer miners
swelled the migration, not unlike the train of church.
drawn on by the entrancing notes of the piper of Hamlin.
How to reach the silver ledges was the absorbing thought.
Far beyond the sierras, the riches of their dreams appeared before them,
and neither inexperience nor poverty could deter such passionate pilgrims from joining the
odd troop, which began its march over the mountains while the passes were still
impassable. So early in 1860, every boat which left San Francisco for Sacramento was packed with
miners and their outfits. From the latter town, the army pushed up the old immigrant trail
to Placerville and thence over the Johnson Pass to the valley of Carson. Snow blockaded the
broken track. Hundreds of tons of freight accumulated in the California town, waiting until teams
could be found to carry it through the Sierra. At last in March, the caravans began to pour into
the mining camp on Mount Davidson, and soon crystallized into Virginia City, where for months
vice and rowdyism flourished unchecked. The true working miners were far outnumbered,
by the floating scum of California, who followed jackal-wise the movements of the metal-seekers.
Volunteers for the Indian War, demoralized by guerrilla warfare, flocked in,
lulled at the gambling tables and swaggered about the streets,
the terror of the more peaceful portion of the community.
A mining difficulty soon arose, or could be raised with ease,
but the extraction of the precious metal it contained was a serious problem.
Transportation to San Francisco for treatment ate up most of the profits,
while the lack of fuel made reduction on the spot almost an impossibility.
However, Almerin B. Paul, an enterprising mill owner of the city of Nevada, saw his opportunity,
raised the necessary capital and entered into contract with various mines to smelt all their ore at a fixed rate per ton,
and what was more, to commence smelting within 60 days of the signature of the contract.
Every pound of material used in the machinery had to be brought from San Francisco,
partly by water, partly overland along a track where the wagons sank to their axles in the mire,
and the mules, urged on by blows and curses, had to exert all their power to keep the cumbersome freight's in motion.
The cost of transportation exceeded the actual cost of the machinery.
The lumber used in the reduction mills touched fabulous prices.
Yet Mr. Paul was undismayed, and on the last day allowed by the contract, the Washoe Gold and Silver
Mining Company, number one, began to crush ore. So successful did the first crushings prove that
mine owners who had previously ridiculed the project gladly sent their ore to the mills,
and Mr. Paul entered upon the reward he so justly deserved.
difficulty number two now appeared as the load descended it steadily grew broader until at a depth of 175 feet
it was sixty-five feet wide such dimensions being without precedent the miners did not know how to proceed to leave pillars of ore to support the roof was of no avail with a roof that crumbled in
spliced timbers bent and broke, so that the owners at last found themselves surrounded by riches,
which they could not carry away except by risking their lives in doing so.
Expert advice was sought. Mr. Philip Diedesheimer, manager of a Georgetown quartz mine, came,
examined and designed a system of timbering, which exactly suited the particular needs of the
Comstock load.
To refer again to the authority already quoted.
This was to frame timbers together in rectangular sets.
Each set being composed of a square base placed horizontally,
formed of four timbers, sills, and cross pieces from four to six feet long,
surmounted at the corners by four posts from six to seven feet high,
and capped by a framework similar to the base.
The cap pieces forming the top of any set
were at the same time the sills or base of the next set above.
These sets could readily be extended to any required height
and over any given area,
forming a series of horizontal floors built up from the bottom sets
like the successive stories of a house.
The spaces between the timbers were filled with waste rock or with wooden braces,
forming a solid cube whenever the maximum degree of firmness was desired.
So the delving was continued to two, three, four hundred feet.
The Gould and Currie, Gold Hill, and Ofer mines poured out their riches.
For a couple of miles north and south ran the load.
fifty to eighty feet wide between its walls of solid rock.
Over so rich a prey there was, as may easily be understood,
plenty of quarreling.
And from 1860 to 1863,
the litigation arising out of disputes as to limits,
water rights, validity of claims, etc.,
choked the local courts,
where many an advocate hitherto unknown,
made a fortune out of his fees.
Into the intricacies of these actions at law,
there is no inducement to enter,
for only to the persons immediately concerned
could they possibly afford much interest.
They serve, however, to show that,
where a number of people settle down on a rich spoil,
they can no more dwell together in unity
than a number of vultures engaged on rending the same carcass.
The years 1863 and 1864 were the bonanza, that is, fair weather times.
Mark Twain is drawn with his facile pen a remarkable picture of how at this period men made each other
presence of feet in mines, just as in other localities one might offer a friend an apple or a pinch of snuff,
and how all sorts of tricks were resorted to by those who wished to turn a worthless shaft into a saleable property,
salting with genuine ore or even melted silver coins being included among these devices.
It may come as news to admirers of the novelist, who have not read his roughing it,
that Mr. Twain himself took a hand at mining, and in conjunction with two friends,
struck a blind lead, which crossed the wide west vein at an angle, pegged out claims,
and was a potential millionaire.
By an unfortunate misunderstanding, all three partners absented themselves from the claims,
each thinking that the other two would do the work necessary to keep the property in their possession.
When, at the end of nine days, they became aware of their danger,
two of them hurried back to find that they were just a few minutes too late,
and that eager onlookers had used their rights to relocate and jump their claims.
We would have been millionaires, he says,
if we had only worked with pick and spade one little day in our property,
and so secured our ownership.
I can always have it to say that I was absolutely and unquestionably worth a million
dollars, once for ten days. It was during this first boom that the sanitary flower sack
went its round of the mining towns of the Comstock District. The great civil war had broken out,
with the terrible suffering inseparable from such conflicts, and the hearts of the citizens
went forth to the wounded lying on distant battlefields. A sanitary fund had therefore,
been set on foot for the relief of the sufferers. And Nevada, anxious to do her share,
raised money in many ingenious ways. At Austin, a sack of flour was put up to auction,
the proceeds to go to the fund, and knocked down at $5,300. It then passed on to Silver City,
which bid $1,800 to Gold Hill, where the purchase was.
had to pay $6,587.5.00 to Virginia City, which advanced to $13,515.
From Nevada, willing hands carried it down to Carson, thence over the Sierras to California.
It finally found a haven in San Francisco, but not until it had enriched the fund by 30,000
pounds sterling. This was the miners' play. They could also work hard. At the close of 1862,
no fewer than 40 companies had erected houses of some sort over their shafts. And in several
instances, steam machinery was already installed for hoisting and pumping. Seen from the top
of Mount Davidson, the heaps of debris raised, appeared like Ant Hill,
gradually growing from day to day.
Some hills were almost deserted.
But all round the Mexican, California,
Gould and Curry, Potosi, and Chawyer claims,
men, horses, mules, and oxen swarmed.
The streets were blocked by vehicles,
hurrying this way and that.
Below the surface, an army of sweating miners
burrowed along the load, which, like the Rand Gold Reefs, sank at a considerable angle to the
perpendicular. Every day they advanced a few more feet, propping up the dangerous roof with a huge
skeleton of timber, each bulk of which had but a short time before been braving the strong
winds of the Sierra. The haphazard methods of 1860 gave place to a well-de-lawful.
ordered plan of working by cross-cuts, gallery, and winzes. In 1862, the Gould and Curry had over
five and a half miles of dismal drifts and tunnels, and the Comstock as a whole could boast 30 miles of
subterranean streets, thronged by 6,000 workers. By 1866, the borings had increased to 57 miles,
which represented but a fifth part of the ultimate total in after years.
Nevada produced five million pounds worth of bullion in 1863,
the year of the Nabobs,
who flew up and down the ladder of fortune like so many shuttlecocks.
The Gould and Curry Mine bought from its original owners for an old horse,
a bottle of whiskey, some blankets, and $2,500 in cash, was four years after the purchase,
valued at $7,600,000. A long list of fortunes thus lost and won might easily be made.
For the history of the Comstock is but a record of Peter impoverished,
and Paul raised to millionairedom.
Two great engineering feats mark the earlier years of the silver mine.
The first, the telegraph line carried from Omaha over the Rockies to Fort Churchill,
where it met a second line extending from San Francisco through the Sierra Nevada.
The Americans with characteristic energy put up 570 miles of this electric thread
in four months, a record all the more remarkable in view of the fact that its route lay through
the dreary wastes of the great desert. Thus, in 1861, Virginia City, the nerve center of wild
speculation, was in touch with the civilization of two coasts. The news of a big find on the
load became common property in San Francisco and New York almost before the discoverers had
realized their good fortune. The second service rendered by the engineer was that of making
a fine high road across the Sierra's via the Johnson Pass. During 1861 and 1862,
toll grants were obtained and a small army of large.
laborers was at work on both slopes of the range from foot to summit. The steepest grades were
cut down and smoothed. Gullies and ruts were filled with compact layers of broken stones and loam.
Bordering rocks were blasted away or rolled aside, and the narrow, dangerous, wretched trail
scarcely fit for the passage of sure-footed pack-mules,
became a broad, compact, well-graded highway,
which might fairly be likened to an old Roman road.
The stagecoach ride across the mountains,
which had hitherto been a torture,
became a pleasure.
The turning points of the road were broad platforms,
built up from the hillsides with outward curving base walls of well-joined rocks.
On the level surface of these bastions, an eight-mule team could turn without slacking their traces,
and loaded wagons could pass one another at all points on the road without difficulty.
When snowdrifts blocked the passage in winter,
a well-equipped party of men and horses sallied from me.
every station and cleared the way with extraordinary dispatch, while watering carts, passing
from station to station, laid the dust in summer, so that the road was like a well-kept avenue
in a mountain park. Great as the expense of making the road was, the builders soon reeked a harvest.
Every vehicle paid a toll, and at times the mule teams stretched in a continuous procession for miles.
Rivalry ran high among the stage drivers, for whom a fresh record ranked above the safe delivery of their charges.
Special coaches, with many relays of horses, covered the 130 miles between Virginia City and Sacramento,
in 12 and a half hours, a speed of travel which fairly eclipses the performances of the bath-road cracks.
Every now and then this time-cutting led to a serious accident, taken in good part by any survivors.
When a Johnson's past stage toppled over the brink of an embankment,
and the falling wreck was stayed by chance in the spreading arms of a large,
pine tree, the bruised passengers looked down upon the bottom of the abyss one thousand feet below
and congratulated themselves on their good fortune without censuring the coachman even in thought.
The excitement of travel arising from the possibility of such incidents being repeated
was increased by the frequent hold-up of a coach by masked desperadoes, who turned to the
out the passengers and stood them in a row with their hands over their heads, while their
persons and the coach was searched thoroughly for booty. Have we not read of these incidents in the
pages of Bret Hart? With the latter half of 1864 came the inevitable fall in the inflated
prices of mining shares. Some of the most valuable stock tumbled to one-fifth of the previous
year's quotations, dragging down the shareholders in wildcat schemes to absolute ruin.
The need for severe retrenchment of working expenses became imperative, and the mine
directors naturally lowered wages, which in the boom times had been fixed at $4 a day.
The miners, unable to see that labor as well as capital, must take its share in a
general depression, soon showed their teeth. John Trembath, the stalwart Cornish foreman of
the Uncle Sam mine, being suspected of sympathy with the proprietors, was seized while in one of the
lower levels, bound hand and foot, and lashed to the hoisting cable of the shaft. His captors then
tied to him a label with the words, dumped this waste dirt from corn,
wall. And thus mummified, the wretched man was lowered and hoisted twice. From this rough horseplay,
the miners passed to organize processions and the formation of a miners' league, which pledged
every member never to give a day's work for less than four dollars in gold and silver.
The league wilted under the economic effects of continued depression and practically went to pieces within a year.
It revived, however, with the return of prosperity to the Comstock, and is still a power in the district.
With these huge excavations being cut through a hillside, water, the bugbear of mining had by 1864 become a serious hindrance to,
to progress, notably in the case of the Ofer Mine. At the higher levels, horizontal shafts
or adits were driven through the wall to the open air, and these served for a time to drain off the
water. But when the shafts reached a depth of a thousand feet or more, pumping became the only
method of clearing the mines, unless a great combined effort were made and a main drainage tunnel
driven right through the hill at a level which would tap the whole load, nearly 2,000 feet below the
surface. In 1865, Mr. Adolph Sutro formed a company to construct a tunnel extending from the foothills
of the Carson Valley into the load, a distance of nearly four miles. He urged that all
mines sooner or later reach a depth where the constantly increasing cost of mining exceeds the
yield and that the Comstock load would, before the lapse of many years, provided no other means
for draining and working the mines were adopted, become practically valueless, and deprive 100,000
people of their occupation and means of subsistence. Such works had already been carried out successfully,
and profitably in the claustle mines of the Hart's Mountains,
where a 10-mile tunnel entered the 900-foot level,
at Freiburg, with its 8-mile tunnel,
and at Schmitz, where the Emperor Joseph ate it,
burrows for nine miles.
In 1865, the companies interested signed a contract
whereby they agreed to pay the tunnel company,
a royalty of $2 per ton on all ore extracted from their minds, in return for the drainage
and the privilege of transporting men, ore, waste rock, and the materials through this back door
at fixed rates. Scarcely had the contract been signed when some repented themselves,
and, in order to back out of their agreement, stirred up formidable opposition to the scheme.
Mr. Sutro was, however, a man of indomitable will.
He overcame all difficulties, including that of raising capital, and in September 1871,
commenced his attack on the hills.
Progress was at first, sadly hampered by the inrush of water, and by the inefficiency of
hand drilling, which advanced the borings only five and a quarter feet a day,
even when things were going well.
The engineers, therefore, had recourse to the imperfect power drills of the time,
to find them very costly and tedious implements to work with.
Fortunately for the tunnel, the burleigh drill appeared in 1874,
and the rate of advance was quadrupled,
though the dimensions of the working face had been increased to nine and a half feet by 13 feet of width.
Mr. Eliot Lord has given the world, in the monograph already laid under contribution,
so graphic a description of this great work, that no apology is needed for reproducing it in extensio.
Quote,
Sutro's untiring zeal kindled a like spirit in his co-workers.
Changing shifts urged the drills on without ceasing.
skilled timberers followed up the attack on the breast and covered the heads of the assailants like shield-bearers.
The hot rocks blown from the face of the heading, harshly ceased rattling on the floor of the tunnel,
before they were thrown and shoveled into iron tram cars and borne away by mule trains.
Lanterns bound to the shoulders of the mules through straggling rays of light on the dark pathway.
The dripping walls and roof reflected the beams through a myriad of water prisms,
and streaks of mottled gray, green and black rocks, shown out at intervals with vivid
distinctiveness, as if illuminated by lightning flashes.
A foreground and background of utter blackness enclosed the moving cylinder of changing lights
and shadows, a fitting framework to the weird picture.
As the train neared the mouth of the tunnel, it was seen first as a line of dancing lights.
Then the tinkle of collarbells was faintly heard and the tramping hooves on the rock floor.
The light specks swelled to clearly shining stars and then shrunk to red points in the glare
of the sun rays, which transformed the rough-timbered entrance into a white-pillared corridor.
In this transfiguring light, the eyes of the mules glowed like carbuncles, which shone in their
dark setting till the animals with quickened steps passed through the gleaning archway into
the sunlight. The dump at the mouth of the Tominil grew rapidly to the proportions of an
artificial plateau raised above the surrounding valley slope. Yet the speed of the electric currents,
which exploded the blasts, scarcely kept pace with the impatient anxiety of the tunnel owners
to reach the load. When the extent of the great consolidated Virginia Bonanza was reported,
for every ton raised from the load, before the tunnel cut, it was a loss to them of two dollars, as they
thought, urged on by zeal, pride, and natural covetousness, the miners cut their way
indomitably toward their goal, though at every step gained the work grew more painful and
dangerous. The temperature at the face of the heading had risen from 72 degrees Fahrenheit at the
close of the year 1873 to 83 degrees during the two following years, though in the summer of
1875, two powerful root blowers were constantly employed in forcing air into the tunnel.
At the close of the year 1876, the indicated temperature was 90 degrees, and on from the 1st of January 1878,
the men were working in a temperature of 96 degrees.
In spite of the air currents from the blowers,
the atmosphere before the end of the year 1896
had become almost unbearably foul as well as hot.
The candles flickered with a dim light,
and men often staggered back from their posts faint and sickened.
Behind the workers were sections of treacherous ground,
crumbling rock and swelling clay, which occasioned constant dread, lest some day the overstrained
props might give way, and a falling mass crush the air pipes and block the passage. In such event,
the men might die for lack of air in the narrow tomb before they could cut their way through the
barrier, or be rescued by outside help. This was not a fanciful peril. As it was a
was averted more than once by the watchfulness and promptness of the miners in propping up sinking
ground and piercing the falling debris. During the months, immediately preceding the junction with the
savage mineworks, the heading was cut with almost passionate eagerness. The miners were then,
two miles from the nearest ventilating shaft, and the heat of their working chamber was fast-growing
too intense for human endurance. The pipe which supplied compressed air to the drills was opened at
several points, and the blowers were worked to their utmost capacity. Still, the mercury rose from 98 degrees
Fahrenheit on the 1st of March 1878 to 109 degrees on the 22nd of April, and the temperature of the
rock face of the heading increased from 110 to 114 degrees during the same period.
From the first day of May 1878, it was necessary to change the workforce four times a day instead
of three as previously, and the men could only work during a small portion of the nominal
hours of labor. Even the tough, wiry mules of the car train could hard.
be driven up to the end of the tunnel, and sought for fresh air not less ardently than the men.
Curses, blows, and kicks could scarcely force them away from the blower tube openings,
and more than once, a rationally obstinate mule thrust its head into the end of the canvas airpipe
and was literally torn away by main strength, as the miners, when other means failed,
tied his tail to the bodies of two other mules in his train,
and forced them to haul back their companion,
snorting viciously and slipping with stiff legs over the wet floor.
Neither men nor animals could long endure work so distressing.
Fortunately, the drills knew no weariness or pain
and churned their way without ceasing to the minds.
At length, the tunnel drew,
so near the load that the men in the savage mine could hear the explosion of the blasts,
and soon after, the tapping of the drills on the rock partition.
These sounds grew more and more distinct until, on the 8th of July 1878, a few feet of rock
alone separated the two working parties. A blast from the savage mine tore an opening through
the wall in the evening of that day, and the goal for which Sutro had striven for so many years
was in sight. He was waiting at the breach, impatient of delay, and crawled half-naked
through the jagged opening, while the hot, foul air of the heading was still gushing into the
mine. If he seemed overcome by excitement, as reported, it was in no way surprising, for he had triumphed,
over a host of obstacles, and his indomitable spirit had fairly won success.
The Comstock, wonderful as it was in itself, derived additional romance from a Herculian work like this,
executed merely as a preliminary to the deep working of the load.
At the time the Sutro Tunnel not only took first place among all feats connected with mining,
but also rivaled the Mount Sennis and St. Gothard Enterprises in the difficulties attending its construction.
We must therefore feel sympathy with its promoter, who found that his scheme had been so hampered at the
outset by opposition, that when completed, the need for it had almost passed.
The quality of ore found in the load, below the level, 1870,
feet, at which the tunnel entered was insignificant, in comparison with the huge deposits found
between it and the surface. Mostly extracted while the tunnel drivers were straining every muscle
to reach the load. Had Sutro only been allowed his way in 1866, both he and the owners of the
Big Bonanza would have profited enormously. Now, for the Big Bananasia, now for the Big Bananasia,
Manza itself, which furnishes the most thrilling episode in the history of one of the world's
most interesting minds. Virginia City and its neighborhood contained many pessimists in the early
70s, prices were down, expenses were increasing, and many financiers had come to the conclusion
that the Comstock as a whole showed distinct signs of being placed.
played out. Mine proprietors had forgotten all about plate glass windows, champagne and beautiful
fountains while they endeavored to keep the balance of the accounts on the right side of the ledger.
While things were in this state, Mr. John W. McKay began to play a prominent part in Comstock history.
A man of cool common sense, extraordinary insight and bold action.
He had risen from day laborer first to be superintendent of the Caldonia Tunnel and Mining Company.
Then a large shareholder in the Hale and Norcross Mine as a partner of Mr. James G. Fair.
These two Irishmen made a fine working combination.
They bought up one property at.
after another, including those between the ofer and Gould and Curry mines, which had hitherto
been unsystematically and unsuccessfully exploited. The original owners, after joining forces
and sinking shafts in search of a rich deposit, concluded that the failure to strike ore indicated
a break in the load, and losing heart were ready to sell.
McKay and Fair, acting in partnership with James Seaflod and William O'Brien,
Francisco men, purchased the Virginia Consolidated, as it was now called, for about 10,000 pounds,
determined to venture their fortunes on the chance of finding a bonanza at a greater depth than
the previous occupiers had attained.
The quartet, forthwith, sank a deep shaft, and cut adrift to meet it from the Best and Belcher Mine at the
twelve hundred foot level. At first the miners found only barren rock. But just as the Virginia
Khan boundary had been passed, a thin seam of ore made its appearance. Mr. Fair followed this
pertinaciously as the possible clue to treasure beyond.
Sometimes it almost vanished, but never quite, so that the ventures were induced to continue
what outsiders were guarded as a mere wild goose chase.
$200,000 were spent without result, and the Virginia con tottered on the verge of bankruptcy.
Illness compared Mr. Fair to be absent for a month, during which time his three partners
thought to improve matters by deflecting the line of search, from a northerly to an easterly
direction. On his return, however, he persisted in following the old course, and in October
1873, the miners cut into a rich ore body, which was the big bonanza. Of its magnitude and riches,
writes Mr. Lord, all then were ignorant.
No discovery which matches it has been made on this earth,
from the time when the first miner struck a ledge with his rude pick until the present.
The plain facts are as marvelous as a Persian tale,
for the young Aladdin did not see in the glittering cave of the genie
such fabulous riches as were lying in the dark womb of the rock.
The wonder grew as its depths were,
searched out foot by foot. The bonanza was cut at a depth of 1,167 feet below the surface,
and as the shaft went down, it was pierced again at the 1,200 foot level. Still the same body
of ore was found, but deeper and wider than above. 100 feet deeper and the prying pick and drill
told the same story. Yet another hundred feet, and the mass appeared to be still swelling.
When finally the 1500 foot level was reached, the ore richer than any before met with was disclosed.
The fancy of the coolest brains ran wild. How far this great bonanza would extend, none could
predict. But its expansion seemed to keep pace with the most.
sanguine imaginings. To explore it thoroughly was to cut it out bodily, but the systematic
search through it was a continual revelation. The average yield of this marvelous silver-saturated rock
was 600,000 pounds per month for three years. With monthly dividends of about one-third of that
amount, the four partners quickly became millionaires, rich, beyond their wildest dreams.
In 1876, Mr. McKay took out 1,200,000 pounds worth of bullion to make an exhibit at the Philadelphia
Centennial Exposition. You can still see in Virginia City, a building where 25,000 pounds worth of
bullion was melted down daily for over 1,000 days, and from which a million sterling started
one night on its journey to San Francisco. To sum up, the Consolidated Virginia had by 1899
yielded or worth 26 and a half million pounds, over half of which passed as profit into the pockets
of the proprietors.
Such a record can scarcely be matched in the whole history of mining.
Of course, this stroke of fortune affected the whole Comstock load.
Why, argued speculators?
Sure, there not be equally rich deposits still lurking undiscovered in other properties.
And they indulge their fancy as deeply as the gamblers of the South Sea bubble.
servant girls and office boys jostled merchants and professional men in San Francisco in the
race for script. Shares worth about 50 cents rose to a value of $275. Then rumors got afloat that the big
bonanza was not, after all, so extensive as had first been pictured. And down came the prices
with a run to a third of their top figures,
leaving much ruin and wreckage behind them.
Fortunately for those who had stuck
to their Virginia consolidated shares,
the mine product knew no such fluctuations,
increasing steadily until the bonanza became ultimately exhausted.
From the sordid dealings of the money market,
let us turn to the manly toil of the mines,
and borrow yet another picture from Mr. Lloyd's gallery.
The scene within this treasure chamber was a stirring sight.
Cribs of timber were piled in successive stages from basement to dome,
400 feet above, and everywhere men were at work in changing shifts,
descending and ascending in the crowded cages,
clambering up to their assigned stopes with swinging lanterns or flickering candles,
picking and drilling the crumbling ore or pushing lines of loaded cars to the stations at the shaft.
Flashes of exploding gunpowder were blazing from the rent faces of the stoops.
Blasts of gas and smoke filled the connecting drifts.
Muffled roars echoed along the dark.
galleries and at all hours a hail of rock fragments might be heard rattling on the floor of a level
and massive lumps of ore falling heavily on the slanted pile at the foot of the breast.
Half-naked men could be seen rushing back through the hanging smoke to the stoops to examine
the results of the blast and to shovel the fallen mass into cars and wheelbarrows.
while some were shoveling ore and pushing cars,
others, standing on the slippery piles,
were guiding the power drills,
which churned holes in the ore
with incessant thumps or cleaving,
the softer sulphurets with steel picks swung lightly by muscular arms.
Roman gladiators were scarcely better fitted for their contests in the arena
than those Comstock miners for their laborers
in the heart of the bonanza.
All were picked men, strong, young, and vigorous,
fed on the choicest food which the Pacific Coast affords,
and paid the highest wages earned by any miners in the world.
In the hot levels, all clothes were laid aside except a simple waistcloth
and shoes which protected the feet from the scorching rocks.
balanced alertly, on wet, crumbling heaps of ore with muscles, swelling like flesh waves at
every swing of the well-balanced picks. They became models for a sculptor. Their hot blood glowed
beneath a skin, whitened by a life in dark rock chambers, often dripping with water and reeking
with vapor. The variety of their motions had made them a troop of athletes.
As one looked upon this swarm of human ants, stopping out and sending up ore from a bonanza
whose riches were incalculable, while the vault of the great mind echoed with busy sounds
and sparkled with moving lights, it is scarcely surprising that the eyes were dazzled by the vision
of the treasure chamber, and the brain, heated by enkindled fancies.
The high temperature of the load walls seriously increased the miners' toil.
At a depth of 1,700 feet, the thermometer showed 104 degrees Fahrenheit,
and when shafts sank hundreds of feet nearer the earth's center,
the heat became so terrific that some men fell dead over their picks,
while others were actually boiled to death by water into which,
which they accidentally slipped. So exhausting was the effort of hewing the ore in air thus heated
and fouled by the exhalations from the lungs and body, that after a few strokes of his pick,
the miner had to stand aside to recover himself, while a fellow worker took his place. Yet,
human perseverance conquered. The bones of the big bonanza were picked clean. Messers, McKay,
Fair Flood and O'Brien pocketed their millions, and the mines now sadly impoverished and
water-logged, passed into other hands. The chancy nature of mining is particularly well illustrated
by the contrast between the good fortune of the four partners and the fate of the first
discoverers of the Comstock load, McLaughlin, O'Reilly, and Comstock. The first after a life,
of continual misfortune and hard work died in hospital, too poor, to leave money enough to cover
the costs of his pauper burial. O'Reilly, his brain turned by unrealized expectations,
wore out his health and strength in a tunnel which he drove single-handed into a barren hillside
of the Sierra.
Angelic voices urged him on to imaginary treasures still far in advance of his pick.
His tunnel fell in and maimed him, and at last he was carried off to an asylum where he died.
The third member of the Luckless Trio, Henry Comstock, also became the victim of delusion.
Beggard, in fact, he still remembered.
remained in fancy the owner of the entire load and its cities. A self-inflicted revolver wound
terminated his inglorious history. He now lies in a nameless grave in the wastes of Montana.
The sad note struck by these melancholy incidents attaches also to the latter fortunes of the
Comstock itself. During 1899, scarcely a dozen
and men were at work in the vast chasms hewn out by their predecessors. Deep down beneath the water,
which finds an outlet through the Sutro Tunnel, are the bottoms of the tremendous shafts and the
deposits deemed to pour to be worth extraction. Virginia City, which Mark Twain has peopled for us
with characters of varied pattern, is shorn of her glory. The old mills,
once humming with life are silent.
Machinery rusts in the rotting shaft houses,
and though the sun still strikes down as formerly on the hillside,
it serves but to show how deeply the word Ichabod has been traced across
the great treasure vaults of the Comstock.
End of Chapter 9, read by Edward Foster,
Sunrise Beach, Missouri.
Chapter 10 of The Romance of Mining.
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The Romance of Mining by Archibald Williams.
The Mines of Lead.
Fifty years ago, significant names, early history, first era of mining, valuable rubbish,
second era, great profits, a railway episode, third and fourth eras.
Tucked away in Colorado between the Rocky Mountains on the west and the park range on the east
is an elevated plain which slopes gently westwards.
Fifty years ago, solitude reigned here,
among some of the grandest scenery which the United States can offer to the eyes of the tourist.
Today, the district is a busy hive,
and the rounded hills, crossing the plain from north to south,
have been honeycombed by shafts and tunnels, driven in to,
pursuit of gold, silver, lead, and other metals.
Leadville, the commercial center of the mines, lies toward the western end of the plain.
On the east are dotted about dozens of properties, named in a manner suggesting
either their nature or some incident connected with their history.
Neodespirondum conjures up a picture of the miner working
against heartbreaking disappointment.
In Only Chance, we see the last card being played by the impoverished prospector.
Resurrection betokens the mending of broken fortunes.
Ready Cash speaks of early success.
In Evening Star, Silver Chord, Forest Queen, Star of the West, imagination has had play.
and Little Vinny, Adelaide, Dolly B, Fanny Rollins,
Nettie Morgan, Lillian, and Minnie,
perhaps indicate that the owner has in mind the girl he left behind him
when he sallied forth in search of fortune among the hills.
The mining history of the Leadville District dates from 1860,
when some gold hunters crossed the park range and entered a then heavily timbered ravine
through which flowed a feeder of the eastern fork of the Arkansas River.
The locality looked promising.
Pans and rockers were soon busy.
Color appeared and the stream, once limpid, became turbid and yellow after its passage through the rough apparitions.
The apparatus of the miners. Some claims panned out a thousand dollars a day for weeks together,
in spite of the shortage of water. Thousands of men flocked into share the spoil. A large camp
rose on either side of the stream with the usual array of stores and drinking saloons
wherein gold dust was bartered for flour or whiskey.
The altitude of Leadville, over 10,000 feet above sea level,
means a long and hard winter, during which the miners, swallow-wise,
migrated to Denver and other milder localities,
waiting for the next spring to return to their claims.
The first era of Leadville history covers the years 1860 to 1869.
The camp saw its best days in 1861 and gradually declined till 1868,
by which time the placers had yielded some $4 million worth of gold.
For the next decade, little was done in the district beyond some quartz mining
though prospectors were busy seeking fresh openings for labor and capital.
We have seen how, in Nevada, gold mining had led to the discovery of silver.
The same thing happened in Colorado, and, as in the case of the Comstock deposits,
the early miners at Leadville threw a side as worthless, material which, to the expert I,
betrayed a fortune ready to be gathered.
The workers in California Gulch
grumbled at the weight of boulders
obstructing their operations.
But when W.H. Stevens, a wealthy miner,
and A.B. Wood,
came on the scene to organize a 12-mile flume
for the gulch, they took the trouble
to investigate the nature of this heavy rubbish
and found that it was carbonate of less,
containing a high percentage of silver.
They kept the discovery to themselves
until they had secured several claims
along what they considered to be the outcrop.
From this year, 1878 dates the second era of Leadville mining,
the carbonate period, as it has been called.
In a few months, a strong spring of immigration
had commenced, people flocking in from all parts of the states. Before a year had passed,
the population had increased 20-fold. Leadville became a magnet, towards which long trains of
wagons moved slowly along overcrowded roads. A bank and a post-office were established,
and round these a town sprang up, one of the liveliest towns of the day.
At nightfall, pleasure seekers crowded the streets, spent their money recklessly, and enriched those who catered for their wants.
Building sites, which a short time before, could have been bought for a few dollars, fetched thousands.
fortunes were made by lucky speculators without the trouble of touching a pick.
The carbonate zone runs north and south with a dip eastwards at an angle of about 20 degrees below the
vertical, the carbonate lying between a covering a porphyry and a substratum or footwall of limestone.
The veins struck varied in thickness.
from a mere streak to 30 feet, and were so soft as to be extracted by the pick without blasting.
Some of the ore yielded $400 worth of silver per ton and 75% of lead.
From the Little Pittsburgh New Discovery and Whitamuck Mines on Friars Hill to the northeast of the town,
ore valued it over $3 million was extrad.
in six months. In the second of these mines, a great bonanza appeared at a very moderate gap.
Between 100 and 200 feet below the surface, so large was the excavation that the owners had to resort to the
system of timbering employed in the big bonanza of the Comstock. The Leadville mines of the
Second era were very shallow as compared with those on the Comstock load, and their working was
therefore very profitable until the price of silver fell in consequence of the quantities of the
metal extracted in Colorado and Nevada, owned by closed companies of a few members each, who kept
the shares out of the market, they never became the subject to.
of such wild speculation as we have already had to notice in the case of the Goulden Curry
and other big Nevada ventures, nor has their working been distinguished by lavish and reckless
expenditure. On the contrary, the Leadville mines afford a good example of efficient and
economical management. The Carbonate period is connected with a stirring episode in America,
Railway history. The 70s were notable for the extension of the transcontinental lines.
The Acheson, Topeka, and Santa Fe had reached the edge of New Mexico in 1878, bound for the Pacific
coast. Its promoters had an eye very widely open for intermediate branches and the discovery of silver
in the Leadville region that year immediately suggested the reflection that a sidetrack
penetrating the park range into the plateau might bring some very pretty returns, considering
the charges then prevailing on the roads. There was only one practical approach to Leadville,
through the Grand Canyon eaten out by the Arkansas River, and this the Rio Grande and
Denver magnets already regarded as their own since Colorado was their particular sphere of action.
Getting wind of the Santa Fe people's intention to seize the pass and gain the right-of-way by commencing
work, they dispatched a trainload of Denver employees to anticipate such a move.
Mr. W. R. Morley, a Santa Fe engineer, proved too quick for them, driving furiously across country to Canyon City while the train slowly wound its way over the metals. He collected a handful of backers, and by dawn had moved the first shovelful of Earth, much to the disgust of the rival faction, who arrived in time to look down.
the muzzles of an assortment of firearms.
It looked as if there would be a fight for the past,
but the West had advanced sufficiently in civilization
to have recourse to the more peaceful methods of the courts.
As the result of a long and notable lawsuit,
the Denver Party compromised and leased
the whole of their narrow-gauge system to the state.
Santa Fe. The latter at once began to build a second line through the pass on their own account,
and, this being construed as an act of perfidy, the conflict broke out again. Different judges gave
different decisions. The employees took a spirited and practical part in the fight. Law and order were
for the time set at naught.
When it came to actual force of arms,
the Santa Fe got the worst of the bargain
and were finally expelled from their occupation.
Such vigorous measures showed that the Leadville traffic
was a prize worth fighting for.
With the decline in the value of silver,
Leadville declined also,
But it did not fall since there was still gold in the district, as Mr. John F. Campion discovered in 1891 when he sank a shaft on Breece Hill to the east of the city. The Ibex Mining Company was formed. In eight years, it extracted gold worth $13 million. Other corporations did almost equally well.
The third era, built like the first on gold, produced many large fortunes.
At present, the fourth era of Leadville is running its course.
Gold, silver, lead, copper, zinc, and iron are all treated as the baser metals have risen
in value.
End of Chapter 10
Chapter 11 of The Romance of Mining
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The Romance of Mining
By Archibald Williams
The Mines of Silverland
Mexico as a silver producer
what Humboldt found in 1802
The total production of silver
Huge lumps of solid metal
Sensational Fortunes
A lucky priest
A millionaire fiddler
Two fortunate peasants
The Good Success Mine
The mines of Zacatecas
The mines of Guanahua
The Valenciana mine
The Marques de Raias
Mexican mining law
About depth of claims
Zacatecas wealth
Of all the silver mined yearly throughout the world
Mexico yields one third
Which is assessed at a value of about
15 million pounds
thanks to the enormous deposits of Nevada, Montana, Colorado, Utah and Idaho,
the United States come in a very good second with 14 million sterling.
But other individual countries are nowhere.
It was gold that attracted Cortez to the land of the Aztecs in the 16th century.
The natives, ignorant of silver mining, had amassed, as we have already noticed,
large quantities of the more precious metal,
though their total accumulations were a mere trifle
in comparison with the silver wealth which they left untouched.
Silver, silver, silver, is the cry which now draws engineers,
capitalists and adventurers of all classes
to the republic so ably ruled by Porphyrio Diaz,
a man whose career is as full of romance as that of the country,
which he has rescued from the country,
which he has rescued from chaos
and given a leading place
among the transatlantic nations
silver is found in most parts of Mexico
either as pure metal
or in chemical combination with various
other minerals
but the provinces most distinguished
by their silver mines are
refer to your map
Sonora
Chihuahua
Gerango
Zacatecas
San Luis Potosi
Guanahua
Poito and Hidalgo, to name them in their due order from north to south.
When Humboldt visited Mexico in the beginning of the 19th century,
he calculated that the great silver loads were honeycombed by 3,000 to 5,000 mines,
each of which had several shafts and many galleries,
and he reckoned the silver extracted since Spaniards first began work
to be worth 130 million pounds.
These figures are now quite eclipsed. For recent calculations, assess the total value till the end of the last century, to be £800 million sterling.
What these colossal figures mean may be concretely represented by assuming that the silver has had an averaged price of three shillings and fopums per ounce.
If you care to work out an arithmetic sum,
taking as your basis the fact that one cubic foot of silver
weighs 10,700 odd ounces,
you will arrive at about 450,000 cubic feet,
which would suffice for a pillar of metal 10 feet square
and higher than the loftiest mountain in the British Isles.
that such huge quantities should have been mined
is due to the kindly nature of the ore
which permits it to be reduced by comparatively primitive methods
many of the loads or veins are rotten or crumbling
and in places masses of solid silver have been found
which completely eclips the records of other countries
The mine of Arasuma in Sonora
takes first place as the producer of monster silver nuggets
So sensational are the figures
That we should hardly dare to quote them
Were they not backed by unimpeachable testimony
At Arasuma then
In the middle of the 18th century
The owner paid duty on several pieces
which together weighed 4,033 pounds,
the largest lump, scaling 2,700 pounds,
or about a ton and a fifth.
Even the largest gold nuggets of Australia
hardly equal this in value.
You will easily understand
that in a country so impregnated with precious metal,
many enormous fortunes must have been made
during the three and a half centuries
during which the miner has been at work there.
The stories of individual success and attainment of dazzling wealth
would suffice to fill a large volume
and we must therefore but briefly notice the look of a few persons
and the productiveness of a limited number of minds.
In the midst of bleak and precipitous mountains,
in the state of San Luis Potosi,
not to be confused with the Potosi of Bolivia,
is the Flores mine.
It was discovered by a priest
who, tired of his life as a starved cleric,
bought for a mere trifle
a claim which was being abandoned as worthless.
After following the vein in a little distance,
he struck a cavern in the rock
full of rotten ore,
out of which he mined over £600,000 worth of silver.
Again, in this same region,
in 1778, a negro fiddler, overtaken by night while returning home from a dance,
built a fire among the ashes of which he discovered, next morning, a button of virgin silver.
The outcrop, thus fortunately brought to light, made him a millionaire.
The Morton Mine, Sonora, was struck in 1826 by two Indian peasants,
so poor that, on the night before their great discovery,
the keeper of the store had refused to credit one of them
for a little corn for his tortillas, cakes.
They extracted from their claim $270,000,
yet in December 1826,
they were still living in a wretched hovel
close to the source of their wealth,
bare-legged and bare-headed,
with upwards of 200,000.
dollars in silver locked up in their hut.
Never was the utter worthlessness of the metal as such,
so clearly demonstrated as in the case of these peasants,
whose only pleasure was to gloat over their hordes
and occasionally throw a handful
to be scrambled for by their less fortunate neighbours.
The good success mine was found by an Indian
who swam a river after a heavy flood.
On arriving at the other,
the side, he found the outcrop of an immense vein which had been laid bare by the force of the
current. All the inhabitants of a neighbouring town went out to see this wonder. Though he was prevented
by water inroads from going deeper than about three yards, he took out a large fortune. Of a neighbouring mine,
the Pastiano Ward writes, the oars were so rich that the load was worked by
with a point at one end and a chisel at the other for cutting out the silver.
The owner of the Pastiano used to bring the oars from the mine with flags flying
and the mules adorned with cloths of all colours.
The same man received a reproof from the Bishop of Durango
when he visited Batopilosh for placing bars of silver
from the door of his house to the great hall for the bishop to walk upon.
The Santa Ulalia mine
Yielded so enormously
that 2.5% of the silver
extracted in a few years
suffice to build the magnificent cathedral
of Chihuahua.
So much for Sonora.
Anything that can be said of this province
can be said several times over
for Zacatecas and Guanahuato and Hidalgo.
The first two of these
have been rivals for first place among the states
as silver producers.
Both have had their ups and downs, the one being in Bonanza, when the fortunes of the other were low,
and then a turn of fortune's wheel would reverse their positions.
Since Christabelle de Eonte located the Tanyos de Pannuco in 1548,
the mines of Zacatecas have yielded over £200 million sterling.
The Guanajuato ore deposits first tapped in 1554 have given up an equal amount,
The Valenciana mine, when visited by Humboldt, had, in four years, produced 13,896,416 ounces of silver.
It was opened in 1760 on the mother vein at a point where some work had been done in the 16th century
and which had been neglected afterwards for two centuries as unsatisfactory.
A rich Bonanza was struck, eight years later, at a depth of 240 feet and 300,000 pounds were extracted annually. A town of 7,000 inhabitants was built near the mine which gave employment to 3,100 people.
A large octagonal shaft was sunk to a depth of 2,000 feet, and the mine was explored by it in lower parts.
but the rich ore extended only to the depth of 1,200 feet,
below which it was then too poor to be worth extracting.
In 1810, the mine filled with water.
Fifteen years later, the Anglo-Mexican Company, of which more presently,
freed the mine at great expense, but did not succeed in making it pay.
The United Mexican Company, which afterwards took it in hand,
managed, however, to extract an immense quantity of paying ore.
A peculiarity of this shaft is a spiral path cut over 500 feet down through the rock
at such an angle that mules can walk up and down it.
The other great mine of Guanajuato is the Marquest Reyes, or Los Reyes.
In connection with it
We may notice a feature of Mexican mining laws
Which give to the discoverer of a load
A right to dig only 500 feet down under his claim
The consequence of this limitation is
That when a very rich claim is made
There immediately springs up a contest
To get below it
And to cut off the lucky discoverer
From the lower part of his expected fortune
and he has no means of avoiding such a result,
but by driving his shaft downward
until he reaches a point below the first 200 Varas, 500 feet,
which entitles him to claim another section downward.
The Marquis de los Raias, being a determined digger,
got down so deep that he claimed the second stratum of 500 feet
before rivals had penetrated obliquely
and so netted a fortune of over two million pounds,
thanks to the ore, being so rich in gold
that it often sold for its weight in silver.
With silver so plentiful, many extravagances were committed.
One Zacatecas minor paved the street with ingots
from the Cassade Gobiano to the parochia,
between 50 and 60 yards, for a christening procession.
In 1800, the Viceroy Ananga
passed a law for bidding godfathers
to fling handfuls of coin into the street
on such occasions.
It was easy come, easy go,
as always where there are bananzas,
with the difference that even a parvenu spaniard
spends his money not like a parvenu,
but like a prince.
The province of Hidalgo
contains two very famous mines.
the San Gertrudis and the Real de Monte.
The story of the last is so interesting
and in many ways so typical of Mexican mining history
that we will devote a special chapter
to its fortunes.
End of Chapter 11.
Read by Bryn Roberts, Kings Winford, December 2022.
Chapter 12 of the Romance of Mining
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The Romance of Mining by Archibald Williams.
The Real Del Monte.
Pachuca in Adalgo is the oldest mining district of Mexico.
The mines in its immediate neighborhood were the first in which the Spanish conquerors forced slaves to work for them.
10 miles from Pachuca, among glorious scenery, is the village of Real Del Monte, on ground honeycombed by shafts and the adits.
As long ago as 1826, when English Enterprise had begun extending the workings of the Real Mine,
Mr. Ward wrote, quote,
The possessions of the Real Del Monte Company on the two great veins of Santa Brigida and La Biscayina cover a space of 11,000,
800 yards, and are intersected at intervals by 33 shafts, varying in length from 200 to
270 yards, but all sunk with a magnificence unparalleled in Europe. The whole of these shafts,
together with the great adit or tunnel for draining the mine, which follows the direction of the two
great veins, branching off from the Santa Brigida vein at the point where it intersects that of the
Viscayina, and from which the wealth of the Regla family was principally derived,
was delivered over to the company in July 1824 in a state of absolute ruin.
Many of the shafts had fallen in, though cut at intervals in the solid porphyritic rock.
In others, the timbers had given way, and in all, as the added was completely choked up,
the water had risen to an enormous height.
End of quote.
But this is anticipating.
Very little is known of this mine prior to 1749, beyond the fact that its surface workings
had yielded considerable quantities of silver. In olden times, water had been lifted from the mine
in bull's hides carried up on a rope, a method so primitive and inefficient that when a
comparatively small depth had been reached, the water got the upper hand and caused the abandonment
of the property at the beginning of the 18th century.
As has been well said, no wreck is more complete than that which water causes
when it once gets possession of a mine, and mingles into one mass, floating timbers,
loosened earth, rubbish, and soft and fallen rock.
The mining laws of Mexico, like those of some other countries, stipulate that a title of
ownership shall be maintained by work and work alone.
When once a mine is abandoned, anybody can denounce or claim it on condition that he works it.
Now an intelligent miner named Bustamante saw his chance.
The water was there, but metal was there as well.
If the former could be drained off, the latter could be easily extracted.
He accordingly joined forces with one Peter Tereros, an enterprising merchant,
though some accounts make him an ignorant muleteer.
to drive and add it into the side of the hill which should enter the Biscayina vein
at a depth of 200 yards below the surface.
To effect this, the tunnel would have to be 3,000 yards long.
The undertaking, though enormously expensive and very arduous,
was persevered in by the two partners,
who fortunately from time to time encountered veins which paid all costs.
Bustamante died before the completion of the work,
but in 1762, Tereris had the satisfaction of cutting into the Biscayina and seeing the water rush out into the valley.
Adolf Sutro, a century later, as we have already noticed, performed a similar but much greater feat at the Comstock load.
When he reached the main shaft, he had a ruined clear out and rebuild, which was a more costly undertaking than the building of a king's palace.
but if the toil had been great, the reward was greater still.
In 12 years, Terreros took out over three million pounds sterling.
Of this, he spent two and a half million dollars on the mines and refineries,
laid out six million dollars on plantations,
and loaned the King of Spain a million,
which were, of course, not repaid.
For this handsome pecuniary help,
and the present of two fully equipped ships of the line,
the once humble Peter Terreros was ennobled as the Count of Regla.
Quote,
Among the common people, he is the subject of more fables than was Cresus of old.
When his children were baptized, so the story goes,
the procession walked on bars of silver.
By way of expressing his gratitude for the title conferred on him,
he sent an invitation to the king to visit him at his mind,
assuring his majesty that if he would conferred,
fur on him such an exalted favor, his majesty's feet should not tread upon the ground while
he was in the new world. Wherever he should alight from his carriage, it should be upon a pavement
of silver, and the places where he lodged should be lined with the same precious metal.
Anecdotes of this kind are innumerable, which, of course, amount to no more than showing that
in his own time his wealth was proverbial, and demonstrate that in popular estimation he stood at the
head of that large class of miners whom the wise king ennobled as a reward for successful mining
adventures and that he was accounted the richest miner in the kingdom the state and magnificence
which he sometimes displayed surpassed that of the vice king this in no way embarrassed in a state
the largest ever accumulated by one individual in a single enterprise end of quote footnote from
Wilson's Mexico, page 365. Tereris's son found the work of extracting ore more difficult than had
his father, for in his time the shafts had sunk so far below the added level that the original
trouble with water was repeated. He installed horse machinery called Malacatis, which raised the
water in skins to the adit and discharged it. As the mine grew deeper, more and more Malacatis
became necessary. Until 28 were at work.
turned by twelve hundred horses, superintended by four hundred men.
A quarter of a million dollars were spent annually on the draining,
and eventually the deeper galleries had to be abandoned,
though they yielded $400,000 per annum,
and operations were confined to the upper levels.
On the death of the second count, the mine declined,
and its activity ebbed very low during the War of Independence in 1821,
which severed Mexico from the Spanish crown.
The Terrerus family kept their title good by employing a few workmen about the shafts.
As soon as the independence of Mexico had been recognized by Great Britain,
English capital began to flow into the new republic.
During the years 1824 to 1827,
a regular mania for speculation in Mexican minds seized the British public.
To quote Mr. Wilson's vivid words once again,
quote,
sea delusion, the Anglo-Spanish-American mining fever broke out in England. It surpassed a thousand-fold,
the wildest of all the New York and Californian mining and quartz organizations of the last five years.
Prudent financiers in London ran stark mad in calculating the dividends they must unavoidably realize
upon investments in a business to be carried on in a distinct country and managed and
controlled by a debating society or board of directors in London.
money was advanced with almost incredible recklessness and agents were posted off with all secrecy to be first to secure from the owner of some abandoned mine the right to work it before the agent of some other company should arrive on the ground
no mine was to be looked at that was not named in the volumes of humboldt and any mine therein named was valued above all price in the end some fifty million dollars of english capital ran out and was used up in mexico
it was one of those periodical manias that regularly sees a commercial people once in ten years and for which there is no accounting and no remedy but to let it have its way and work out its own cure in the ruin of thousands
while finance was thus distracted a company known as the reall del monte company was formed to drain the reale mines and render them workable their condition at this period has already been described
besides all the machinery in the large reduction works formerly used to extract the silver from the ore had been destroyed or carried off and as the war had almost obliterated the villages round workers were hard to find
Englishmen are not easily discouraged.
The necessary capital, having been subscribed,
1,500 tons of machinery,
including five large steam engines, a stamp,
sawmill engines, and pumps,
were sent out in May 1825 to Veracruz.
Even when the three ships carrying the material
had discharged their cargoes
after great difficulty on account of the exposed and dangerous anchorage,
trouble had only just begun.
300 miles of ruddy and hilly roads had to be traversed by the transports, drawn by 700 mules under the direction of 100 men.
This process occupied five months and cost a million dollars, a sum equal to the original value of the machinery.
Meanwhile, a detachment of the mines had cleared the added, repaired many of the shafts, erected buildings round the property,
and built a finely engineered road from the mines to the reduction works through the rocky ravine
which intervenes. The pumps were erected and hopes rose high. Unfortunately, the promoters
made an initial mistake which ruined their venture. Instead of trying to drain the mines by a tunnel
driven below that of Tahriris, at the level of the bottom of the existing workings, they decided
to pump the water into the old added. At first all seemed to go well.
since two small steam engines, working pumps that lifted 600 gallons per minute,
easily accomplished what the 28 Malacati's had failed to do.
But the galleries drained did not prove very remunerative,
and the engineers therefore decided to sink a large shaft farther along the vein.
The manner of sinking of this was, at the time, a novel engineering feat,
for instead of proceeding from the top only,
the engineers drove five galleries at different levels from the old workings
to spots under that which had been fixed for the mouth of the shaft,
and worked simultaneously both upwards and downwards from these five levels.
The shaft was finished in 1834,
and it must be placed to the credit of those responsible
that when the sections met,
they made a hole as straight and perfect as if a shaft had been sunk from the surface direct.
The new treasure house reached through this shaft was worked profitably for a time,
excavations reaching downwards to a point 720 feet below the surface.
the added. Then the difficulty of drainage made itself felt. Three large pumps, discharging between
them 2,700 gallons a minute, could scarcely keep the water in check. The cost of pumping ate up
all the profits. Shares which had risen from 100 pounds to 4,800 pounds in value fell,
fell, fell, till in 1845 they could be bought for 50 shillings apiece. The company, worn out by a losing
fight with the water, gave up the struggle, and a property on which $20 million had been expended
passed into the hands of other people for 25,000 pounds sterling. This was indeed a sad ending
to the second chapter of the Rael's history. A Mexican syndicate bought the mine and all
appertaining thereto for a mere song. As indeed the amount named above must appear,
in comparison with the intrinsic value of the silver deposit still left untimed.
touched. Mr. Buchan, the engineer of the new company, at once commenced to drive a drainage
tunnel 400 feet below that of the first count. It had to pierce nearly a mile of very hard rock
before it reached the great Dolores shaft. Then the water got away, and the third chapter,
which may be said to last to the present day, commenced. In 1856, 5,000 men and countless
animals were at work. For a pen picture of the mine at this time, we must once again appeal to Mr. Robert
A. Wilson's interesting book. Clad in a skull cap, miners' pants, and coat and calfskin boots,
an oddly assorted garb, he descended one of the main shafts. While standing at the top of the shaft,
he writes, I was astonished at the size and perfect finish of the steam pump that had been
imported from England by the late English mining company. With the assistance of balancing weights,
the immense arms of the engine lifted, with mathematical precision, two square timbers, the one spliced
out to the length of a thousand, the other 1,200 feet, which fell back again by their own weight.
These were the pumping rods which lifted the water 400 feet to the mouth of a tunnel or at it,
which carried it a mile and a quarter through the mountain and discharged it in the creek.
A trapdoor being lifted, we began to descend by small ladders that reached from floor to floor in the shaft, or rather in the half of the shaft.
The whole shaft was perhaps 15 or 20 feet square, with sides formed a solid masonry where the rock happened to be soft,
while in other parts it consisted of natural porphyry rock cut smooth.
Half of this shaft was divided off by a partition, which extended the whole distance from the top to the bottom of the mine.
Through this the materials used in the work were let down,
and the ore drawn up in large sacks,
consisting each of the skin of an ox.
The other half of the shaft contained the two pumping timbers,
and numerous flooring at short distances,
from one to the other of these ran ladders,
by which men were continually ascending and descending,
at the risk of falling only a few feet at the utmost.
The descent from platform to platform was an easy one,
while the little walk on the platform relieved the mother,
exhausted by climbing down. With no great fatigue, I got down a thousand feet, where our further progress
was stopped by the water that filled the lower galleries. Galleries are passages running horizontally
from the shaft, either cut through the solid porphyry to intersect some vein, or else the space which a vein
once occupied is fitted up for a gallery by receiving a wooden floor and a brick arch overhead.
They are the passages that lead to others
and to transverse galleries and veins,
which, in so old a mine as this, are very numerous.
When a vein sufficiently rich to warrant working is struck,
it is followed through all its meandering as long as it pays for digging.
The opening made in following it is, of course,
as irregular in form and shape as the vein itself.
The loose earth and rubbish taken out in following it
is thrown into some abandoned opening or gallery,
so that nothing is lifted to the surface but the ore.
Sometimes several gangs of hands will be working upon the same vein,
a board and timber floor only separating one set from another.
When I have added to this description that this business of digging out veins
has continued here for near 300 years,
it can well be conceived that this mountain ridge has become a sort of honeycomb.
When our party had reached the limit of descent, we turned aside into a gallery and made our way among gangs of workmen,
silently pursuing their daily labor in galleries and chambers reeking with moisture,
while the water trickled down on every side on its way to the common receptacle at the bottom.
Here we saw English carpenters dressing timbers for flooring by the light of tallow candles
that burned in soft mud candlesticks adhering to the rocky walls of the chamber.
Men were industriously digging upon the vein, others disposing of the rubbish,
while convicts were trudging along under heavy burdens of ore,
which they supported on their backs by a broad strap across their foreheads.
As we passed among these well-behaved gangs of men,
I was a little startled by the foreman remarking that one of those carriers
had been convicted of killing ten men and was under sentence of labor for life.
far from there being anything forbidding in the appearance of these murderers
now that they were beyond the reach of intoxicating drink
they bore the ordinary subdued expression of the mestizo
according to custom they lashed me to a stanchion as an intruder
but upon the foreman informing them that I would pay the usual forfeit of
cigarettes on arriving at the station house
they good-naturedly relieved me then we journeyed on and on
until my powers of endurance could sustain no more
We sat down to rest and to gather strength for a still longer journey.
At length we sat out again, sometimes climbing up, sometimes climbing down.
Now stopping to examine different specimens of ore that reflected back the glare of our lights
with dazzling brilliancy, and to look at the endless varieties in the appearance of the rock
that filled the spaces in the porphyry matrix.
Then we walked a long way on the top of the aqueduct of the adit, until we at last reached a
vacant shaft, through which we were drawn up and landed in the prison house, from whence we
walked to the station house where we were dressed in our own clothes again. End of quote.
Like the kaffirs of the Kimberley diamond mines, the Mexican workmen are adepts at stealing.
They try every possible device which may enable them to carry off pieces of rich ore.
The hollow handles of hammers, the ears, the spaces between the toes, the mouth, and cigarettes
all serve as hiding places. Accordingly, the men are carefully searched three times when leaving work.
The Real Del Monte mines have been worked with profit ever since the Mexican company took them over,
new deposits being struck from time to time. Not the least interesting features of a great mine
are the reduction works, or haciendas, where the silver is extracted from the ore.
Twelve miles from the real is the regla hacienda, built by the first count in the bottom of a very
picturesque valley. It is a very extraordinary group of buildings, externally much resembling a castle,
since the massive walls are loophole for defense. Inside are magazines, courts, furnaces, mills,
smelting, and amalgamation works, built over dungeons, vaults, and tunnels. Let us enter a mill
and see how the Mexicans treat the ore. In a large yard, boys and women are breaking up the
ore with hammers. When broken, it is sorted. The use
useless rubbish being cast aside and the rich portions being placed in a Molino, which is somewhat
like the mortar crusher used on large building operations.
Large circular stone rollers are drawn round and round into the trough of the Molino by mules,
until the pieces of ore have been broken up very small.
The stuff is then transferred to an Arastra, a basin nine to twelve feet in diameter lined
with cement.
Heavy stone blocks moved round by animal or water power, reduce it in the water which has
been gradually added to a kind of thick mud paste.
The mass is next poured out on a large floor carefully paved with stones or wood and enclosed
by vertical sides.
After it has been allowed to dry a few days, salt is added and mules are turned in to tramp
it for two or three days.
Sulfate of copper, lime, and quicksilver are thrown in also, and the trampling continues
for 70 more days. According to some writers, the quicksilver and other chemicals rapidly destroy
the hoofs and tails of the poor mules, though others say that the evil effects are small.
Judging, however, by the damage done to plumbers and other workers in metal by metallic poisoning,
we can easily understand that continuous immersion in a chemical mixture such as has been
described might soon prove disastrous to animal tissues.
Presently the time comes when the official tester must decide whether the mercury of the torta or paste has been fully amalgamated with the silver.
On his judgment depends perhaps the fate of several thousands of pounds worth of metal.
He is responsible for the proportion in which chemicals must be added to secure the best results with any one torta.
The quality of the ore varies and its treatment must also vary according to its nature.
When he gives the word, the mass is carried to an immense washing machine,
driven by water, which separates and expels the dross, leaving the silver-impregnated mercury.
The amalgam is then retorted and cast in bars from minting or export.
Foreign capital is, of course, altering mining methods,
and the patio system just described will doubtless give place in the future to one more scientific.
At present, however, it holds its own as being very cheap.
and yet effective, though tedious. Silver is doing for Mexico what precious metals have already done
for many other countries. Apart from enriching the actual owners and citizens, it has caused the
settlement and cultivation of large areas upon which a mining population must depend for its subsistence.
The increased need for transport of silver and machinery is responsible for the ever-increasing
network of railways, which at the coast terminate in fine harbors. A notable instance of
of Enterprise being the Newport at Veracruz.
Besides her great mineral deposits, Mexico has what is even more valuable.
A stable government controlled by a great-minded man,
who not only himself has clearly before him the path which he wishes his country to pursue,
but also has instilled into his helpers a large portion of his own enthusiasm,
so that when he is taken, worthy successors will be left to continue his work.
End of Chapter 12, read by Geoffrey Wilson, Ames, Iowa in December of 2022.
Chapter 13 of The Romance of Mining
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mining by Archibald Williams
The copper mines of the Rio Tinto
The natural riches of Spain
Early miners
The Carthaginians
The Romans
Blindness of Spaniards
The irony of history
The Rio Tinto
Modern Development
Vallejo
Valiant
Liberto Volters
Early Company Promotion
Report on the Rio Tinto's resources
Samuel Tiki
Thomas Sance
The Spanish government tries its hand
The Marquis de Rémes
The government decides to sell its rights
French invaders
German invaders
Dosh, Sundheim and Bloom
A gigantic payment
The Rio Tinto Mine
Separation of copper from its ore
Spain's future
Wanted
The effects of misrule and maladministration on Spain
Has been to place her among the lesser powers of Europe
Stripped of her colonies
By secession after secession
Early in the 19th century
Stripped of her navy
Cuba and the Philippines by the disastrous war with the United States, Spain, who once yielded to no other nation in pride and might, who shook the nations of the new world with but a handful of her chivalry and sent against England the mightiest armada that had yet been seen, now stands apart, poor, proud and reserved, waiting till fortune shall give her rank and prestige again. To imagine that Spain is a country without natural
resources would be to commit a grievous mistake. Gold, silver, copper, tin, iron, lead, coal,
quicksilver, she has them all generously stored in her rugged bosom. So that, were her wealth properly
exploited, she would probably eclipse the output of any other European country. The richness of her
mineral supplies was discovered many hundreds of years ago by the Phoenicians, who mine for gold,
along the Guadalquivir before the time of David.
Later on, her silver stores came to light,
and the Carthaginians raided the country to get labour for the mines.
After the fall of Carthage,
the Romans took up the work,
transporting thousands of captives to toil in the mines which they had formerly owned.
They produced large quantities of silver and copper,
besides gold, and have left their marks in many a fold of the Cierras.
In course of time, the richest thus won from Spain made Rome overwealthy,
and she shared the fate of luxurious nations.
The Goths, Vandals and Moors, who overran the peninsula, did little mining.
The loads opened by their predecessors remained idle for centuries.
Even when Spain was at the zenith of her power,
with Ferdinand and Isabella on the throne,
her people, straining eagerly to the El Doradoes of Mexico and Peru,
were oblivious or ignorant of the greater wealth
lying neglected beneath their very feet.
It is a strange example of the irony of history
that when Columbus sailed on his first voyage to America
he left behind him, within 50 or 60 miles of the fishing port he sailed from.
Mineral deposits which were destined to produce
a more famous mine of its kind than has yet been discovered across the Atlantic.
The dark waters of the Rio Tinto, on which he saw,
pioneer ships floated out into the unknown ocean, owe their colour, to a mountain of copper,
which has yielded almost as many solid millions of money, as have been got out of the Comstock
load or the Kalamet and Hekla. The name of the subject of this chapter, having now been mentioned,
we may turn at once to the history of one of the world's most remarkable minds, remarkable
alike, for the vicissitudes through which it has passed, its extent, and the vastness of its
wealth. Let us then, first be quite clear as to the Rio Tinto's position on the map.
So follow down the boundary line between Spain and Portugal till you reach the province of Huelva,
and about 30 miles north of the town of that name, you will find Los Minas de Rio Tinto
on the southern slope of the Sierra Morena. From this district, for district it is rather
than a place, comes one-tenth of the copper mined annually in the world.
Who first delved here for the metal is and must remain uncertain.
Indeed, we do not get on the centre of facts till the middle of the 16th century
when a formal report containing some truth and a good deal of fiction
was made on the mines by government inspectors.
It drew so rosier picture of the deposits that Adon bought the rights to them,
with what success we do not know.
A century or more passes,
and Don Sebastian Valljejo is found busily engaged in the Sierra
precipitating copper from the ore.
He too disappears into obscurity,
while Don Nicholas Valiant emerges,
secures a lease for 30 years,
and fails to make anything out of his privileges.
The first really practical man to attack the great riches of the Rio Tinto,
was a Swede, Liberto Volters by name.
In the early part of the 18th century,
Sweden lost much of the prestige won by Gustavus Adolphus Charles X and Charles X,
but with the passing away of her military power,
her commercial enterprise, stimulated no doubt by the great wars in which she had engaged,
did not disappear also.
Swedes penetrated into all parts of Europe and became preeminently successful
as miners. Volta's, a native of Stockholm, came to Spain in or about the year 1700. At first, he practiced the
profession of a diver in Vigo Bay and probably made a good profit out of his work since in 1725, when the Rio Tinto
mine was in need of a lessee, he offered to lease it and form other mines for 30 years, agreeing to pay the crown
a royalty of one-thirtieth of the all-mind.
Not being rich enough to finance the undertaking entirely by himself,
Volters took the step which today marks the beginning of so many commercial enterprises.
He promoted a company, with a capital of 100,000 Dubloons, or nearly 400,000 pounds sterling.
Of the 2,000 shares, Volters kept 700 for himself, as vendor shares.
and through the other 1,300, open to public subscription.
It is interesting to note how closely he followed modern methods.
Shareholders were given the opportunity of paying in installments.
Five doubloons on application,
10 on the last day of May 1726,
10 on July 1, 1726,
and the remaining 25 at such times as the management should consider it convenient,
to make a call.
The shares seem to have found ready purchasers
who included persons of rank and distinction,
even some ladies of the royal household.
Yet the public press did not forbear
to hurl at the enterprise many envenomed darts
tipped with such terms as liar, swindler and heretic,
the last, no doubt most effective
in the country of Tokimada and the Inquisition.
It was probably owing to fears of priestly enmity that Volta's included in his lease
of stipulation that any foreign employees of the Protestant persuasion
should not be interfered with so long as they did not proselytize or air their opinions too openly.
In order to cut the ground from under the feet of his adversaries,
Volters did a very wise thing.
Scarcely had the first instalments been paid on the shares,
when he appointed a mining engineer to examine the mines and draw up a report, just as is done today.
The report for which an Englishman, Robert Shee, was responsible, said a great deal without giving much real information.
It served, however, to quicken public interest greatly in the scheme, with results somewhat disastrous to the promoter,
who soon found himself at variance with his fellow shareholders
on pretty well every point which could be made the subject of dispute.
The king, to whom reference was repeatedly made as umpire,
finally decided in 1727 that the company should be separated into two distinct enterprises.
Vultors retaining the Rio Tinto and Arthena mines as his portion,
while the mines of Cathala Guadalcanal and Galarotha went to the other shareholders.
Volta's got the better half of the bargain, but at such a cost to his constitution that he shortly
afterwards died, leaving his property to a nephew, Samuel Tike, also a Swede, and a practical minor.
Unfortunately, TK became involved in a litigation suit with an Englishwoman, Lady Mera Terriq.
Heza Herbert, who had lent money to the company, and now sued it for breach of contract.
The verdict went in her favour, and she entered into possession of all the five mines.
But T.K., being a man not easily beaten, appealed against the decision and was reinstated in his property,
though not before the lady owner had played havoc with some of the mining and reduction plant.
To the end of his life, he died in 1758, TK continued an uphill struggle against heavy odds.
His successor, Francesco Thomas Sance, fared equally badly, and the end of the lease found the Rio Tinto mine with its fabulous resources, ready to the pick,
yielding a beggarly 100 tonnes or so of metal a year.
In 1777, the Spanish government once more tried its hand at administrative.
during the mine in order to get material for its bronze currency.
But money was supplied to the management in such niggily quantities
that little progress could be made.
The Peninsular War, which paralysed all industry in Spain,
caused the abandonment of the mine for nearly 30 years.
Then the government, in 1828, offered the mining rights at auction
for a period of 20 years.
The highest bid came from a Frenchman, the Marquis de Rémen,
who offered 2,600 pounds per annum for the first 10 years
and 3,100 pounds per annum during the remainder of the lease.
He seems to have worked the mines with fair success
and certainly increased the yearly output to over 2,000 tonnes.
When his lease fell in, the government again took over the task of converting copper into cash,
which they now sorely needed.
whether the Spanish official was radically incompetent or was so enmeshed by red tape that common-sense mining practice proved impossible, we cannot say.
Whatever the facts may be, the government decided, in 1872, to sell the property which for centuries had been the source of endless squabbles, litigation and loss.
We must now retrace our steps a few years to see how it came about that Spain found a purchaser of one of her greatest.
treasures. Mr. W. R. Lawson in his book draws attention to the fact that Napoleon the 3rd's coup d'etat
in 1851 practically exiled many Frenchmen who took the anti-bonaparte side. A large number
emigrated to England. Others, of a more adventurous turn, crossed the Pyrenees into the land
where half a century earlier
the legions of the great Napoleon
had held temporary sway.
Attracted by stories of Spain's mineral wealth,
they sent men in advance to spy out the land and report.
The forerunners passed southwards to Huelva,
searching for the mines associated by legend
with the Tarshish of scripture.
And after examining the Rio Tinto,
which did not suit their fancy,
fixed upon the Tharsis
in a neighbouring valley.
They obtained a lease from the government
and worked the property until bought out
by a Scotch syndicate.
Another political upheaval,
the American Civil War,
led to a second invasion of Spain by fortune hunters.
This time, they were Germans,
whose livelihood in the States had vanished
amid the clash of arms.
And Mr. Doche became manager of the Rio Tinto.
Wilhelm Sundheim started a shipping business
at Huelva, while Mr. Bloom sat down and watched what was going on at Tharsis, Andrio Tinto.
His deep mineralogical knowledge soon caused him to recognise the true value of the immense copper loads,
and he gave his two friends his opinion on the subject.
At this time, 1872, Spain had only just emerged from the Karlist War,
in a state verging on national bankruptcy.
It became absolutely necessary
to realise such assets as could be changed into money.
And when a bill drafted by Messrs. Doche and Sundheim
for the sale of the Rio Tinto mines by auction
was brought before the Cortez,
it soon received ratification.
On February 14, 1873,
the tender of some English bankers,
Mrs Matheson and Company
of £3,712,000, was accepted,
and the Rio Tinto passed into the hands of an Anglo-German group of financiers.
The enormous price paid for a property which,
considering its now ascertain value,
can scarcely be said to have been more than scratched,
may seem to mark a gamble of unprecedented proportions.
Yet the purchasers were hard-headed men who, though they took risks, did so with their eyes very wide open,
and not until the loads had been fully reported upon in a manner somewhat more scientific than that of Volta's expert.
The confidence placed in the reports was fully justified.
At first, shareholders who had bought in a hurry sold as hastily, ten-pound shares going for thirty shillings.
They were glad to repurchase at £30, and today the shares are worth more than £60,
despite the immense sums that have been spent since the purchase on railways and dock accommodation at Huilva.
The Rio Tinto is undoubtedly the largest mine in the world.
It covers eight square miles and gives subsistence to 50,000 people.
It is worked by tunneling and also by the open cast system
Which merely clears off the overburden or useless earth
Etcetera and quarries down into the deposit
There are hills through which cross cuts have been driven for 250 yards
Without emerging from solid ore
The area of the mine says Mr Lawson
Is covered from end to end with masses of red and grey earth
looking like gigantic ash heaps.
A few of these are the natural hilltops,
which it has not been thought worthwhile to remove.
But most of them are artificial mounds
formed during the operations of the mine.
That towering mass of broken slate and granite
in the distance was made by the Romans,
whose implements and domestic utensils
are found in it to the present day.
That high embankment of blood-red clay and porphyry,
with two lines of railway running along the top of it,
is overburden.
It represents millions of tonnes's weight
and has been carried miles away from where nature placed it.
In the hollow below,
there is as much slag or cinder from the blast furnaces
as would pave all London.
And it is but a fraction of what
the furnaces have turned out. Every year thousands of tons of it are put on the railway as ballast,
and wherever a chance occurs it is made away with, but still it goes on growing.
Rio Tinto was wild and desolate enough when the copper mine has laid hold of it.
But that was grace and beauty compared with what it is now.
Pluto himself, lurid as his fancy is supposed to be, could not have conceived the idea of
of such a scorched, scarified and grimy wilderness
as it has since become.
It is pandemonium painted red
and set out to roast in a blazing sun.
The terraces of the open castes
are traversed by nearly 60 miles of railway
on which more than 30 locomotives
and 750 wagons are running daily.
From one end of the workings to the other
is a journey of seven or eight miles,
curving in and out of hollows,
crossing points, running up one slope and down another,
and your engine all the while,
shrieking to signalmen at every few hundred yards.
Walking is out of the question in such a country.
Short journeys, the superintendents do on horseback,
but for long ones, they have to take the rail.
When they wish to look round,
instead of calling a handsome, they send for an engine and car.
It takes them quickly over the ground and gives them a good elevation to see from.
The copper forms but a small part of the ore.
Sulfur is present in large quantities, also iron.
Only the richest ore is smelted on the spot.
A considerable portion of the ore is taken direct from the mine to ships at Huelva,
whence it travels to England and other countries.
Some again is reduced by calcination, ready for the smelter and so shipped.
One of the most lucrative processes is that of precipitating the metal from water
which has been allowed to pass through heaps of refuse and smalls or dust ore.
In fact, no mining industry is more complex than that of separating copper from its matrix.
This partly accounts for the high price of copper, about one-fifieth that of silver, which for years past has steadily depreciated.
The world's demand for copper is in advance of the supply, largely because of the immense quantities of the metal used in electrical equipments.
It would be a great boom to civilisation if the price were halved, while still leaving a sufficient margin for the producer to make mining a profit.
business. As time progresses, improved and economical means of reduction are discovered,
but at present there appears to be no parallel between the copper and steel industries in this
respect. Copper mining is also hampered by the great cost of dragging the ore from
depths seldom reached in connection with other minerals. The future welfare of Spain is
bound up with the advance of agriculture
and the further tapping
of her mineral wealth.
The Saracens were tillers of the soil
and converted many barren stretches of sandy desert
into well-watered gardens
and today the eastern provinces
are noted for their fertility and high cultivation.
Though agriculture must in all countries
be the foremost industry,
that one upon which the health
as well as the wealth of a nation must depend,
mining comes in a very good second as the provider of riches
and it is for this reason that future generations should witness a great change in the peninsula
as soon as the internal condition of the country is such as to attract foreign capital
in larger measure than today railways will be run through hundreds of districts
now far removed from the sound of the locomotive's whistle
The examples of Rio Tinto, Almeiden and Bilbao
will lead to a hundred other enterprises
among the gold, tin, lead, coal and silver deposits
which are waiting to make Spain one of the richest kingdoms of the world.
When the Spaniard is ready to turn from his old-time doctrine of
manana, tomorrow, and lay his hand to the splendid task before him,
We may live to see Spain once more
The greatest mining country of Europe
Such as it was
When the Romans sent their thousands of slaves
To work their wretched bodies to death
In the horror chambers of the Sierras
Such as it was
When a thousand years earlier still
The Phoenicians sent their ships
From Tyre and Sidon
To fetch treasure
From near the pillars
Of Hercules
End of Chapter 13.
Read by Bryn Roberts.
Kings Winford, December 2022.
Chapter 14 of The Romance of Mining.
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The Romance of Mining by Archibald Wood.
Williams, Section 14, Other Famous Copper Mines
The copper contributions of different countries, the United States, the Lake Superior
Deposits, History of Their Discovery, A Large Mass of Solid Copper Found, Sensational
Blocks of Metal, The Calumet and Heclamine, a huge shaft, machinery at the mine,
refining, a bad speculation, the Montana deposits of Butte, the Anaconda Mine,
Bessamerine Copper, Arizona, California, the Copper Mines of Ashio, Japan, Fallon, Remelsberg,
splitting rocks with fire, the Burra Burra Mine, British Copper Mining, a decayed industry,
the Paris Mountains Anglesi, concluding remarks.
At the present time, the United States produces far more copper than any other country.
While Spain yields about 50,000 tons annually, Mexico 40,000, Australasia 29,000, and Japan 30,000,
the United States furnished 275,000 tons out of the world's
total of about 525,000 tons. That is to say, more than half of all the copper mine comes from
the land of the stars and stripes. Three states take the lion's share of the copper industry.
Montana heads the list with about 250 million pounds weight. Michigan comes second with about
$150 million, and Arizona 3rd with $115 million. At ruling prices, the output is worth over $86 million annually,
a sum which gives copper the first place among metals in the United States after iron.
The most famous copper district in the New World lies on the south shore of Lake Superior,
in a tongue of land known as the Kiwanah Peninsula.
Parallel to the water, a few miles inland,
runs the mineral range intersected by veins of the metal.
Before noticing individual minds,
we may glance at the discovery and history of these remarkable deposits.
The early exploration of the country, bordering Lake Superior,
was undertaken by Jesuit priests,
who played a very important part in Franco-American history of the 17th century.
The frequent occurrence of copper was one of the objects that early attracted their attention,
and its presence so often met with among the Indians,
naturally excited their curiosity and wonder.
Repeated mention of it is made, and in some instances the descriptions relate to masses of considerable size.
but long prior to this period the metal that attracted the attention of the missionaries and early voyageurs in which now forms the basis of a great industry had been sought and mined for by a people who have left no record but the implements which they used in the excavations which they made
These excavations had been obscured from view by the slow growth of overlying debris during the years which had since elapsed,
and the Indians had no knowledge of the workings of their prehistoric predecessors.
In fact, no suspicion that any such mining had been done occurred until comparatively recently,
after the country had been settled in prospectors had commenced operations.
then it became known that the copper veins of the district had apparently yielded large amounts of metal to some forgotten race that the old occupation of the loads was very ancient was evident from many facts
pits and tunnels had become filled with rubbish and overgrown with large forest trees if depressions were ever observed they were naturally regarded as those made
by overturned trees or as hollows and rocks, and it was not suspected until the actual discovery,
as late as 1847, that the district had once been busily mined. So general are the ancient excavations
of the mineral range that there is scarcely a vein or outcrop in the whole copper district
which does not bear signs of the old miners.
Some of them pits sunk 50 feet or more into the solid rock.
In these pits, when cleared of rubbish,
have been found large masses of copper
which the primitive seekers had unsuccessfully tried to remove.
Lumps of solid copper, weighing many tons,
have been discovered surrounded by numerous stone hammers,
pieces of burnt wood, and other evidences of former labor.
It is obvious from the nature of these finds that the rock was heated and then split by pouring
water on it to make it friable enough for smashing with the stone hammers,
which consisted of small boulders of hard rock weighing three to 30 pounds,
round, which a groove had sometimes been made to hold an osier handle.
The old-time miner knew his business so well that modern prospectors have sought eagerly for these ancient pits
as betokening the outcrop of the copper loads.
In 1760, an explorer, Alexander Henry found a great copper mass about twenty-two.
20 miles above the mouth of the Otnangan River.
Ten years later, he took men with him and tried to secure the metal, but only managed to chip
off some pieces.
In 1820, General Lewis Cass, governor of Michigan, led an expedition to the same spot.
The party had great difficulty in ascending the rapids and climbing over the mountains under
a blazing sun, while harassed by countless flies and mosquitoes.
The general became exhausted, but the others, pushing on, discovered the object of their search,
which, though not so big as they had anticipated, was still considered a remarkable object.
It had evidently been much reduced from its original size.
In broken tools lying about showed that several persons had attempted to hew it to
bits. This mass of native copper, the largest that at that period had ever been found,
was transported bodily down the river in 1842 and sold to the United States government,
who set it up in the grounds of the War Department at Washington.
Its arrival caused quite a sensation among mineralogists, and soon the district from which it
had come was swarming with speculators, prospectors, and explorers, all bent on tapping the mother load.
In the, quote, cliff mine, other large masses were soon encountered, the first being struck in
1845. This discovery was of great importance, since it determined the fact that the erratic boulders
previously found had their origin in the region itself.
It was the precursor of a succession of masses that astonished the world
and gave confidence to investors and enthusiasm to the workers.
In 1852, a mass weighing 200 tons, 40 feet long, 20 feet wide, and 2 feet thick,
was discovered in the North American mine close by.
But a few years later, this huge block was quite eclipsed by lumps found in the
Minnesota company's mine. Of one of these, the engineer wrote, quote,
It was at once apparent that they had something very valuable, but they had no conception of the
immense thing which a few days worked disclosed. At one convenient point, they broke away
behind the copper so as to get in a sandblast of five or six kegs of powder. They stripped the
mass further and again fired without result. Again they fired nine kegs of powder and the mass remained
unmoved. Breaking the rock around for a considerable distance, 18 kegs of powder were shot off without effect
and again 22 kegs and the copper was entirely undisturbed at any point. After further clearing,
25 kegs were shot off under the copper and it was thought.
with some effect, but a final blast of 30 kegs or 750 pounds was securely tamped beneath the mass and fired.
As soon as the smoke cleared away, a mass of copper 45 feet long and 3 to 5 feet in thickness, apparently very pure,
and which will probably weigh 300 tons, had been shot out and was ready for cutting up.
it was torn off from other masses which still remain in the solid rock, end quote.
A later report says, quote, there is now in the Minnesota mine, between the added in the
ten-fathom level, a single detached mass of apparently pure metallic copper,
which is some 45 feet in length, and in the thickest part as much as eight or nine feet in
thickness. It contains probably more than 500 tons of pure metal and is worth as it lies
more than $150,000, end quote. It took 20 men 15 months to remove this monster, which had to be
hewn asunder as it lay. Some of the cut faces measured 16 square feet, and the mere chips weighed
over 27 tons. Truly a splendid find, the largest and most valuable nugget,
quote, ever struck by a miner. Among the Michigan copper mining companies, that known as the
Calumet and Hekla stands preeminent. It produces more than half of all the Kiwanah metal, and is
further remarkable for the fact that it rivals the neighboring Tamarack mine in possessing
the deepest shafts in the world.
Quote, in all the estimates and considerations
applicable to other mining companies,
this mine must be accepted.
The mine so exceeds all others in extent and richness
that there is none to be compared with it
in product or in profit.
If any comparison is instituted,
it must be borne in mind
that the Calumet and Hecla load is
probably by far the richest vein ever known in the annals of copper mining, end quote.
From mineral statistics of Michigan.
The mine is situated about five miles from the shores of Lake Superior and about 12 miles from
Portage Lake, which with the Mineral Range Railroad connects it.
The Calumet Company was started in 1865 with shares that stood at a
dollar apiece. But the profits were so large that the price rose rapidly to $30, and a few months
afterwards to $75. In 1871, the Hekla Company, which was working close by on the same
load, amalgamated with the Calumet, and the two ventures have since been run as one very
successful concern. Within three years of joining forces, dividends of 2,800,000.000,000,000
thousand dollars had been paid on the total capital of a million dollars. By 1881, dividends
aggregated nearly $19 million and enough money had also been spent to install mining plant
superior, it is believed, to that of any mine in the world. Everything here is on a gigantic
scale. The red jacket shaft is known, by name at least, to mining engineers all the world over.
This was begun in 1889, and for 12 years men worked on it night and day until a huge well,
4,900 feet deep and 14 by 22 and a half feet in section, had been driven down through the rock
in copper-bearing conglomerate.
One and a half million cubic feet of material were removed,
with the aid of power drills and dynamite.
And the excavation was lined from top to bottom with pine,
besides being divided into six separate compartments.
The amount of timber needed for the work was enormous,
enough to represent the destruction of a large forest.
The shaft is so consistent.
that in case of fire in the mine, the men can make their escape through it when all other
means of exit are cut off. Two disastrous fires in 1887 showed that it was necessary to make
provision for similar accidents in the future. Hence, this great work, the magnitude of which
will be more fully realized, if you consider that five Eiffel towers piled one on the top of the other,
would not total in height the depth of the shaft.
In addition to the red jacket,
the Calumet and Heckla Company can boast no fewer than 11 shafts
averaging about a mile in depth.
Through them, the load is worked horizontally
for a distance of two miles.
For hoisting from such depths,
great speed is necessary to avoid undue loss of time.
Two huge engines dominate,
the top of the red jacket, up which they whirl the cages at a rate of nearly 20 miles an hour.
They form one of the most striking features of the whole plant.
Quote, the twin engines, the Minogue and the Siskoit, as also the Messnar and Pontiac,
are the finest engines on the mine. The two latter are held in reserve in case of accident.
and here it might be said that the Calumet and Hekla have duplicated every engine on the mine.
Some idea of the size of the engines at the red jacket shaft may be gained from the weight of some of their parts.
Engine bed, 76,100 pounds, main pedestal bedplate, 150,722 pounds, end piece for bedplate,
19,466 pounds,
cylinder, 25,500 pounds,
engine beam steel, 64,920 pounds, end quote,
from Cassiers magazine.
To ventilate the mine, huge gieball fans, 30 feet in diameter,
pour air down the shafts all day long.
and to work pumps and drills, high-pressure air is forced down through many miles of piping.
As at the De Beers mines, Kimberly, quote-unquote forwards, is a word which the engineers are very fond of.
And when any improvement in machinery appears, they soon adopt it for their own uses.
Consequently, the mining student can hardly find a better school in which to learn his trade.
than the domains of the calumet and hekla.
The ore mine is very equal in quality,
though it contains only 3% of copper.
Huge masses of solid metal are not found at extreme depths.
But as the vein is in places 30 feet wide,
it can be worked economically.
Indeed, copper being so extremely tough,
the dismemberment of large solid lumps
might be even more costly than the reduction of comparatively poor ore.
Owing to the perfection of the machinery used,
or containing only a few pounds of metal per ton can be treated profitably.
The levels or galleries are 100 feet apart vertically.
Large gangs of miners blast and chip the ore from the, quote,
stopes or blocks formed in the vein by verticals,
and horizontal channels cut through the vein right across its breadth.
The quote, stuff is dumped into cars, each of which holds three tons.
The cars are run into cages in the shafts and soon reach the surface.
There the ore passes into a crushing plant, which smashes it until no lump has a diameter
exceeding six inches, and then is dispatched to,
the stamp mills at the lake's edge. These can each reduce upwards of 500 tons of ore per diem
to the size of small marbles. The rubbish is washed out by apparatus somewhat resembling the separators
described in connection with the rand gold mines, and the residue goes straight to the smelting
furnace, since the ore is singularly free from those chemical impurities which in other districts
such as the Rio Tinto
render copper reduction
of very complicated business.
The furnaces used are of the
reverberatory type. The ore
lies in the shallow,
dish-shaped chamber of fire brick,
and the flames of the furnace
in an adjacent compartment
pass over the top of the intervening wall
and are deflected down onto the ore
by a roof of very refractory,
therefore fireproof material.
The slag and scum is skimmed off
and the molten mass is kept stirred
through openings in the sides of the hearth.
When scum ceases to appear,
the copper is ready for tapping
and is run off into ingot molds.
Quote, Lake Copper is famous for its high quality.
At the lower depths,
the percentage of arsenic in the ore increases
and to get rid of this unwelcome element economically,
the Calumet and Hecala people send a lot of their stuff to refineries at Buffalo.
Though many extraordinary successes marked the copper mining history of Michigan,
there have been equally gigantic failures.
To anyone coming to the Kiwanau Peninsula,
and seeing the amount of ore raised from hundreds of shafts dotted about here,
there and everywhere, it would appear probable that other shafts sunk in their immediate vicinity
must sooner or later strike ore, but that such conclusions, if acted upon, sometimes have unexpected
and unpleasing results, may be well illustrated by the case of a Philadelphia syndicate,
which some years ago bought up large tracts of land in the Kiwanaw, and made preparations for a campaign
which would take the wind out of the sails of some other big concerns.
So confident were the promoters of success
that while their huge shafts were piercing the earth,
they built the finest stamp mill in Michigan,
ready for ore that would presently pour up from the workings.
They also went to the expense of a private railroad connecting mine and mill,
and dug a canal from the mill to the lake.
But alas, the experts for once had made a lamentable miscalculation.
The winding engines puffed and panted.
The rock drills bored.
Dynamite rent the rock.
The miners toiled on, looking for the color that would tell them,
their work had not been in vain.
Thousands of tons of useless, barren stuff came up in the skips.
The managers wore a look of increasing anxiety,
when the level at which ore should have shown had been passed and still there was no sign.
At last the terrible fact could no longer be denied that tens of thousands of dollars had been
flung into the pit beyond hope of recovery. The engines ceased to turn, the miners sought work
elsewhere, and now the rust-eaten machinery in massive buildings stand as warning against overconfidence.
The copper-bearing district of Butte in Montana has been exploited over an area not exceeding two square miles,
yet from this small block comes nearly half of the metal mined in the states.
The Anaconda mine is to Butte what the Calumet and Hekla is to Kiwanah.
Vertical fissures in the granite, varying in breadth from a few inches to 100 feet,
have been filled by nature's laboratory work with a compound of silica, iron pyrates, sulfur, and copper.
Silver also occurs in the proportion of 2 to 6 pounds per ton of ore, and there is a very small percentage of gold.
Large caverns are dug in the ore bodies and timbered on the quote square set principle used at the Comstock and at Leadville.
ore is raised in 10-toned skips and sent by rail to the Great Reduction Works at Anaconda,
where a huge plant capable of handling 5,000 tons per diem covers 60 acres.
After being crushed between huge rollers and washed,
the ore goes to the mechanical roasters which drive off water in some sulfur
and leave material fit for the furnaces.
These eliminate more of the impurities until the residue about one-half copper is ready to be run into iron tanks carried on rails,
transferred to the converter, and treated by the Bessemer process, air being blown through the liquid copper to drive off more sulfur,
and cause the iron present to combine with a silica which lines the converter.
The converter which swings vertically on two trunnions or pins and somewhat resembles a champagne bottle
with the top of the neck cut off is tipped over till the charge can be poured in through the narrow
mouth of the top. Then the air blast is turned on. Thousands of cubic feet of air rush through the molten
metal and cause a greenish flame to roar from the mouth. The iron combines with the lining to form
slag, while part of the sulfur present passes off as sulfurous acid gas.
By the time that the process is complete and the slag has been removed, 99% of what remains is
copper. To separate any gold or silver carried by the copper, electricity is used.
The metal is first cast into large plates, which are immersed in a chemical bath and connected
with the one terminal of a strong electric circuit,
which deposits the copper on a second plate, also in the bath,
connected with the other terminal of the electric circuit,
and allows the more precious elements to sink to the bottom of the tank
in the form of mud, which is afterwards refined.
This method of reduction is much more complex than that
which circumstances permit at the Calumet and Hekla.
though by no means so intricate as is the series of operations necessary with some other very impure copper ores.
Arizona, the third great copper state, could once, like Michigan, boast many rich surface deposits,
found in caves in the limestone, consisting of very beautiful blue and green crystals called azurite in malachite,
which contain in some cases 25% of copper.
So profitable was the smelting industry,
in spite of difficulties in getting a good supply of fuel,
that the smelters did not hesitate to cast aside slag carrying 2 to 3% of metal.
Richer, that is, than much of the ore to get which such enormous shafts are sunk in Michigan.
The United Verde mine at Jerome is the largest copper.
copper mine in the world owned by a single person. As it produces 20,000 tons a year, and as the copper
contains enough gold and silver to pay all costs of extraction, the proprietor, Senator W.A. Clark
ought to be a wealthy individual. California, though so rich in other minerals, can claim but one
copper mine of importance, that of Shasta. Her annual production is about 15,000.
tons. Tennessee mines about half this quantity. Turning to other countries, we find that Mexico
takes a leading place as a copper yielder. The Baleo deposits in Lower California are the most
valuable. Chile has in half a century produced over two million tons, but at present its output
tends to decrease.
35 years ago, Chile furnished half the world's supply of copper.
Japan, on the other hand, is coming to the front.
The development of Japan's natural resources has been as remarkable as her increase in military power.
Though sulfur, gold, and copper have all been worked by the, quote, gentle Japs from time immemorial,
the methods employed were till lately very primitive.
When in 1853, Japan abandoned her policy of isolation
and gladly welcomed Western ideas, mining at once went ahead.
Today she produces 30,000 tons of copper,
a large proportion of which is exported to China and Korea for minting purposes.
Japan's great copper district is that of a shio,
near Niko in Hondo, a town which tourists visit on account of its fine scenery and magnificent shrines.
From Niko, the mines may be visited in Jin Rickshaws.
Quote, tea houses along the route exhibit beautiful specimens of copper pyrites,
which are sold to pilgrims to the sacred mountain of Naitaisan, close by,
and the traveler is also notified of his proximity to the copper mines by the tram cars passing through the streets of Niko,
drawn by slow-moving bullocks laden with copper ingots on the down trip and returning with fuel.
The change from Niko is complete.
One leaves a land of peace with delightful surroundings and steps into the midst of a foul-smelling, smoke-laden valley,
where the bare red hill size denuded of all vegetation
present a striking contrast to the green hills of Niko
with its world-famed avenue of Cryptomirius
while the air vibrates with the clang of hammers in the throb of engines,
end quote, from the engineering magazine, October 1901.
The writer whose words are here quoted
goes on to say that the village of a.
Shio has flowing through it a stream spanned by numerous bridges of design so different that the
visitors left with the impression that the, quote, engineer in charge must have, quote, put into practice
all the available literature of bridge designing, end quote.
Over 10,000 people are employed in the copper industry here, in a large number of whom
had never seen the country lying beyond the red encircling hills
till the Great War gave them the signal to join the contingents
hurrying to meet the Russians in Manchuria.
The village has a well-equipped hospital
at which the miners and their families are treated free of charge.
Only men work below ground,
their women folk finding employment in the sorting and washing of ore.
The pay is seven pence a day,
and a small allowance of rice and fuel,
though the more skilled mechanics earned 15 pence.
Not a very tempting remuneration as judged by Western standards.
The mines are entirely managed and organized by Japanese,
yet they are equipped with up-to-date machinery and appliances throughout.
Reverbatory furnaces, electric light, electric cars,
a 30-mile railway and a three-mile cable car over the mountains for transporting copper ingots and fuel.
The ore is very rich in metal, which averages about 20 percent,
so that with labor as cheap as it is, Japanese copper must prove a formidable competitor to that produced
where the percentage is lower in labor much more expensive.
Though originally the property of the Japanese government, the mines are now owned,
by a single proprietor who, like Senator Clark, must be well on the road to millionairedom
if he has not already reached the desired goal. Other famous copper mines are those of
Fallen in Sweden said to have been explored before the Christian era. At their most prosperous
period, they yield 5,000 tons of metal yearly, besides large quantities of lead. Then there is the
celebrated Ramosburg deposit in the Hars Mountains of Germany, which is like an inverted wedge,
the thickness of the vein increasing as it descends. It has been an operation for nearly a thousand
years and at one time produced very abundantly. It was for a long period worked on the
quote open cast system, like the Kimberly mines in their earlier days. But when the depth of working
became great, recourse was had to shafts and galleries. A writer thus describes the method of
softening and splitting the rock by fire, which the German miners employed in the middle of last century.
Quote, by a fixed plan, piles of faggots are arranged in the mine, and it is usually on a Saturday
that all the piles of faggots distributed during the week are kindled.
Those in the upper floors are first burned and kindled in the upper ranges at 4 o'clock in the
morning, from pile to pile. And very soon the fire unfolds its wings in the metallic vaults,
which are filled with fast volumes of smoke and flame. In course of time, the oars pass into a
shattered and divided condition, which allows them to be afterwards detached by long forks
of iron. The combustion goes on without any.
person entering the mine from Saturday evening to Monday morning when the fireman and his assistants
proceed to extinguish the remains of the bonfires. On Tuesday, all hands are employed in detaching
the oars, sorting them and taking them out, and preparing new piles of faggots against the next
Saturday, end quote. The Burra Burra Mine of South Australia was a wonder of the decade preceding the
quote, gold rush. It yielded richly from, quote, opencast workings for nearly 30 years and paid a
million sterling in dividends. It has now been worked out. Wants of space forbids more than a mere
mention of the deposits of Canada, Namakaland, Siberia, Bolivia, and the Caucasus. But before
concluding this chapter, we may glance at the copper industry of Great Britain, once responsible for
half the world's total output, but now shrunk to a meager proportions. Today, the British Isles produce
only 650 tons annually, a sad fall from the 20,000 tons in 1863. Cornwall and Wales mine most
of this scanty quodum, though a hundred years ago, the Paris mine, Anglesea, was the chief source of
copper. This is how Mr. Richard Warner describes the scene at the Paris mine in 1799.
Quote, this vast natural accumulation of mineral, which measures a mile in length and a half a mile
over, arises to the southeast of the town of Amnick, about two miles from it. Its appearance is
waste, wild, and barren in the extreme. Not a vestige of green is seen on its parched and scarified
surface, all vegetation being prevented by the sulfurous fumes which arise from the
roasting heaps and smelting houses and extend their destructive effects for miles round.
The wonders of this abyss, the open cast, are not concealed by a superficial crust of earth,
but all is open to the day. The bowels of the mountain are literally torn out, and the mighty ruin is
subjected to the eye. Standing on the edge of the excavation, the spectator beholds an awful
range of huge caverns, profound hollows, stupendous arches, gloomy passages, and a
enormous masses of rock. Amid this striking scenery, the miners are engaged in their curious but
perilous occupations, some sticking to the sides of the rock or seated on the narrow ledges
of precipices, which gap beneath them to the depth of two or 300 feet, tearing the oar from the
mountain and breaking it into smaller masses. Others boring the rock in order to blast it, whilst a third
party are literally hanging over the abyss below them, drawing up and lowering down the ore
buckets supported only by a frame of woodwork, which quivers like an aspen leaf with operation
carrying on upon it. Ever in anon, we heard loud explosions rattling through the dark profound,
occasioned by the discharge of the gunpowder and in separating the ore from the mountain.
The reports varied, increased, and multiplied amongst the passages in caverns of the abyss,
and united with the scene of rocky ruin below us, excited the idea of the final consummation of all things, end quote.
This huge deposit, once 5,000 tons of copper, were once got annually, has now been so exhausted that Anglesea yields only 27 tons a year.
and that amount is extracted from the water flowing out of the old workings one striking feature of copper mining is that though the metal is widely distributed in mined in most countries a very large part of the world's total comes from but a few mines
These, the Calumet and Hekla, the Anaconda, and the Rio Tinto, between them account for 28%.
And eight, those mentioned, plus the Boston and Montana, United Verde, Mansfield, Copper, Queen, and Tharsus for 50%.
The engineering magazine thus sums up the question of future supplies of copper.
quote, the dominating position taken by the United States among the contributors to the world's supply of copper has already been commented on.
The immense activity of the Americans added to their mechanical genius has led to the initiation by them of a scale of operations hitherto unprecedented in the history of mining.
But if the increasing demand for copper continues, present sources of supply will soon be,
insufficient, unless the production at the big mines can be still further stimulated.
It is doubtful, however, whether the productions of mines like Anaconda in the Rio Tinto
can be very largely increased.
And there is another side to the question that must not be lost sight of.
The more rapidly an ore deposit is exploited, the sooner it will be exhausted.
It is true that there are immense reserves of copper ore at Lake Superior,
assuming that the beds can be profitably worked down to a vertical depth of 6,000 to 7,000 feet.
But it seems likely that even this source of supply will fail to cope with the increased demands
of the early part of the next century.
In three or four decades, we'll probably see it exhausted.
We are bound to assume, therefore, that unless new and abundant sources for the metal are opened up in the early part of next century, the 20th,
or some substitute is found for it in the electrical industry, there is no prospect of copper being overproduced, end quote.
April 1900.
End of Chapter 14
Chapter 15 of The Romance of Mining
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The Romance of Mining by Archibald Williams
Chapter 15
Quicksilver Mining
A peculiar characteristic of Quicksilver or Mercury
distinguishing it from other metals is its extremely low melting point, which is 38 degrees below zero Fahrenheit.
At ordinary temperatures it is always liquid, and on account of the consistency of its rate of expansion when heated,
it is invaluable in thermometers, accepting in such instruments as are called upon to a register
extreme cold for which alcohol is used instead. As its melting point is low, its boiling or vaporizing
temperature is comparatively low also, to be exact, 675.1 degrees Fahrenheit.
This property, in conjunction with the readiness to combine with gold and silver, makes mercury
plays so important a part in the refining of precious metals. We have already noticed,
in our chapters on gold and silver mining, how it is spread in sluces, vats and patios,
to seize upon finely divided gold or silver and form,
and amalgam with it, out of which the more volatile metal is easily driven by the action of heat,
to be caught in cooling chambers and condensed back to liquidity.
Apart from metallurgy, quicksilver is valuable to the maker of many scientific instruments,
to the electrician, to the paint manufacturer and to the doctor,
who finds compounds of mercury most useful in the treatment of certain skin diseases
and inflammation of the joints.
Mercury has a high specific gravity. Only gold, platinum and iridium, among the better known metals, are heavier. It weighs bulk for bulk more than a third as much again as silver, and is nearly double as heavy as iron, so that an iron bar would float like a cork in a tank of mercury. Another feature is its freedom from oxidisation on exposure to the air. Mercury occurs naturally as a sulphide called Cinebar.
a red substance which is found in comparatively few parts of the world, Spain, Illyria, California,
Russia, Italy and Mexico. The best quality of Sinebar contains about 86% of mercury to 14% of
sulphur. The oldest and most famous quicksilver mine in the world is that of Almaden in the Sierra Morena,
almost at the meeting point of the provinces of Theodad Real, Badahos and Cordova.
The railway from Madrid to Cordova passes through the town, which has a population of about 10,000 people,
almost all connected directly or indirectly, with the mines.
The word Almaden is Arabic, signifying the mine of quicksilver.
Ever since the time of the Romans, who called the place Sisapona, Al-Madan has been
renowned for this metal, which is mentioned by Theophrastus, Vitruvius and Pliny.
The last writer tells us, in his natural history, that the mine was sealed with the greatest
care and was only opened to take out the quantity of cinnabar necessary for the consumption
of Rome, where it apparently served as a rouge for fashionable matrons and a pigment for painters.
The Moors did not work the mine, but after their departure it was reopened, and in the
the 17th century two Germans, Mark and Christopher Fugar, softened by the Spaniards into
Foucares, undertook to work the mine and give the government 450,000 pounds of metal yearly
in return for the mining rights. After some years of working, they professed to be unable
to pay the royalty on account of the exhaustion of the deposits, and withdrew in 1635,
though not before they had amassed sufficient riches to make their name synonymous with millionairedom.
A branch of the family took over the mine and worked it for ten years, when it passed again into the hands of the government.
Their manager, Don Juan Bustamante, established 12 furnaces, named after the 12 apostles, for reducing the ore.
But on his being unable to make the mine pay, the locality was explored for other deposits.
and this led to the discovery of the extraordinary formation that has been worked ever since.
Until the deposits of new Almaden in California came to light in 1845, the Spanish mine was without
arrival and even now holds its own. To the world's total of 3,775 metric tons in
1890, Almaden contributed 1,357 tonnes, or more than one-third.
There are three veins at Almaden, named the San Nicolas, the San Francisco, and the San Diego,
running as a rule nearly parallel to one another, though they converge and meet at intervals.
The principal vein is 25 feet in thickness, and though mined to a great depth, its richness and
to increase. The town lies over the mine which is entered by an adit or tunnel. Deep shafts
penetrate into the bowels of the earth, ladders reaching from stage to stage. The pumping out of water,
fortunately not a serious item here, was for years performed by machinery installed by Watt
in 1790, and accounted a marvel of its day. The mineral hacked out of the veins by hundreds of
semi-nude workmen is hoisted up perpendicular shafts and the metal is separated from its ore by
distillation. The mercury is then poured into iron flasks containing 76 and a half pounds each and the iron
corks are screwed down very tightly by machinery so that there may be no tampering with the contents.
Though the mine is very well organised, many of the galleries being arched over with masonry as a
protection against falls, the workers have a far from pleasant task to perform, on account of the
injurious effects of mercury on the human constitution. Work in the Almaden mine is so unhealthy
that up to the end of the 18th century, only criminals were employed as miners there.
Almaden, says Monsieur Simona, was the site of a presidio, or house of correction, and a gallery
ran from the prison to the mine. Now the workmen, now the workman, now.
numbering some 4,000 to 5,000, are all free men, attracted from all parts of Spain,
and even from Portugal, by grants of land, and immunity from certain civic duties, as the mine is a
government concern. The miners are divided into three watches, each of which works about six
hours out of the 24, the rest being from 10 o'clock at night till 4 o'clock in the morning.
The health of the men employed in extracting this most unwholesome mineral,
we quote here Captain S. E. Widrington's, Spain and the Spaniards,
varies very much, but on the whole they are very seriously affected by the exhalations
and the heat of the lower workings. This may easily be imagined when it is stated
that at the lowest part to which we descended, the Quicksilver was running down the walls
and the heat was considerable, whilst the ventilation was naturally extremely deficient.
Both Dr. Dolbony and myself sensibly felt the effect even in the short time we passed there,
and I distinctly perceived the coppery taste of the mercury on the palate.
How much more must the labourers be affected who are working hard, are heated, and almost naked?
After the winter's work, most of them are seriously altered in health and appearance.
but the effect of their native air soon restores them, and in most instances they return again.
Everything depends on care and attention to diet. Those who live freely, especially those who
indulge in wine, rapidly fall victims to the disorders generated by the pernicious mineral,
whilst those who are attentive in cleansing their persons immediately after leaving work,
and lived temperately, using a good deal of milk,
attain the usual age of man in that country.
Some instances of men of upwards of 70 were pointed out
who had worked all their lives in the mine,
and were hail and strong,
but these are rare examples.
Monsieur Simona draws a rather darker picture.
He says that few of the miners escape the effects of mercury.
They become emaciated and won,
their gums are salivated,
and their teeth fall out, causing all the digestive troubles connected with defective mastication.
They are subject to tremblings and convulsions, and finally die of consumption, or become idiotic.
Even the vegetable life of the district is affected by the mercury fumes,
and the immediate neighbourhood is as sterile as the environs of the Rio Tinto.
The new Almaden mines are situated 15 miles from San Jose in California.
The first discoverers of the Sinaba deposits were the Indians, who found that, when mixed
with Greece, Sinaba made a very effective red paint for the decoration of their persons.
In 1845, a Mexican cavalry officer, named Castellero, met a tribe of Indians, whose faces were
painted with vermilion, the pigment made from Sinabar, and offered them a reward if they
would reveal the spot from which they had obtained their paint. When shown the place, he
experimented and being satisfied that there was a rich vein of the mineral, he registered a claim
in accordance with the requirements of Mexican law, and communicated the news to a brother,
who managed to raise enough money to form a syndicate for exploiting the mine.
The first company, finding that the process of raising ore and extracting the metal, was very
expensive, gave up independent operations at the end of a year, and leased their rights to a second
company, stipulating that they should receive one-fourth of the proceeds.
Eventually, all the original shareholders were bought out by their successors, who in 1850 had already
spent £80,000 over and above their receipts.
Fortunately, in that year, an employee discovered a process of smelting the ore, which greatly
reduced the expense of extraction, an ore chamber, having two sides built of perforated
bricks is filled with cinnabar, and a fire is lighted in a compartment adjacent to one of these sides.
The flames, passing through the ore, vaporise the mercury, which is carried along with the products of
combustion through the other perforated wall into a series of condensation chambers,
the partitions between which are open alternately at the top and bottom, and is condensed into metal.
Any vapour that escapes the last condensing chamber passes over a cistern of cold water and through a spray of water.
The metal runs to the lower end of each chamber and thence through a small pipe into a trough,
extending to a large circular vat, from which it is drawn off into flasks.
The entrance to the mine is at the top of a steep hill through a tunnel ten feet wide and ten feet high,
which has been driven more than 1,000 feet through solid rock to meet the main shaft.
Along this runs a railway for cars, into which the ore is dumped,
as fast as the Tenatoros or ore carriers can bring it up in bags of hide.
This entry saves the carriers a great amount of labour,
for, until it was made, every ounce of material, including useless rock,
had to be transported an extra 150 feet,
perpendicularly to the top of the main shaft.
At the end of the tunnel is a shrine,
at which every workman pays his devotions
before descending to his round of labours.
You descend a perpendicular ladder,
formed by notches cut into a solid log,
perhaps 12 feet,
then turn and pass a narrow corner,
where a frightful gulf seems yawning to receive you,
carefully threading your way
over the very narrowest of foothold,
you turn into another passage, black as night, to descend into a flight of steps, formed in the
side of the cave, tread over some loose stones, turn round, step over arches, down into another passage
that leads into many dark and intricate windings and descendinges, or chambers, supported by but a
column of earth. Now stepping this way, then that, twisting and turning, all tending down, down,
to where, through the darkness of midnight, one can discern the faint glimmer which it seems
impossible one can ever reach. We were shown a map, giving the subterranean geography of this mine,
and truly the crossings and recrossings, the windings and intricacies of the labyrinthine
passages, could only be compared to the streets of a dense city, while nothing short of the
clue furnished Theseus by Ariadne would ensure the safe return in today of the unfortunate
pilgrim who should enter without a guide. The miners have named the different passages after
their saints, and run them off as readily as we do the streets of a city, and after exhausting
the names of all the saints in the calendar have commenced on different animals, one of which
is not inaptly called eliphante. Some idea of the extent and
of these passages may be formed when we state that sixty pounds of candles are used by the workmen in the twenty-four hours another turn brings us upon some men at work one stands upon a single plank placed high above us in an arch and he is drilling into the rock above him for the purpose of placing a charge of powder it appears very dangerous yet we are told that no lives have ever been lost and no more serious accidents have occurred than the bruised
of a hand or limb from carelessness in blasting.
How he can maintain his equilibrium is a mystery to us,
while with every thrust of the drill his strong chest heaves,
and he gives utterance to a sound,
something between a grunt and a groan,
which is supposed by them to facilitate their labour.
Some six or eight men working in one spot,
each keeping up his agonising sound,
awaken a keen sympathy.
we step aside to allow another set of labourers to pass there they come up and up from almost interminable depths each one as he passes panting puffing and wheezing like a high-pressure steamboat
as with straining nerve and quivering muscle he staggers under the load which nearly bends him double these are the tenatas carrying the ore from the mine to deposit it in the cars
and like the miners they are burdened with no superfluous clothing a shirt and trousers or the trousers without the shirt a pair of leather and sandals fastened at the ankle with a felt cap or the crown of an old hat complete their costume
the tenatero must be a strong fellow but his load weighs up to two hundred pounds and he makes forty to fifty journeys a day he has learnt the proper method of carrying a load viz by a broad
band passing round the forehead. The African natives and Tibetan tea carriers adopt the same system
of distributing the pressure over the muscles of the neck and back. For this hard labour,
he receives three dollars a day. The miner is paid by results, and the gang to which he belongs
takes care that he keeps hard at work. When the ore has reached the surface, it is spread in a yard,
where labourers sort it over and break it up, separating
refuse from the ore. The good stuff is then carefully weighed and loaded on mules,
£300 to each animal, for transport to the furnaces. In former times, the Sinebar
ore caused little injury to health, but at the depths now reached, where the ore is so rich
that beads of metal as large as a pea can be seen clinging to the sides of the workings,
the air of the Labore's, or Stokes, is so saturated with quicksilver vapour, and, and
that, in spite of good ventilation, the men suffer a great deal from metal poisoning.
This is partly due to the heat of the workings, which causes profuse perspiration, and leads
the miners to use very little clothing, so that the vapour has direct access to the skin.
The effects are aggravated by the sudden changes from heat to cold, against which little
or no precaution is taken by the ignorant Mexicans. More deadly even than hewing the or
is the drawing of refuse from the furnaces. Men employed in this business are obliged to knock off
after three weeks of work and to take a rest. Horses and mules also die from the effects of mercury
poisoning. It is remarkable that while the Mexican recovers rapidly from wounds received in the
frequent quarrels indulged in by the hot-headed natives, or from accidental injuries,
he soon succumbs to constitutional troubles such as pneumonia and consumption.
Mrs. Alec Tweedy draws attention to the Mexican miners' prejudice against the presence of women in the mines.
Should a lady visitor inspect the workings, and any mishap subsequently occur, such as the ending of a vein or a fall of rock,
it is at once laid at the door of the woman, whom must have been the devil in disguise.
managers are therefore very chary of allowing the fairer sex within their precincts,
lest their employees should take fright and keep away for a day or two
till the evil effects of the satanic visitation might be considered to have evaporated.
The estate of the new Almaden Company covers 7,800 acres.
Huge deposits no doubt still remain untouched.
In the years 1850 to 67,
This mine yielded 35,333,586 pounds of metal,
and is still prolific enough to supply all the needs of new world miners,
while leaving a good margin for export to China and Japan.
In 1902, the value of the mercury raised from New Almaden and New Idria
was about $1,500,000, and the weight $1,195.5.5.
tons. End of
Chapter 15.
Chapter 16 of The Romance of Mining.
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Read by Paul Lawley-Jones.
The Romance of Mining by Archibald Williams.
The Tin Mines of Cornwall.
Of late years, since Roles,
railway communication has been extended and expedited,
the isolated Duchy of Cornwall has become a favourite resort for holiday makers,
on account of its bold, rocky coasts, and the bright hues of the sea that washes them.
A century ago, the westernmost county of England was less visited by Englishmen than many foreign
countries, since a journey to the rough promontory projecting far into the Atlantic
involved more difficulties than a trip to Rome.
While many other more accessible portions of our coast were still unhackneyed,
unspoiled by hordes of invading trippers,
there was little to attract folk across the Tamar into the land of saints,
pastes, cromlechs, and mines.
Not that Cornwall has played an unimportant part in English history.
It was to Cornwall that the first voyages of which
which we have record, the Phoenicians, came to barter their wares for tin.
In Cornwall, the British made a long and desperate resistance to the Saxon invaders.
William the Conqueror considered the district sufficiently important to form a handsome
present to his half-brother, Robert of Mortain. And, owing to its riches and development,
Edward III created Cornwall a duchy which, since his time,
has yielded its revenues to the Prince of Wales,
or, failing a prince, to the Crown Direct.
During the Civil War, the Duchy naturally declared for the King,
and the Cornishman engaged in several fights with success.
As far back as records take us,
mining has been the great industry of Cornwall.
The earliest historical mention of our islands is made by Herodotus in connection with Cornish tin mining,
if indeed the Cossiterides to which he alludes be the islands dotting the Cornish coast,
and there seems little reason to doubt that they are.
Deodora Siculus, a Greek historian of the century preceding the Christian era,
writes more explicitly.
Quote,
The inhabitants of that extremity of Britain, called Bollerion, excel in hospitality,
and, through their intercourse with foreign traders, live in a civilised manner.
They prepare tin, working the earth which yields it with great skill.
The ground is rocky, but as earthy veins, the contents of which are brought down, melted, and purified.
After casting this into the form of cubes, they carry it to a certain island adjoining Britain
called Ictis. During the ebb of the tide, the space intervening is left dry, and they transport
large quantities of tin to this place, probably St. Michael's Mount, in their carts.
From thence, then, the merchants buy tin from the natives, and carry it into Gaul, and at last,
after travelling through Gaul on foot for about 30 days,
they bring their burdens on horseback to the mouth of the River Rhone.
End quote.
Besides tin, Cornwall has for ages yielded copper, granite, slate, lead,
iron, antimony, manganese, and china clay.
But the copper and tin mines are undoubtedly the most interesting features of the county.
These two metals are sometimes found together in the same seam, either intermingled or in strata, as it were.
Though as a rule, the loads are worked definitely for one metal only.
The chief groups of mines are as follows.
1. That of St. Ostle, mostly tin-bearing, including the famous Karkler's mine.
2. That of St. Agnes, also steniferous.
3. The Red Ruth, mostly copper-bearing, among which the Gwennap, Trasavian, Dolkhoff and United Mines are the most notable.
4. The Morazian and Helston, including the Wheel Vore, low pool and wheel-wary tin mines.
5. The St. Just and St. Ives, mostly tin-bearing. The Botallic Mine is the best known of this group.
Tin and copper are found in seams occupying faults in the granite and slate,
the general direction of the loads lying east and west.
The veins vary in breadth from the thickness of a sheet of paper to many feet,
and the ore is sometimes finely disseminated,
and sometimes occurs in bunches or large masses.
Copper is found in combination with sulphur, as a sulphurate or bisulferate.
tin, in combination with oxygen, as an oxide.
The tin seams were, at some period, largely disintegrated by the action of water,
and their upper portions were washed down and deposited in the valleys
to form the alluvial strata from which stream tin has been won in large quantities
by a process much resembling the extraction of gold from surface places.
The earliest tin mining was mostly stream work.
The Cornish miner is famous for his intelligence and resourcefulness.
In all parts of the world where deep mining is conducted,
posts of great responsibility are entrusted to the Cornishman who,
by both ancestry and training,
is fitted to undertake any mining problem which requires skill and courage.
As we have already noticed,
Cornish copper mining has fallen on evil times,
and though the tin mines still yield 5,000 tonnes of metal a year,
it is to the straits settlements that the world looks for most of its tin.
Perak now exports annually the huge total of 46,000 tonnes,
smelted from the ore of extensive streamworks.
As a consequence, Cornish miners have been obliged to emigrate in large numbers
to seek a livelihood where their presence will be welcomed
by the exploiters of virgin metal deposits, and many a Cornish village, once tuneful with the
partsongs of its inhabitants, is unpeopled and crumbles to ruin. It must not be imagined,
however, that Cornish mining is a thing of the past. Many properties are still being steadily
worked at a profit. Even were the country utterly deserted, there would remain the romance of
great feats to which allusion must here be made.
We should remember that Cornwall combust some of the deepest and most extensive mines in the British Isles,
and the early introduction of steam power to help drain the workings.
Then there are the great drainage tunnels of Dolkoth and Gwynap,
which rank high as engineering achievements.
The Gwennap added, emptying into the Canaan Valley a little above the high water mark,
was begun in 1748 by the manager of the Poldis mine
and gradually extended in all directions
until its branch is drained 50 mines in the parish of Gwynnap.
One branch alone, that running to the Cardreau mine,
is five and a half miles in length,
and the aggregate of the excavations
which drain an area of over 5,000 acres
reaches nearly 40 miles.
Think what labour must have been expended,
in driving these tunnels through solid rock
without the aid of the power drills
and other modern appliances
which the miner now has to help him.
The feat even eclipses the making of the Nent
force level, draining the Alston Moor mine's Cumberland,
though this last is three miles long
and large enough for boats to pass through.
As in the case of the great Sutro Addit,
the drainage tunnels of Cornwall
can be used for the transport of ore.
The largest open-cast tin mine of the county is that at Carclays near St. Auster.
The enormous open work of Carclays, says Professor Sedgwick,
quote, is an object of no ordinary interest.
The traveller may there see the operations of the miner carried on in the light of day,
without being compelled to descend a hundred fathoms below the surface of the earth,
and then to crawl into a dirty dripping cavern.
The ore deposit has been worked for nearly 500 years by generations of miners
who have scooped in the hills a huge bowl-shaped cavity
measuring a mile or more in circuit.
Fifty years ago, its dimensions were 1,500 feet in length,
500 feet in width,
and in places 130 feet in depth.
From this great excavation, over a million tonnes of ore have been removed,
yielding tin worth more than as many pounds sterling.
It is indeed a remarkable object when viewed in the hole,
taking in its white cliff sides of pointed abruptness,
its self-contained completeness,
its ever-widening extent,
and the suddenness with which the whole is presented in one view to the stranger,
with its men, women and children, scattered over the works.
The ground which is laid open here is almost wholly complete,
composed of soft groan, decomposed granite, through which runs a numerous assemblage of shawl and quartz loads
in the usual direction. These, as they contain tin, are the sole objects of mining adventure,
and the removal of the soft groan is effected by a stream of water, which conveys all the refuse
of the mine through the adit. I believe there is no other instance of a mine so worked,
or of a mine the working of which is attended by so little labour.
End quote.
We should add that much of the glory of carclers has now passed away.
Another famous mine is that of Batallic,
situated on the big toe of Cornwall, not far from St. Just.
Though copper forms the chief yield,
tin and iron are also brought up from its depths.
The entrance is at the edge of a cliff,
from which a shaft runs obliquely through the killus, or clay slate,
to a depth of 240 fathoms beneath the sea.
At many points, horizontal levels have been driven in pursuit of the ore.
Originally, a perpendicular shaft 180 fathoms deep was used,
but as it grew deeper, the levels had to be driven farther and farther
through barren ground to the submarine deposits.
The proprietors, therefore, decided to cut the diagonal shaft, six feet square, through the
Kylas, into the heart of the load. The expense was great, but at that time, large amounts of
ore were being brought to bank. In Little Bounds and Wheelcock, neighbours of the Botallic,
the miners had worked upward so near to the sea bottom that only a few feet of rock separate the
salt water from the galleries.
During a storm, the rolling of pebbles and thunder of the waves can be heard distinctly.
I was once in Wheelcock, says Mr. W. J. Henwood.
Quote, during a storm.
At the extremity of the level seaward, some 80 or 100 fathoms from the shore,
little could be heard of its effects, except at intervals,
when the reflux of some unusually large wave projected a pebble outward,
bounding and rolling over the rocky bottom.
But when standing beneath the base of the cliff,
and in that part of the mine where but nine feet of rock stood between us and the ocean,
the heavy roll of the large boulders,
the ceaseless grinding of the pebbles,
the fierce thunderings of the billows,
with the crackling and boiling as they rebounded,
placed a tempest in its most appalling form
too vividly before me ever to be forgotten.
More than once, doubting the protection of our working shield, we retreated in a fright,
and it was only after repeated trials that we had confidence to pursue our investigations.
End quote.
If we admire the courage of men who are content to labour within so small a distance of destruction,
what can be said of the adventurer who dared to sink a shaft from a point on the shore
which was covered at high water?
In Mounts Bay, near Penzance, were found 140 years ago, some veins of ore crossing the elven rocks.
Miners excavated the outcrop during low tide, and even sank shafts to a small depth, protecting
the tops by some method not recorded. In 1778, a miner named Thomas Curtis decided to make a bold
attempt to erect permanent works over a spot where, at spring tide, the water is 19 feet deep.
His capital being only a few pounds, he had to execute the initial work single-handed,
taking advantage of low tide to add a little more to the wooden tower, which very slowly rose
20 feet above the rocks, to which it was attached by means of stout iron stays. The joints between wood and rock
were plugged with Tard Oakham.
The building of the tower and the sinking of a pump shaft
occupied three summers.
When this part of the work was completed,
a platform was affixed to the tower's top.
Pumps were erected, and excavation for ore began.
Curtis and his fellows, he had now got help,
soon became aware that the rocks were fissured
and let in salt water,
and that during a storm the tower,
leaked. Nothing daunted, the miners plugged the roof of their level with clay, and supported it with
beams, though they found that during the winter it was impossible to work owing to the difficulty of landing the
ore in rough weather. In the summer months, they made the best of their time, and drove a large
level under the sea within a few feet of the surface, working eight hours a day. 30 sacks of tin ore were
brought out every tide, a quantity which yielded about one ton of metal. Curtis had struck a very
rich load, as indeed he deserved to do after his plucky fight with difficulties, and in course of
time he made his fortune. Or to the value of £70,000 was raised, and then, one day, ruin
overtook the mine. An American vessel anchored in the bay broke loose and collided with the wooden tower,
which was smashed in, giving the water free access to the workings.
Wheel, or Hewell Werry, as the mine was called, lay abandoned for many years.
Then, a company installed expensive machinery and essayed to carry on Curtis's work.
But what that simple miner managed to do, to make money out of his venture,
they failed to effect, and the mine soon became derelict again.
Footnote
Hewell or wheel means hole or pit.
End of footnote.
Cornwall is not without its bonanzas, or rather carboners,
as the Cornishman name large deposits of rich ore.
It is supposed that the word carboner is connected with the Aramaic word Corban, a treasury.
We know that for a long period in early tin mining history,
Jews held and worked the Cornish mines
as securities for money advanced to the then-dukes of Cornwall
and that they left behind the rude furnaces,
now known locally as Jews' houses.
We probably have in this word another relic of the Jewish occupation.
The greatest carboners of Cornwall
were found in the St. Ives' Consul's mines
at depths varying from 210 to 642 feet.
Here, huge bodies of ore were struck, and their removal has left caverns 60 to 70 feet high, and as many wide,
in their way as remarkable as the big bonanza of Comstock, or the huge copper masses of the Lake Superior District.
Other unusually rich loads put in an appearance at Wheel Vore near Helston.
At one time, the load seemed to have given out, as all effort to try to.
trace it failed. One old miner thought, however, that the cuts were being driven in the wrong
direction, and asked to be allowed to explore on his own account. His judgment was correct,
and soon he had broached a vein 100 feet broad in places, which yielded so much ore that special
plant had to be installed for its reduction. History does not say whether old beagle hole,
that was the miner's name, got due credit.
for his persistence. He certainly deserved well at the hands of the company which he thus saved
from insolvency. Another example of the reward of perseverance can be given in connection with
the old Crinnis mine near St Auster. In 1808, this mine was considered to be worked out,
but a party of adventurers, as mining exploiters are called in Cornwall, took it over for better or worse.
When they got no return for their money, all the adventurers except one, a Mr. Rowe,
retired from the venture.
Rowe stuck to his colours and tried for awe in another part of the set, or property,
with the result that at a depth of 60 feet he came upon an extremely rich vein,
which, in 41 years, left him with 168,000 pounds in his pocket.
On learning of his prosperity, the other partners at once claimed a share in the spoil,
and when Mr. Rowe refused to let them participate in the good fortune which was entirely due to his private expenditure and enterprise,
they went to law with him.
It is satisfactory to learn that the verdict was given against them.
We could give a long list of similar turns of fortune's wheel,
which revolves pretty freely in all mining districts.
But, as space forbids, we must pass at once to a short consideration of the working of the mines and treatment of the ore.
Generally speaking, the Cornish seams are explored by the system of shafts, drives, cross-cuts, and winses,
which has already been described in our chapter on the Rand mines.
A typical mine is that of Dulcuth, where the shafts sink to a depth of two and a half thousand feet,
and galleries run east and west for half a mile or more,
the total of the shafts, galleries, etc., aggregating nearly 30 miles.
Half of the excavations have been driven through granite.
Dolkuth history records some curious changes.
Until a depth of 130 fathoms had been reached,
the veins were rich in copper.
The next 30 fathoms proved so poor that it looked as if the mine was exhausted.
Then tin appeared, and the load became increasingly rich in tin to the 420 fathom level,
giving the property a fresh lease of financial life.
Cornishman employ the underhand method of stoping.
A gallery is driven above and below the block of ore to be removed,
and a perpendicular winds is cut to join the two.
The miners then begin hacking at the angles made by the top of the winds and the upper
gallery, and remove the ore on both sides in a series of steps, sufficiently steep to allow the
material to roll by gravity through the winds into the lower gallery, where it is caught in trucks
to be transported to the shaft. Meanwhile, the other windses have been made parallel to the first,
and other gangs of workmen hew out the intervening stoops, which may be compared to the panes
of a window, the horizontal bars of which would represent the galleries, and the upright bars,
the winds is. Eventually, a great cavity is left where once the ore was, and it becomes necessary
to keep the sides from caving in by stout timbers, and also to leave floors at intervals to catch
any falling masses. The labour of descending, and still more of ascending, the footway of a two thousand-foot
mine is very exhausting to the miners. Imagine that you have to climb hand over hand up a series of
ladders, fixed one above the other, to a height five times that of St Paul's Cathedral,
and that perhaps this has to be done twice a day, to say nothing of the descent. Then perhaps
you will be able to understand why the man-engine now generally used in Cornish mines is so welcome to the
laborers. The first man-engine was made in Germany, at one of the Haas Mountain mines, in 1833,
as the result of an accident on the ladders then used. It happened that the drainage of this
particular mine had just been completed by means of an adit, which threw the pumps out of work.
An ingenious miner saw a new use for the idle tackle. Why not attach steps to one pump rod at intervals,
and corresponding steps at equal intervals on the sides of the other rod with proper handholds.
Then, by stepping from the one to the other at the end of a stroke,
a minor would be transported up or down the distance of the next stroke,
and, by a succession of changes, finally reached the top or bottom as the case might be.
An experimental apparatus, 600 feet high, was rigged up,
and it proved so successful,
that man-engines were soon in use in many Haas mines.
Nine years later, the idea was imported into England.
At the instigation of the Royal Polytechnic Society of Cornwall,
the proprietors of the Trisavian mine installed a man-engine.
Soon afterwards, 391 of the Trisavian miners
put their signatures to a letter thanking the society
for the new apparatus which spared them so much toil and weariness.
Other mines followed suit, and now the man-engine is a recognised item of Cornish mine equipment.
The single-rod engine is most commonly used, as being safer, even if slower, than the double.
In this case, one set of stages is attached to the sides of the shaft.
The stroke is 12 feet, and on a single rod, the miner can ascend 1,800 feet in half an hour.
as against one hour consumed in climbing ladders.
The cost of working has been reckoned at three half pence per man per day,
and the value of time saved at from sixpence to ninepence per man.
So that humanness has brought its own reward.
The ordinary cage and rope transport used in the coal mines
does not appeal to the Cornishman who sticks to his engine.
The men are so skillful in stepping off and on the,
the moving platforms that fewer accidents are due to the engines than to the ladders formerly used.
Good Cornish ore yields about 6% of the black oxide of tin, which itself contains 78.6% of metal.
When the ore has been brought to grass, i.e. to the surface, it is sorted out, ground to powder
in stamp mills, and well washed to remove earthy matter.
The washed ore is then roasted in an inclined iron cylinder revolving over a fire,
being poured in at the top.
On its way through the cylinder, it gives up any sulphur and arsenic that it may contain,
as gas.
The purified black tin is smelted in reverberatory furnaces,
and polled, or stirred, to cause the oxygen to combine with a proportion of anthracite coal that has been added
to form carbonic acid gas, which passes off with the furnace draft.
The slag, having been skimmed off, the tin is ladled into moulds.
The chief uses for tin are
1. To mix with lead and copper to form alloys for coining, soldering and other purposes.
2. The manufacture of tin foil.
The metal is so malleable that it can be easily beaten out into shodering,
sheets one one thousandth of an inch thick, which are used for the wrappings of certain kinds of
sweets.
3. The tinning of sheet iron to protect it against oxidisation.
We have already remarked that the tin production of Cornwall is diminishing, on account of
the increasing expense of raising the ore and the discovery of rich deposits in other countries.
The Malay Peninsula now heads the list of tin-producing district.
The Dutch possessions of Banca and Billerton yield about 14,000 tonnes yearly.
Australasia, 5,000.
Bolivia and Cornwall, each 5,000.
It is curious that the United States, rich as they are in almost every conceivable mineral,
appear to be absolutely barren of tin, a fact which has helped to keep up the price of the metal.
The following table, borrowed from Mr. Robert Hunt's standard work, British mining,
is a computation of the amounts of tin raised in Cornwall since mining began there.
In the 500 years before Christ, 50,000 tonnes.
In the 500 years of Roman occupation, 50,000 tonnes.
To 1066 AD, 100,000 tonnes.
To 1,300 AD, 369,800 tonnes.
To 1,500 AD, 42,048 tonnes.
To 1600 AD, 680,100 tonnes.
To 1636 AD, 30,000 tonnes.
To 1740 AD, 235,000 tonnes, to 1834 AD, to 1834, AD, to 1834 A.
202,000 tonnes, to 1860 AD 162,000 tons, to 1880 AD, 1880 AD, 195,223 tons.
Total, 2,116,171171 tons.
Assuming an average price per tonne of £70, we are left with a total value of over
140 million pounds sterling.
A very fine contribution from Little Cornwall to the wealth of the world.
End of Chapter 16.
Chapter 17 of The Romance of Mining.
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The Romance of Mining by Artable Williams.
coal and coal mining.
The importance of coal, its origin, its formation, the distribution of coal, some figures, the coal fields of South Wales, of the Midlands, of the northern counties, of Scotland.
Statistics. French and Belgian deposits. German coal fields. French perseverance.
The coal fields of the United States. Some interesting stories about their discovery.
popular prejudice against anthracite coal efforts to overcome it the poker trouble growth of the coal industry in the states the connellsville coke fields indian scenes
having considered the mining of the most important of the precious metals and minerals we will turn our attention to the subject of coal mining this subject is indeed so vast that within the compass of a few pages it cannot be more than outlined and the author of this book
has been tempted to leave black diamonds out of the list of minerals to be treated,
simply on account of the difficulty experienced in picking and choosing among the many things
that may and should be said in connection with the world's greatest mineral industry.
Yet, from a volume which deals with a more romantic side of mining,
we can automate reference to this great topic.
The mere mention of the word call starts many trains of thought.
The origin itself of coal is so interesting, we might say, uniquely interesting.
The natural occurrence of coal is so widespread.
The amount's mind are so colossal.
The risks and labor required to raise these masses are so great.
The uses of coal are so manifold.
Yes, coal forms the basis upon which the pyramid of mineralogical and most other human industries
and hence human health, wealth and happiness ultimately rest.
Coal moves thousands of mighty vessels through the seas and oceans.
Coal sends a hundred thousand locomotives spinning over the ironways of the world.
Coal smells the millions of tons of iron ore from which we fashion all our machinery and the countless appurtenances of modern civilization.
Coal makes busy factories hum in towns unnumbered, lights our streets and houses,
warms us with its stored sunbeams.
We need not extend the list.
Let us rather boldly say that hardly a manufactured object meets our eye,
hardly a luxury appeals to our senses,
that is not due at least indirectly to King Cole.
If we are to avoid confusion,
we must attack our subject as methodically as the miner attacks the mineral itself,
and therefore we will commence at the proper point.
The Origin of Coal
all of us had read at one time or another accounts of the manner in which coal came into being
and what are its constituents.
We may therefore dismiss this part of the subject as briefly as possible.
Coal is carbon plus hydrogen plus oxygen plus sulphur plus other impurities.
At periods far back in the dim past, these constituents took upon themselves the form of gigantic ferns
trees and mosses, which flourished exceedingly in the tropical heat and humid atmosphere of their time.
Basterias of the earth's surface were covered by these dense groves,
which in many places were gradually submerged by subsidences of the earth's crust.
Water sold them fresh flowing in, very slowly covered them up with deposits of sun and mud,
which, in course of time, under the influence of pressure, were converted into sandstone and shale.
Myrials of tiny shellfish died in the lagoons overlying the vegetables and the mud strata and contributed a stratum of limestone.
As soon as the surface of these successive strata had reached the water level, vegetable life commenced again,
and the operations of nature's laboratory passed through another cycle.
Vegetation, sand, mud, limestone were superimposed again and again in great blankets ranging in thickness from a few inches to hundreds.
of heat. Then came upheaval's distortions and crackings, as the earth's crust cooled,
and the level strata were bent and twisted into vast hills and valleys. The summits of the hills
were washed off by the seeteless action of water and carried into the adjacent depressions,
leaving the upturned edges of the strata open to the day. The amount of the upheaval varied
greatly in different localities. Hence, we find the cold deposits of some countries,
remarkably level and in others almost as much tilted as silver gold or copper veins.
On account of the nature of its formation, cold is found in beds of comparatively uniform thickness
and of great continuity. Where falls are absent, the miner, after one striking a seam,
may be able to work steady the head for many miles through the solid mineral.
Coal mining, therefore, resembles rather the mining of slate, marble, stone and
other geological deposits, than the raising and working over of large masses of silver, copper or lead,
from which only a small percentage of useful material is obtained.
The coal measures, as distrait are called, which include layers of coal,
are upwards of 11,000 feet, or about two miles thick in places.
Sometimes the coal layers are separated by very deep blankets of other matter.
Sometimes they occur in close proximity with but the thinnest film of fireclay between them.
The fire clay, be noted, is the soil in which the plant's sins converted into coal grew,
as it proved by the existence in seams of fossil trees with the roots ramifying through the clay.
Deformation of coal
Wood, we have already said, contains carbon, oxygen and hydrogen.
During the period when the forests and mosses were rotting,
they gave off oxygen and carbon in a combination known as carbonic acid gas,
and the moses gradually changed into a substance called lignite,
which, according to the pressure to which it has been subjected,
and the length of time that the composition has gone on,
ranges in color from a dark brown to a dead black.
Under the influence of heat and still greater pressure,
the hydrogen also passed off with some more of the carbon,
as carbureated hydrogen,
and bituminous or true coal was formed.
More pressure drove out of the gases still further,
and the anthracite coal resulted, almost pure carbon.
The next stage produced graphite,
a substance of immense antiquity,
and then came the last stage of all,
one in which of foreign elements were driven off,
and the heat caused crystallization,
and loved the diamond.
You will now understand the appropriateness of the term,
black diamonds as applied to coal. It is possible by the bite to change wood into coal and coal
into diamonds artificially, though at so great an expense that the De Beers company need not
fear the rivalry of the chemist. The time occupied by these changes cannot be reckoned in the
case of diamonds and graphite, but for antarcite and bituminous coal, calculations have been made
which may be assumed to be approximately correct. Mr. McLaren, an expert,
reasons that the vegetable matter from which cold is formed was deposited at the rate of one yard in depth every thousand years.
In the South Wales coal fields, there is a combined thickness of coal totaling 40 yards,
overlaid by 12,000 feet of sedimentary matter which was deposited at the average rate of two feet per century,
so that apparently this coal field was 640,000 years in the making.
The process of coal formation is still going on in our peat bogs, in the great swamps at the
estuary of the Mississippi and in the tropical laguins of the African coast.
Modern research points to the fact that the transformation of baup moss into peat is largely
due to the action of certain bacilli and fungi, and even in cold the microscope has detected
what may be called fossil bacteria.
Whether present vegetation and present natural conditions are such as would ultimately
result in true coal is a question which it is impossible to answer. Mr. Edward Hall in the
coal fields of Great Britain says, the physical conditions of the cold period stand alone, and we cannot
but conclude that they were ordained beforehand for a great and evident purpose. As for the vegetation,
we know that the plants which form the bulk of our coal grew to a size vastly suppressing
that of their modern descendants, and very possibly the circumstances, the circumstances. The circumstances, the
circumstances which promoted their growth also fitted them especially for the change which they
afterwards underwent. From scientific suppositions we will turn to the hard facts of the distribution
of coal. It is not of course possible to state the exact extent of the world's coal fields,
since vast areas of Asia, Africa, Australia and South America have not yet been prospected.
But geologists have calculated that the coal measures underlie at least
half a million square miles of the earth suffers. China and Japan claim between them 200,000
square miles, the United States, 200,000, India 35,000, Russia 27,000, Great Britain 9,000,
Germany, 3,600, France, 1100, Belgium, Spain and other countries, about 25,000.
Of late years, it has become evident that Rhodesia overlies a huge deposit
which extends indefinitely northwards and in the future may be found to rival those of North America and China.
As to the quantity which the known coal fields may be expected to yield,
this has been reckoned at the enormous total of 600 billion tons,
enough to last for 1,000 years at the present rate of consumption.
From the deposits of Great Britain, over 10 billion tons have been raised since the year 6,000.
1800 daily. During last century, the annual output of Great Britain rose from 24 million tons in 1830 to 240 million tons in 1900,
which, allowing for the growth of population during the same period, means an increase from one ton per inhabitant to six tons.
Even more startling is the augmentation of the United States supply, which, from two and a half million,
tons in 1940 has reason to 320 million tons in 1903.
To give some idea of the magnitude of the industry on the other side of the Atlantic,
we may mention that coal forms one-third of the total freights moved over the United States
railways. Germany takes third place among coal mining nations with 150 million tons annually,
France fourth place with 34 million tons, and Belgium, fifth.
with 23 million.
There are 20 principal co-fields in Great Britain.
Let us glance at some of these.
First in importance is that of South Wales,
extending from Pontipool in Monmouthshire on the east
to Kidwell in Pembrokeshire on the west.
It forms an elliptically shaped pacing,
about 50 miles long from east to west,
by 18 miles broad from north to south.
Covers an area of about 1,000 square miles
and has an extreme depth of 11,000 feet.
The value of the deposit is greater enhanced by the fact that nearly half of it is anthracite,
which contains 94.10% of carbon,
and which, while burning with a fierce heat, combines so perfectly with oxygen
that the products of combustion are practically invisible.
Consequently, Welsh steam coal is of the utmost importance to all war vessels,
and large quantities are exported annually to feed the furnaces of the French, German, Russian, Japanese and other navies.
The great coal ports of South Wales are Cardiff, Swansea and Newport, from which vast quantities are shipped every month.
The minable coal of the field, i.e. that lying within 4,000 feet of the surface, has been calculated at 16,000 million tonnes.
Merthetitville may be considered the centre of the South Wales coal and iron-melting industries.
Passing north over the small forests of Dean Coalfield, which has an extent of 34 square miles,
we entered the central coal fields, belted over an area measuring 100 miles each way.
This bunch includes the Shrewsbury, North and South Staffordshire, Leicestershire, Warwickshire, North Wales, Lancashire, Yorkshire and Derbyshire, the Bucshire
separates by wide coal-less districts.
The South Staffordshire Field is notable for containing the thickest single seam in England,
the 10-yard seam, as it is called, and broken by any intermediate layers of eye clay.
The Warwickshire or Tamworth colliers give us a large part of our house and steam coal.
The North Staffordshire bed, known as the Pottery Coalfield, has seams totally 97 feet.
97 feet in thickness, and this important has been adjacent to valuable beds of iron ore.
In Yorkshire and Derbyshire, the deposits run north and south for 60 miles and from 10 to 30 miles
east and west. From here is derived to the silk stone, a famous house coal and basley
steam coal. Lancashire contains a bed measuring 52 by 19 miles, with a greatest thickness of workable
coal of 100 feet, giving a total bulk of over 16,000 million pounds.
Durham and Northumberland contain fields measuring 65 miles north and south by 22 miles east and west,
its greatest breaths, been near the centre, along the course of the thine, which is the
great highway for exporting coal to the London market.
The central district that join in Newcastle and Sunderland produces the best class of
Housecall, known in London as Walsand, from the pits on the Tyne where it was originally mined,
which were close to the eastern termination of the wall built by the Romans to protect the country
between the Tyne and the Soulway from the incursions of the pits. These galleries have been long
since abandoned, but the name is still given in the London market to the best Durham House Call,
and even too much that has been produced in other places, as indicating a call of superlative
excellence. The great merit of Wilson coal is in a small proportion of ash, which also, being
dark-coloured, is not so obtrusive on the hearth as the white ash generally characteristic
of the midland coals. This strongly caking property and the large amount of gas given out in burning
tend to produce a bright and enduring fire. In the district north of the thine, the produce
is principal steam coal, which is known as Hartley Coal, been named after one of the principal
collieries. The area of this field is 460 square miles, and the estimated quantity of minable coal
is about 7,000 million tonnes. Passing over the border, we come to the great Scotch-cold belt,
stretching from coast to coast in three main beds, covering the counties of 5-shear, Midlothian,
Sterlingshire, Lanachshire and A-shear.
It is bounded on the north by the Grampian hills, on the south by an elevated district, of which the Lammermur, Moffut and lead hills form apart.
The coal measures are all exposed here and therefore can be worked comparatively easily.
Together they underlie an area of 1,720 square miles, and, if mined to a depth of 4,000 feet, would yield the enormous total of 25,000 million pounds.
Statistics for 1890 give the following as the yields of the coal fields mentioned.
In millions of tons, South Wales 28, South Staffordshire 9, North Staffordshire, Shropshire and Cheshire,
6, Midland Counties 27, Lancashire, North Wales, 25, Yorkshire, Durham and Northumberland,
70, Scotland, 30.
total
195 million tons
the balance needed to make up the years total of 220 million tons
came from Kent Island
Camberland Somerset and Wiltshire
French and Belgian cold fields
A carboniferous belt stretches westwards
from Ella Chappelle along the valley of the Sambre
to Namur where it is interrupted
to reappear to the west of Mons
and again at Boulon
The same belt passes under the Channel, under Kent and Sussex, and comes to the surface in Somersetshire.
Other French deposits are found in the pacing of the Saon and Rual, near Chalon and Dutton, near Nima, and in the Alpine provinces, the last being Antar site.
German cold fields.
The chief of these cover three districts, one in Westphalia, two in Greenish-Balaya, three, three,
in Silesia.
The second group is the most important of Western Europe.
Its thickness, 20,682 feet, exceeds that of any other known coal field.
Speaking of it, Monsieur Simonin says,
When the Allies revised the Frontiers of France in 1815,
they endeavored to define them in such a manner on the side of Rhenish of Prussia
that all the rich coal-basing of Zarbrook,
which had been worked for 20 years, should lie off.
outside the new boundary.
It seemed to the Prussian engineer of mines, who in part the diplomatist with the bright idea of adopting such a boundary, that the strata, if they did not and politely, turned their back upon France, were nevertheless situated at such a depth beneath the surface that no more coal could be expected to be got on the French side.
The enemy had not reckoned on the bold initiative taken by the inhabitants of de Moselle.
The successful attempt made in the Department of the North had a tract.
the attention of these intelligent people and were remembered by them.
They set resolutely to work at once in the environs of warby.
The ground was bored, pits were sunk, and, in spite of the length of time,
and the patience which are always necessarily required in the prosecution of such undertakings,
nothing discouraged the explorers.
Capital one spent was followed by the subscription of fresh funds,
and if boreholes and pits afforded no results, others were made.
It was also necessary to contend against the water,
which filled the borings, causing falls in them, or rising in artesian dreads.
In short, after many years of continuous efforts, the moment of triumph arrived,
and man rested victorious in this contest with the ground.
At the opening of the chambers in 1958, the Emperor Napoleon III announced the discovery of the
Moselleco basing, an extension of the vast and productive basing of Zarbig.
It is sad to have to add that, with the annexation of Alsace,
Loren by the Germans in 1971, the ownership of the new coalfield passed into German hands.
The coal fields of the United States.
These also form three great groups.
One, the Allegheny or Appalachian, lying on into the northwest of the Allegheny Mountains,
and including the states of Pennsylvania, Virginia, West Virginia, Maryland, Ohio, Kentucky, Tennessee, Georgia and Alabama.
This field covers about six.
60,000 square miles, an area greater than that of England than Wales.
2. The Illinois and Missouri field of equal size.
Besides trenching on the states already mentioned, these deposits invade Indiana, Iowa, Kentucky, Kansas and Arkansas.
3. The Michigan field, a deposit of almost circular form lying in a gigantic limestone bowl,
the rim of weight shows all round the outcrop of the coal measures.
We must add to these groups isolated fields in Colorado, Dakota, Montana, Indian Territory, New Mexico, Washington, Oregon, and California.
In short, 29 states are coal-bearing.
Only 460 square miles out of the 200,000, yield anthracite, which is confined to Rhode Island and three fields in Pennsylvania,
situated between the Susquehanna and Lehigh rivers.
They are called the northern or Wyoming, the middle and the Shuiquil or southern coal field.
From the Pennsylvania district, 365 tons were mined in 1920.
This quantity had increased to 50 million tons by the end of the century.
The anthracite beds have been subjected to much greater pressure and more violent upheavals than the bituminous
deposits. Some veins lie nearly flat, but others approach the vertical, especially at the edges of a
formation. In Rhode Island, the anthracite has been so squeezed as to form a graphite in places,
and so contorted and broken that it cannot be mined profitably. Anthracite, cold in the states,
is brought up through shafts, now that the surface deposits have been worked out.
The bituminous coal, on the other hand, is got out almost entirely through tunnels driven
into the veins at or near the outcrop, since the beds almost without exception lie horizontally
and near the surface, so that any depression which has been scooped out by the action of water
serves as a convenient point from which to make an entry.
In connection with the discovery of antarcide cold deposits, some interesting stories are told,
which will remind us of the gold fields.
Before 1790, it had been suspected that coal beds existed along the Lehigh River,
but they remained unknown until 1791,
when a hunter named Philip Ginther stumbled upon an outcrop quite accidentally.
This is his story as related in Mr. Homer Green's valuable little book,
Coal and the Coal Mines.
He said that at one time the supply of food in his cabin,
chanced to run out, and he started into the woods with his gun in quest of something which
should satisfy the hunger of those who were at home. It was a most unsuccessful hunting expedition.
The morning passed, the afternoon went by, night approached, but his game bag was still empty.
He was tired, hungry and sadly disappointed. A drizzling rain set in as he started homeward
again across the Mochunk Mountain. Darkness was rapidly coming on, and
despondency filled his mind, as he thought of the expected faces of little ones at home,
to whom he was returning empty-handed.
Making his way slowly through the thick, wet undergrowth, and still looking about him,
if pertains something in the way of game might yet come within the range of his gun,
his foot happened to strike a hard substance which rolled the way before him.
He looked down at it, and then bent over and picked it up, and so by the deepening twilight,
that it was black. He was familiar with the traditions of the country concerning the existence
of stone called in this region, and he began to wonder if this indeed was not a specimen of it.
He carried the black lamp home with him that night, and the next day he set out with it to find
Colonel Jacob Wise at Port Allen, to whom he exhibited what he had found.
Colonel Wise became deeply interested in the batter, and brought the specimen to Philadelphia,
where he submitted it to the inspection of John Nicholson, Michael Hillegas and Charles' cyst.
These men, after assuring themselves that it was really anthracite coal,
authorized Cornel Wise to make such a contract with Kinter,
as Wood induced him to point out the exact spot where the mineral was found.
It happened that the hunter covered a vacant piece of land in the vicinity,
containing a fine water power on mill site,
and on Colonel Wise agreeing to obtain a paper.
for him from the state for the desired lot of land,
he very readily gave all the information in his possession
concerning the stone call.
Another district of the Shilku Field was also discovered by a hunter
in a rather similar way at about the same time.
Nicholas Allen had been hunting all day and thus night came on,
built a wood fire to keep him warm while he slept.
He was awakened from his lumbers by feeling unpleasantly hot
and there, close by, was the ground with south.
on fire. That scared him away, but next morning he returned to investigate and found that he
had actually lit his sticks on the outcrop of an anthracite deposit. This was not the last
hunters find four in 1826 when John Charts, while digging a ground hook from its borough,
uncovered the ledge of coal which afterwards formed the rich property of the Hayes-Don Coe Company.
It is interesting to note, before we conclude the list of happy accidents,
that the first co-found in the States, in 1760 in Virginia,
was stumbled upon by a boy while seeking bait for his fishing operations.
The reason why sportsmen should have been so successful as unintentional prospectors
is easily understood when we remember that in those early days,
almost every country dweller was before a huntsman, trapper and fisherman,
if he wished to keep his larger well-supplied.
The Americans were at this time acquainted with the use of bituminous call,
which had been mined in Great Britain long before the pilgrim fathers set sail for the new world.
But anthracite came as a new thing when discovered.
It was unusually hard and refused to burn in an open grate.
True, blacksmiths used it for their forces were a forced draft promoted combustion.
but in ordinary household fireplaces and smelting furnaces, it appeared to be worthless.
People simply refused to buy it, though they would gladly have substituted a fuel for the wood,
which was generally burnt outside the bituminous coal district.
Of course, the owners of new anthracite coal fields were grieved at this
and determined to try to convert popular opinion to the true facts,
namely that anthracite will burn in an open fire if treated in the proper way.
In 1903, six barges of coal were sent down the Lehigh River to Philadelphia from Muchunk.
Four were overturned on the way, and the contents of the two which reached their destination safely could not be sold.
The public authorities were asked to give it a trial and did so in a steam engine.
It refused to ignite, so they spread the rest of it about the public footpaths instead of gravel.
The exporters lost heart and closed down their mines.
Ten years later, however, they took courage again and dispatched another barge,
sending in advance handbills which set forth the correct methods of burning anthracite in stoves, grays and furnaces.
Stoves were erected in prominent places to give the Philadelphians' ocular demonstrators.
of the mineral's value. Fires were lit gratis in citizens' houses. Blacksmiths had
gratis fuel for the forges. At last, the public began to take interest in the exhibitions,
though they would persist in poking their fires, according to an instinct which seems to move
anyone who comes face to face with burning coal.
We will draw upon Mr. Homer Green for another anecdote.
Among the purchases of Lehigh Coles in 1814 was the firm of White and Hazard manufacturers of iron wire at the falls of the Shulkin.
They had been told by Mr. Joshua Malin, proprietor of a Roland meal, that he had succeeded in using the new fuel,
and thus the Virginia coal was very scarce at the time, White and Hazard decided to test the qualities of the anthracite.
They purchased a cartload of it, paying a dollar a bushel for it, and took it to their works.
Here they tried to build a fire with it in their furnace, giving it what they considered the most skillful manipulation, the most assiduous attention.
Their efforts were in vain.
The entire catload was wasted in a fatal attempt to make the coals burn.
Nothing daunted, they obtained another catload and determined to spend the night, if need should be, in the work of building a coal fire.
And they did spend the night.
But when morning came, they were apparently as far from the air.
attainment of their object as ever.
They had poked and punched
and raped. They had labored
incessantly. But notwithstanding
the most constant manipulation,
the calls above the burning wood would
not sufficiently ignite.
By this time the men
were disargent and disgusted,
and slamming the door of the furnace, they left
the mill in despair and went to breakfast.
It happened that
one of them had left his jacket in the furnace
room, and returning for it
about half an hour later, he discovered
that the furnace door was red-hot.
In great surprise, he flung the door open
and found the interior glowing with intense white heat.
The other hands were immediately summoned,
and four separate parts of iron
were heated and rolled by the same fire
before it required renewing.
Seeking for the cause of this unexpected result,
the man came to the conclusion
that it was due to simply letting the fire alone,
a theory the correctness of which
they afterwards abundantly proved.
thus by chance
these men hid upon the secret of success
in the matter of burning a fire of anthracite calls.
That secret is simply to throw the calls loosely
on the burning wood and then let them alone.
For the time, success seemed assured,
but unfortunately for anthracite coal owners,
the Declaration of Peace with Great Britain in 1815
opened the way for the importation of foreign soft calls
which ousted the homegrown article
and the mines closed down again.
The year 1820 saw the tide turn. Property went up in value by lips and bounds. Owners
lease their lands to companies who paid them a royalty on every ton mined from the strait below,
while not interfering with the agricultural operations on the surface. Royalties of 25 to 35 cents per ton are now quite common.
Of late years, railway and canal companies have bought up huge tracts of anthracite country.
at sums ranging to 10 million pounds sterling.
Owing to the economy is possible when mining can be done on a large scale,
with big capital behind it, the price of coal has diminished,
and properties which, if owned by individuals,
would during times of depression and labour troubles,
be unable to weather the storm,
can, when amalgamated into powerful corporations,
hold out through long periods of adversity.
The Pennsylvania coal fields have been used,
been the scene of some of the most serious strikes in the world's industrial history,
and of deeds which we are glad to be able to include among things that have now gone by.
This sketch of the anthracite coal fields of Pennsylvania, says Mr. John Birkenbein,
could be made to embrace the story of fortunes won and of fortunes lost,
of terrible disasters by gas explosion, by fire, or by crashing of supports,
relieved by deeds of heroism on the part of those who sought to rescue the indigenous.
or to recover the dead. It could include the sanguinary history of the Mollimagires when
murder was done by order and of later strikes and riots by which property and life were sacrificed.
Before leaving the American coal fields, notice should be taken off the Connellsville-Coke region
in southwestern Pennsylvania. The noun does not imply that coke is their dug out of the ground,
merely that here is a deposit of coal particularly fitted for reduction to coke,
which is needed in huge quantities to heat the many blast furnaces of Pittsburgh, the steel
centre of the world. The seam, nine feet thick, has an extent of about 62,000 acres.
It is very easily mined and yields over 12 million pounds of coal annually.
This is transferred to 23,000 coking ovens, which drive off the bullet off.
constituents and leave the shining residue so prized by Pittsburgh Iron Masters on account of its
wonderful consistency. It is said that for the Conersville Coke, the United States would not
hold the proud position of first among still-making nations. The Coal Fields of India
Asam is the province most richly gifted with coal, though, owing to its inaccessibility,
it has not as yet been extensively mined.
The cold is very pure
and is easily worked by tunnels driven into it through the hillsides.
In one area, measuring only five miles by one-third of a mile,
there is said to lie more than 140 million tons of the mineral.
The gold is dotted over with collieries,
which stop the past deposits that in time to come
will be of great value to the industrial expansion of eastern India,
if only sufficient workers can be found.
Most of the natives consider mining an occupation unworthy of their caste,
or are too lazy to put their hands to work so strenuous.
This is particularly unfortunate, since the coal seams are very easily mined,
thanks to their broad outcrops, their freedom from dangerous gas and a good roof,
though the coal itself is inferior to that of a sum.
When mechanical coal cutters have been generally introduced,
the owners would be less at the mercy of their workpeople,
who, under least provocation, indulge in a holiday lasting several days,
if they have made sufficient money to meet their simple wants during that period.
Other fields exist in Madras, the Punjab, Burma, the Central provinces,
and over the border in Belucistan.
End of Chapter 17, read by Claudia Caldi.
Romance of Mining
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The Romance of Mining by Archibald Williams.
Work in the coal mines.
Few sites are more dreary and depressing than a coal mining region.
The naturally fair face of the earth is scarred by unsightly rubbish heaps of the
enormous extent, dominated by hideous chimney stacks, gaunt buildings, and twirling wheels.
The earth is blackened. The roads are covered thickly with black mud or black dust.
Almost everyone we meet has a black face as well as a blackened dress.
We think of the black depths down below. Of the long black list of terrible accidents that occur
so frequently in coal mining annals. Of the black records of oppression and slavery that once
disgrace to the management of these deep pits, and we are tempted to conclude that apparently
there is not a single redeeming feature about a colliery. But stay, even the darkest picture has its
light lines, and if we pry more closely into the lives of our coal miners and into the methods
by which the mineral is one, we shall find that things are by no means as gloomy as our first
impressions may lead us to consider them to be. These miners who pass by us have a free carriage.
Some whistle, others are chaffing and laughing, though they have just returned from their shift below
ground. The labor evidently hasn't knocked the heart out of them. Their toil is severe,
but they are well paid, and the hours of work are short. When they feel so disposed, they take a
holiday. Money is plentiful enough for that, and even to allow them to keep bulldogs and a piano,
on which instrument some of them are no mean performers. Of course, there come times now and then
when cash is short, a thing which happens in all trades and professions. Then those engine houses,
slab and hideous enough outside, but peep inside and there loom before you magnificent
machines performing prodigies of work. Pluck up your courage and peep, peeperoying,
peer down the shaft.
Ugh!
A horror of darkness.
Yet far beyond where the light of day penetrates,
there is a busy town with streets of coal,
houses of coal, stables of coal,
railways laid on coal,
more marvelous machinery,
an army of grimy men,
each intent on his allotted task,
under the guidance of generals,
colonels, and captains.
There is danger down there, tis true.
but the men wreck little of that perhaps too little it never robs them of a night's sleep there are animals down there which were born there will live there and will first see daylight when they are past their work if indeed they come up alive
they don't miss the daylight however they have never known what it is however we feel glad that the lot of the brave folk brave without knowing it who toil below is a happier wise toil below is a happier wife
than it was prior to the investigations of the coal mine commission in 1842.
All honor to Lord Ashley, afterwards the Earl of Shaftesbury,
for his bold championship of the coal miners.
The abuses that the commission found in existence were appalling,
such as to help us to understand why in these latter days
the successors of the hapless sufferers that dragged out a miserable existence in the mines,
sometimes take an unreasonable advantage of the power.
of combination. Quote, they, the commission, found women toiling underground like beasts of burden,
surrounded by a loathsome atmosphere of physical suffering and degradation and moral pollution,
to which savage life scarcely affords a parallel, and children of five and six, and even of
four years of age, stunted, diseased, and half-starved, compelled to crawl on all fours in the
low and narrow passages of the coal pits, dragon,
by a chain passing from the waist between the legs small carts laden with coal.
In many mines, especially in the Midland counties, the mines were damp and streaming with water.
No attention was paid there to efficient ventilation or to drainage.
End of quote, from the age we live in.
So the poor women and children were soaked through and half stifled by want of air.
It was a common sight to see weak youngsters toiling,
with trucks through passages only 22 inches high, doubling their bodies into shapes which, as they
grew older, produced malformation of the limbs. Women had to draw loads nine miles daily. In one instance,
a girl worked 24 hours at a stretch, rested two hours, and then worked 12 hours more. When such
callousness to human suffering possessed the mine owners, it causes little surprise to learn that,
through want of proper precautions, accidents were frequent and lamentably disastrous.
When the report of the Commission was produced in Parliament,
every member expressed a genuine horror that such things should be permitted in a land where poetry at least
declares that nobody is a slave, and an act was speedily passed prohibiting female labor below
ground and the employment of boys under 10 years of age.
Today, everything has been changed.
As we shall see, the health and safety of employees is regarded as of primary importance,
and human ingenuity has been taxed to render their toil less irksome.
We will now pass at once to the work of winning and getting coal.
Winning signifies penetrating to the coal measures by shafts, tunnels, or slopes,
getting the removal of the mineral from the seams.
The first operation is one in four,
which the mining engineer has to perform some of his most important offices.
Suppose that a new district is about to be exploited. A company is formed and an engineer is
appointed and sent out to search the country and to decide what is the best plan of operations.
Perhaps he may stumble upon an outcrop of coal showing on the side of a hill and be able to
calculate the dip or angle from the horizontal at which the seam plunges under the super-incumbent's
and the strike or direction in which the seam runs laterally.
If no signs of coal are visible at the surface,
he must resort to boring with a diamond drill,
which has almost entirely replaced the cylindrical steel auger once used for the purpose.
Its cutting edge is circular and studded with amorphous black diamonds,
which will pierce many thousand feet of hard rock before they need replacement.
An engine is installed over the spot where a test-holted,
is to be bored, and a hollow rod carrying the drill is attached to an apparatus which gives it
a rotatory movement. As soon as this rod has sunk in a certain distance, a second length
with butt or flush joints, which offer no obstruction to the descent, is screwed on and the work
proceeds. Water is forced down through the hollow interior of the rods to wash the sludge or
rubbish to the surface. Through the space between the outer face of the rods and the face of the
whole. From time to time the drill is raised, bringing with it a solid core of the substances
through which it has eaten its way. An examination of these cores tells the expert prospector
whether he is nearing coal, and furnishes an exact record of the strata under his feet.
At last perhaps a black cylinder is extracted, the long-wished-for coal. Still the boring goes on,
revealing seam after seam of the mineral.
The drill is then moved to other spots,
and the process is repeated
until the engineer has accumulated sufficient information
about the lie of the coal
to warrant a commencement of actual mining operations.
A good diamond drill will sink 60 feet a day
at a cost of about 1,000 pounds for as many feet.
With greater depths, the expense grows
as the labor of raising and turning the drill increases.
steadily. If a coal seam comes to the surface at a gentle angle, a slope is driven down through the seam,
or a tunnel is cut into it from a point below the outcrop if the ladder is discovered on the side of a hill.
In the bituminous districts of the United States, almost all the mining is done through
tunnels, slopes, and drifts, because the coal beds fortunately lie very horizontally and can be
approached at a gentle upward or downward
angle. Where
possible, the entry is driven uphill,
so that mine drainage
and the haulage of material to the mouth
may be assisted by gravity.
In England, the coal beds
lie deep and must be won
by shafts. Before sinking a shaft,
the engineer must decide its most
advantageous position, as he
wishes to strike the seam as nearer as
possible to the synchinal axis
or bottom of the bowl, that here too gravity may come to his aid in collecting the water and rendering hollage easier.
The shaft may be round, elliptical, or rectangular.
This will depend on circumstances.
In soft and yielding strata, a round shaft, well lined with brick or iron, is necessary,
since that shape offers most resistance to squeezing.
But where the overlying measures are solid and hard, a rectangular shaft,
at once cheaper to make and more convenient is preferred.
Such a shaft is usually divided into four divisions,
the two central ones forming up and down tracks for the cages,
and the other two pumping and ventilating shafts.
The partition separating off the last must be made quite airtight
by careful boarding and the plugging of all joints.
Of late years, boring machines have been introduced for sinking.
They consist of a central pillar for,
which radiate arms, each having at its extremity a power drill to make blasting holes.
As soon as the holes have been bored and the charges placed, the machine is raised out of danger
and the charges are fired.
Brick layers follow the excavators and build a lining round the shaft wherever it shows signs
of caving. In some workings the excavations and bricklaying go on simultaneously. The masons being carried
by a staging which fits the bore of the shaft exactly, so that no materials may fall on the heads
of the people below. Holes are left in the staging through which the broken stuff of the blasting
operations is removed. When a water-bearing stratum, such as a quicksand, has to be traversed,
the difficulties of sinking are much increased, and it becomes necessary to line the shaft
with iron tubing. Sometimes the inflow of water is so great that it is so great that it is a
it can only be kept at bay by airlocks, which act on the same principle as the great head shield
for tunnel driving. In 1883, a most ingenious process of freezing the ground round the shaft
was introduced by Mr. A. H. T. Putch, and has been used successfully in France and Belgium.
The soft ground is temporarily solidified by freezing the water for a few feet all round the scene
of operations. To affect this, brine, chilled to a temperature of 5 degrees Fahrenheit, is circulated
in vertical pipes closed at the bottom, inserted into boreholes sunk at regular intervals
round the space to be frozen. Each pipe has a central tube of small diameter reaching almost to the
bottom. The brine is forced down through this, and returns upwards through the space between the two tubes.
When hard ground is reached, an iron lining is lowered and any interstices between it and the wall of the shaft are filled in with concrete.
Shafting is expensive work, as much as a hundred thousand pounds has been spent on a single shaft.
The deepest shafts are to be found in Belgium, where 3,790 feet has been exceeded twice.
In Lancashire are situated the two finest British examples, three thousand.
4474 and 3,3,360 feet respectively.
English mine owners are now compelled by law to have at least two shafts to each mine,
so that in case of an accident blocking the one, the workers may still have a means of escape.
Footnote, this legislation resulted from an accident at the Hartley Colliery,
where the single shaft was blocked by the fall of the pumping engine beam,
causing the death by starvation of all the poor fellows in the mine.
End of footnote.
In any case, two shafts would be advisable as rendering proper ventilation more easy,
and in some cases a third shaft is sunk and used only for pumping out the water,
which often bears the proportion of three tons to every ton of coal extracted,
while occasionally the ratio is four or five times higher.
When at last the shafts have entered the coal seam, the winning is at an end,
and as soon as machinery for pumping, ventilating, and hoisting is in full work,
working order, the process of getting commences. All round the bottom of the shaft, a thick
body of coal is left, to avoid any settlement of the roof at this vital point in the workings.
From the pit eye, as it is called in Scotland, two galleries are driven parallel to one another
and of large size, the one named the gangway or trackway for haulage, the other the airway
for ventilation. From these headings are driven into the coal for the removal of the sea.
There are two chief methods of getting coal.
One is known as the long wall, by which the whole of the coal is removed as the seam is penetrated,
the excavated area between the working face and the gangway and airway being filled in with gulf,
or rubbish, except for the protected passages which are needful for the ingress and egress of workers in air,
and for the trucking of the coal.
The other method is called the pillar and stall, pillar and the wall,
pillar and room, or pillar and board. In this case only part of the coal is removed, a large
proportion being left to support the roof, so that the workings somewhat resemble a large
crypt. The long wall method requires a good roof and floor, and a seam not exceeding
six to seven feet in thickness. When the seam is very thin, not more than three feet thick,
only long wall mining is practicable. Let us watch the long wall
minor at work. Lying on his side, he attacks the base of the wall with a sharp pick, and undercuts
it to a depth of three to five feet. As the excavation proceeds, it becomes necessary to insert
short, stout props between the floor and the slanting top of the groove, so that the roof
may not fall on the worker. As soon as the holing of a length is finished, the props are knocked
out, and if the coal does not fall naturally, blasting charges are fixed and fired to bring it down.
The fallen masses have now to be loaded onto flat trucks, a very arduous task in a space where a man
cannot even stand upright, and shoved to the gangways by putters. Long wall work is very dangerous,
since the timber box, placed in a double row at a short distance from the face, are often
unequal to the strain and crumble like matchwood, allowing the roof to descend on the hapless miners.
Its advantages are that it allows room for more men to work in a given area and is therefore a cheap
method. Its disadvantages that it requires more timbering, suffers more by settlements when the mine is
idle, and is more difficult to ventilate. Where coal is over seven feet thick, or where the overhead
pressure is very great, the pillar and stall system becomes advisable. In some minds the pillar
must be left standing, but where possible they are robbed or removed as soon as the limit of the
seam has been reached. The miners working from the boundary back to the gangways. Where the coal is
very thick, it must be mined in terraces, as it were, pillars of extra size being left.
The loss from this method is considerable, and the danger from falls of roof
much greater than with shallow seams.
South Staffordshire, where the seams are sometimes 40 feet thick,
has an unenviable reputation for crushing accidents.
The problem of ventilation has been solved by a systematic plan of leading the air
only through the parts of the mine where work is in progress.
In a pillar and stall working,
the headings are driven out at right angles to the airway parallel to one another,
and as soon as the one heading has progressed a certain distance,
an opening is cut to connect it with the next heading.
Previous openings are carefully boarded up,
and as a partition has already been built between the points where the headings enter the airways,
the air is directed up one heading through the cross-opening
and down the next heading on its way to the upcast shaft,
that is, that through which the foul air is sucked by powerful blowers.
When work is done in what may be termed a blind alley,
having no communication laterally with another working,
circulation is affected by building a wall of thin wood or brattice cloth
down the center of the heading almost up to the face.
Air currents are needed for the removal of fire damp
as well as to promote the comfort of the miners,
and the greater the amount of gas liberated from the coal,
the larger must be the quantity of air circulated.
In the first half of the last century,
furnace ventilation was generally used.
You may imagine an ordinary room to represent the mine,
the open fire in the hearth of the furnace,
the chimney, the upcast shaft,
and the open door the supply from the downcast.
And there you have the principle of furnace ventilation.
The large fire at the bottom of the upcast expands the air in the shaft,
causing it to rise by reason of its lightness.
To take its place, fresh air rushes in through the furnace,
to be itself heated and expelled.
Though effective, this method had its obvious dangers,
and several serious mine fires have been traced to it,
so that mechanical ventilation is now almost universal.
To replace the furnace, huge air pumps were first used,
with enormous cylinders, pistons, and valves.
They often broke down, a fatal defect,
as the air below ground must be kept in continuous motion.
So they gave way to the centrifugal fan, which is connected with the upcast in such a way that air cannot reach the fan except from the shaft.
The Ghi-Bal fan, so largely used, is enclosed in a case, with a central opening at one side through which air is sucked to be flung by the curved whirling veins through another opening into the atmosphere.
The principle is precisely that of the centrifugal water pump.
Some old gheeball fans had a diameter of 45 to 50 feet and were turned directly by steam engines,
but more modern practice uses a much smaller fan turned at a greater speed by steam engines or by electric motors.
The steam turbine by has proved very effective on account of its high speed to work a fan direct.
A large fan will pass a million cubic feet of air per minute, sucking it through a circuitous course
which may run for several miles underground between the downcast and upcast.
Recognizing the full importance of ventilation, mining engineers sometimes sink a special shaft
to serve as the downcast. We may now return to the face and speak of the mechanical devices
which are gradually replacing hand-hewing. We have seen that the labor of holing or undercutting
long wall faces is at once severe and risky. As long ago as 17,
In 1961, a man named Menzies proposed to work a heavy mechanical pick underground by power transmitted to it by ropes from an engine on the surface.
But until the introduction of compressed air into mines, it was impossible to operate a practical coal cutter.
We now have four main types of coal cutters worked by compressed air or electricity.
First, a mechanical pick, which closely imitates the action of a miner, and is particularly useful for the
short faces in pillar and stall work. Second, a horizontal disc cutter, much resembling a
large, coarse-toothed circular saw. Third, an arm round the extremity of which passes an endless
chain furnished with teeth. Fourth, a horizontal bar-carrying teeth, which revolves on its axis.
Some of these machines, especially those used for long wall work, are mounted on rails,
along which they propel themselves or are pulled as the cutting proceeds.
For pillar and stall operations, a pick machine has been invented which makes a vertical cut.
The employment of mechanical cutters is much more extensive in the United States,
where 25% of the bituminous coal is got by their aid than in Great Britain,
where the proportion falls to 2%.
But when prejudice permits their wider adoption,
the economies rendered possible by their use will,
doubtless help the industry, since the saving per ton ranges from six pence to a shilling.
Unfortunately, the miners, like workers in many other trades, fear that mechanical appliances will
reduce wages and the need for human muscles, though more probably it would have the opposite
effect, to judge by the high pay given in the states, where coal is much cheaper than on this
side of the Atlantic, and the quantity produced per man 68% more.
Electricity is now very popular in coal mines to light the galleries, move the cars, pump the water,
operate cutters, and supply means of communication between the workings and the surface.
On the continent, the main winding gear at the pit head is also sometimes moved by electricity.
Compressed air too plays a very important part to turn drills and cutters, pump, hoist, and haul.
In the bituminous coal fields of the states, both electric and compressed air are employed to bring laden trucks out of the mines.
Sometimes the main entrance is there made wide enough to admit of four tracks being laid side by side.
After being broken down, the coal is loaded in trucks and pushed along the branch line leading to the main gangway.
Here they are formed into trains for haulage to the shaft bottom, in a deep mine,
which is done sometimes by ponies or mules, sometimes by mechanically driven ropes.
Where a double track is possible, an endless rope is laid between the rails,
passing at one end of the plane round the winding drum at the other round a fixed pulley.
The full cars are hitched to the up side of the rope, and so taken to the shaft.
The rope travels continuously in the same direction all the time.
When the tail rope system is used on a single track, the engines must be reversed for the down journey.
At the pit's eye, a hydraulic lift several stories high is awaiting the trucks.
The lift is lowered and a truck or two are pushed in.
Then it rises a little till the floor of the second story is on a level with the rails.
On go the second batch of trucks.
Up it rises another stage.
and so on till the loading is finished and the lift has risen to its full height burr down comes the cage with empty trucks
these are all pushed off simultaneously into a second lift which will gradually deposit them while the next load goes up and the full ones are pushed on board the shaft is three thousand feet deep surely the journey to the top will take a considerable time
No, the winding engines are powerful.
Whir!
The signal has been given, and almost before you realize it,
the bottom of the cage has disappeared into the upper darkness.
By the time the central point of the shaft has been reached,
the cage will be flying upwards at the rate of 35 miles an hour.
Already the cage has finished its journey.
It knocks open two flap doors at the pit's mouth
and is brought to rest opposite a second set of lifts,
which rob it of the full trucks and puts empties aboard.
The laden skips are run over a way bridge and tipped into shoots.
Then they are restored to the lift for the downward journey.
So the work goes on for hours at a time.
Empty trucks descending in one division of the shaft,
while full ones rise in the other.
Before the day is over, a couple of thousand,
tons of coal maybe have been brought up into the daylight, which last shown on it eons before
man first inhabited the earth. It sounds so simple, this hoisting system, with one cage
partly balancing the other. But it is not so simple after all. Don't forget that the rope
must be stout and strong and therefore heavy. Two or three thousand feet of rope weighs a good
deal more than the load itself, so that when one cage is at the bottom all its rope has been
paid off the drum, while all the rope of the other has been wound in and so has no counterbalancing
effect. The engine, therefore, has less and less to do as the cage rises, for the second
rope is exerting an increasing pull, and soon after the cages have passed one another, the
descending rope would quite overcome the ascending.
To meet this variation of load, tapering drums are often used, the rope winding onto the drum
from the small to the large end, and of course unwinding in the reverse order. This helps to
keep the balance more even as the rope exerts less leverage on the drum the farther it is
paid out. It must be understood that the cages are not attached to the ends of one rope. Each has its
separate rope, sometimes thicker at one end than the other, the larger end being attached to the
drum. Another method of equalizing strains is to have cylindrical drums and a tail rope passing from
the bottom of one cage round a pulley at the pit's bottom and up to the bottom of the other cage.
Thus there is always the same amount of rope between the bottom and top in each cageway.
Whatever shape the drums may have, they are mounted.
either on a single axis or are so geared together that they cannot turn independently.
Then there is another difficulty.
You can easily see that if a rope is being wound on a drum fixed so that it cannot move laterally,
the rope will be at right angles to the drum only at one point.
When the rope is very long, the angling, as it is called, becomes troublesome,
and to obviate it, Mr. W. Morgan mounted engine,
mounted engines and drums on a traveling carriage,
which traversed a distance laterally equal to the diameter of the rope
with every revolution of the drum,
so that the rope always lay on a line drawn through the center of the overhead pulley wheel
to the drum and formed a right angle with the latter.
Every reader has seen, or at least heard of, the pneumatic tube system of dispatch.
The article to be transmitted is in the article to be transmitted is in the letter.
inserted into a carrier, the carrier is placed in an airlock connected with the tube,
and either blown or sucked through it to its destination.
Well, the same principle has been tried for coal-raising and with success,
so that it is worthy of mention.
Monsieur Blanchet fitted the Epinac shaft, near Cruzeau in France,
with a wrought iron tube, 63 inches in diameter,
hammered round upon a special mandrel and placed on one side of the shaft.
The cage, which had nine decks and carried over four and a half tons of coal,
was slung below two airtight pistons and above a third,
and under all was a parachute, which, in case of a fall, would jam in the tube.
Three cages could be loaded and unloaded simultaneously.
Their ascent and descent was controlled by valves putting the tube,
in connection with the exhausting engines or the outer atmosphere.
To raise a cage from the bottom,
the bankstman had merely to open a valve,
and the load was sucked up,
and to lower it, he opened another valve
which gradually let atmospheric air into the tube,
allowing the cage to fall by its own weight.
Unfortunately, the shaft did not pierce a coal-bearing stratum,
and the pneumatic coal hoist has therefore not received a trial
under full working conditions,
but the device acted so well
that, had a seam been struck,
it would have done good service.
Quote,
it is highly probable
that we have not seen
the last of the pneumatic system of hoisting.
Its advantages in connection
with deep shafts are numerous.
The method can be practiced
with as great facility in mines
of enormous depth as in shallow mines,
and the winding rope,
which in a deep mine is
a very expensive item and a constant drain on the resources of the concern is entirely dispensed
with. A large load can be dealt with at each trip and the speed of the cages, especially in the
descending trip, is almost unlimited. End of quote. From the engineering magazine, January 1904.
When the coal reaches the surface, it has still to go through several processes before it is ready for
sail. Anthracite and other kinds of coal that come to the surface in very large lumps
must pass through powerful crushers which reduce the masses to a convenient size. The mineral is then
passed along traveling belts and sorters standing on either side pick off the slate, fireclay,
pyrites and other rubbish that may be present. After that, the coal is passed over gratings
of decreasing mesh, which sort it out into various sizes. To clean the coal,
small coal, handpicking would be too expensive, and washing with water is used instead.
The stuff is poured into jigging troughs, which keep the contents in constant motion
and cause the heavy impurities to sink to the bottom, whence they are ejected through a valve,
and the lighter coal to keep near the top and be carried off by the current flowing through
the troughs. The cleaned coal is lifted by bucket elevators into storage bunkers. The fine dust
which formerly was emptied onto the dump heaps along with the rubbish,
is now saved and either converted into coke or into briquettes, according to its nature.
Until these new uses for the duff was found, the loss was enormous.
Quote, it is estimated that from 20 to 25% of the coal mine was carried to the dumps.
The wasteful methods of treatment are evident in many of the streams which drain the coal basins,
for the beds of these consist largely of coal and slate washed by storms from the waste dumps.
For a distance of 30 to 40 miles below the workings, farmers collect their fuel,
and screeners make a good living by digging coal from the beds of creeks
or from bars formed on the banks during freshets and selling it.
End of quote from Cassiers magazine.
This quotation applies to the American anthracite fields.
Even the rubbish is not all wasted, for in the States at least, a use has been found for it.
Where a mine underlies houses, there is a danger that settlements may cause the cracking of the walls
if the excavations are within a thousand feet of the surface.
To prevent this possible damage, the plan has recently been adopted of crushing the rubbish,
mixing it with water, and discharging the cullm, as it is called, through pipes or boreholes into the exhaustive.
workings. The water drains off into collecting pits and is pumped to the surface. The solid
matter left soon solidifies and becomes so firm that headings can be driven through it. This method
of refilling does away with timbering and the necessity for leaving large pillars of good coal,
and also helps to diminish the refuse heaps. It is interesting to note that the idea has been
mooted of pumping a mixture of coal dust and water through pipes'
from the coal fields to distant towns,
just as natural gas and petroleum are piped so extensively in America.
The colliery owners are very anxious to be rid of the banks,
and sometimes actually set them alight.
In some piles, fires have been burning for nearly a century.
We may be certain that in the future these huge, unsightly deposits
will become valuable, probably as fuel for larger power stations,
which will distribute electrical energy through the surrounding country.
From the mines, the coal is distributed to the consumers by rail only or by rail and water.
Vast quantities are shipped annually overseas from England and the United States.
If you visit Cardiff, Swansea and Newcastle in England, Port Richmond, Greenwich Point, Curtis Bay, Newport News, and Buffalo in the United States,
you will see great transporters dumping the mineral by the thousand tons into the holds of grimy-looking vessels.
The most sensational methods of handling coal are American, so we will follow them for a page or two.
Near the mine is a tipple, or superstructure, overhanging several railway trucks.
The mine trucks are run onto a platform sloping downwards at an acute angle.
Their lower ends are opened, and their contents fall out onto screens,
which sort the coal into various sizes, each of which passes through its own weighing machine,
and is shot into the railway cars down below.
In this case, the sizes are kept separate and made up into special trains.
But if the order comes for run-of-mine coal, that is, unsized coal,
the hole is poured without separation into a train of empties down below,
which is drawn forward under the tipple by the locomotive, as each car,
which holds upwards of 50 tons, is filled.
Then off goes the train, weighing perhaps two thousand,
thousand five hundred tons, to the port, where it arrives without much difficulty as the grades
generally run downhill from the coal fields to the coast. At the port, the cars are pushed onto elevated
piers, which have openings under the tracks and above the mouths of chutes leading to the hold of the
vessel to be loaded. As each car comes over an opening, a trap door in its bottom is released by
pulling a lever, and in five minutes or so the 50 tons have passed into the chute.
By discharging several cars simultaneously, 2,000 tons per hour can be transferred from train to vessel.
Boats specially built for coal transport are now largely used.
They are divided by steel bulkheads, running longitudinally and transversely into large bins,
and the cargo is thus prevented from shifting.
Where such subdivision of the hold is not made, the collier may, if it meets a gale,
alter its trim with disastrous results.
Ships of 11,000 tons' capacity have been floated for the coal trade,
and in future years, even larger units will probably become popular.
A great deal of money is saved by the employment of these special ships,
since the bin will trim itself, whereas in a large open hold,
the labor of a number of men would be required to make them snug.
End of Chapter 18, read by Jeffrey.
Wilson, Ames, Iowa in January of 2023.
Chapter 19 of The Romance of Mining.
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Read by Ted Linehart.
The Romance of Mining by Archibald Williams.
The Mining of Iron.
Anyone who is interested in the story of mining,
should not fail to visit a geological museum, such as is to be found in German Street, London.
This last building is full of objects which to a casual observer who has just strolled in to see if there's anything worth seeing,
are not peculiarly impressive, just slabs and pillars of stones, tables made of marble mosaic,
cases full of endless specimens, large diagrams of strata, seams, and faults, etc., etc.
The first view is rather disappointing, but if we look more closely into things, we shall soon find ourselves becoming interested.
Here is a diamond drill, which, to judge by the worn condition of the diamonds, has done yeoman service.
Beside it like cores of some seams penetrated by it.
Above it is mounted a large, old-fashioned steel auger, which it has supplanted.
The eye is also attracted to some of the lovely copper ores.
pyrites of golden color, blue azurite, purple ore from Cornwall, green ore.
The agates and felspars are beautiful to look upon.
Antimony, ore, and asbestos are curious.
Many oars would never suggest what they contain.
Their drab, uninteresting appearance helps us to understand
why the Comstock and Leadville miners made such mistakes in the early days.
Ah, here is a gilt model of the welcome.
nugget, the second largest ever discovered, value over 8,000 pounds. It rouses feelings of envy,
as we note the rough, corrugated surface, and try to imagine the sensations experienced by the lucky
miner who struck his pick-in to it nearly 50 years ago. Close to this model are cases full of iron-ore
specimens, representing a metal that has been vastly more valuable to mankind than all the gold,
silver and diamonds ever mined put together. In color, iron ore cannot compare with copper,
though the pyrites, or sulfide of iron, is golden, and the elbin ore wears the hues of the peacock.
The majority of specimens range from a dirty yellow through browns and reds to black.
Their shape is somewhat more interesting. Hematite, one of the most important varieties of
occurs as curious knobs with smooth shining surfaces. Spat-hose iron ore, on the other hand,
is made up of curious laminae, somewhat like butterfly's wings, standing up on edge.
Here again, there is little externality to suggest that the most useful of the metals
forms from 35 to 60 percent of these dull-looking compounds. Certainly we cannot see a trace of metal
sparkling from the lumps. Iron is even more widely distributed than coal. We may say at once that
scarcely a country could be named in which iron ore deposits are not to be found. Some of the most
notable fields will be mentioned presently after we have briefly enumerated the chemical compounds
in which iron occurs. The only naturally pure iron is that contained in meteorites, which have fallen from
the skies and once formed part of the heavenly bodies. A poetical mind might see in the fall of
these errant masses a divine hint that iron is the most valuable material gift that can be sent to man
from above. And indeed, it is remarkable that space should be full of iron lumps whirling about,
heated to whiteness whenever they encounter the friction of our atmosphere.
Combined with sulfur, iron appears as ferric disulfide or iron pyrite's, which is of little use to the smelter,
but valuable as a source of sulfuric acid or vitriol.
The oxides of iron, for example substances in which iron is combined with oxygen, are known as,
one, magnetite, also called magnetic iron ore or lodestone, which contains 72% of iron,
the largest proportion that can combine with oxygen.
Two, hematite, brown and red, including limonite, specular ore, lake ore, etc.
Hematite contains up to 70% of iron.
Thirdly, we have the carbonates of iron, i.e. iron plus carbon plus oxygen, which fall under
two main heads.
One, spathic iron ore, otherwise called spari ore, side right, or spat hose.
This has a crystalline form and is comparatively free from impurities.
Two, clay ironstone found largely in the coal measures alternating with coal and limestone.
This ore is the poorest in iron, of which it seldom contains more than 40%, but on account of its
interstratification with the fuel necessary to smelt it and the flux, limestone, needed to separate
the impurities, it has been, till recent years, the main foundation of the immense industries of
England and western Pennsylvania, though it has assumed less importance as cheap freights have
enabled ironmasters to import richer ores from distant regions to the smelting furnaces of the coal
fields, or to transport coal to the districts where the richer ores occur.
Taken as a whole, iron ore falls into four classes.
One, rich, those containing more than 50% of iron.
Two, average, those containing 35 to 50% of iron.
Three, poor, those containing 25% to 35% of iron.
Four, useless, those containing up to 25% of iron.
The last class is useless, however, only for smelting direct from
the ore. Thomas Edison, the Wizard of the West, has discovered a method of separating the iron from its
matrix by electricity. The ore is pulverized in a huge crusher, and the powder falls through a hopper
past the poles of a very powerful electromagnet, which deflects the particles of metal so that they
fall into a special receiver, while the rubbish drops directly into another. Iron mining, though as
compared with some other branches of mining, a modern industry, dates back into the unrecorded
past. The metal occurs in large pockets near or at the surface, as well as in veins and deep beds,
and was therefore easily accessible to workers armed with very simple tools. The Romans mined iron
extensively in the Forest of Dean, in South Wales, and in Sussex. At the time of the Norman
conquest, the Sussex industry had ceased.
since we find no reference to it in Domesday Book,
though smelting still continued on the borders of Wales.
Whence, during the reign of the Saxon kings,
England seems to have derived most of its iron.
During the Middle Ages, fresh districts were opened up near Warwick and Leeds,
and huge cinder beds testified to the activity of the workers,
who were to a great extent controlled by the abbots of the large monasteries.
At this time, ironworking was considered an iron.
honorable trade, and even so far back as the Regency of St. Dunstan, we have evidence that monkish
hands wielded the hammer and pincers, since it was at a forge situated in his bedroom that the saint
had his famous encounter with the devil. During the 14th and 15th centuries, England imported most of
iron and steel from Spain and Germany, the business being in the hands of the merchants of the
steel yard, London. Then the Sussex Furnesson,
grew busy, fed by the charcoal made from the forests, which then covered the weld.
Cannon were cast as early as 1543 and exported in such numbers to Spain that Sir Walter Raleigh said
in the House of Commons, I am sure her heretofore one ship of Her Majesty's was able to beat ten Spaniards,
but now, by reason of our own ordinance, we are hardly matched one to one, and the exportation was
prohibited by law. In Elizabeth's reign, the industry reached its climax, though the output was very
small as compared with that of other mining districts of today. A furnace did not yield more than
three to four tons a week, but to produce the comparatively small quantity of iron turned out by the
old works, the consumption of timber was enormous for the making of every ton of pig iron
required four loads of timber converted into charcoal fuel, and the making of every ton of bar iron
required three additional loads. Thus, notwithstanding the indispensable need of iron, the extension of the
manufacture, by threatening the destruction of the timber of the southern counties, came to be regarded
in the light of a national calamity. Up to a certain point, the clearing of the weld of its dense growth
of underwood had been an advantage by affording better opportunities for the operations of agriculture.
But the voracious iron mills were proceeding to swallow up everything that would burn, and the old
forest growths were rapidly disappearing. An entire wood was soon exhausted, and a long time was
needed before it grew again. At Lamberhurst alone, though the produce was only about five
tons of iron a week, the annual consumption of wood was about two hundred
thousand cords. Wood continued to be the only material used for fuel generally, a strong
prejudice existing against the use of sea coal for domestic purposes. It therefore began to be feared
that there would be no available fuel left within practicable reach of the metropolis.
And the contingency of having to face the rigorous cold of an English winter without fuel,
naturally occasioning much alarm, the action of the government was deemed,
necessary to remedy the apprehended evil. In 1581, an act was passed, which made it penal to convert
wood into fuel within 14 miles of London, to erect new ironworks within 22 miles, or to increase
the number of Sussex, Surrey, and Kent furnaces beyond certain limits. As a result of this legislation,
some Sussex Ironmasters removed to South Wales,
and the Sussex iron industry declined steadily till 1790,
when it ceased altogether.
Dr. Smiles says,
The din of the iron hammer was hushed,
the glare of the furnace faded,
the last blast of the bellows was blown,
and the district returned to its original solitude.
Some of the furnace ponds were drained
and planted with hops and willows.
others formed beautiful lakes and retired pleasure grounds,
while the remainder were used to drive flower mills,
as the streams in North Kent,
instead of driving folling mills,
were employed to work paper mills.
All that now remains of the old ironworks
are the extensive beds of cinders
from which material is occasionally taken
to mend the Sussex roads,
and the numerous furnace ponds,
hammer posts, forges, and cinder places,
which mark the seats of the ancient,
manufacture. Fortunately for England, she contained inexhaustible supplies of a fuel much better suited
than wood for smelting. A German named Simon Sturdivant took out a patent about the year 1610
for kneeling, melting, and working all kind of metal ores, irons, and steels with sea coal,
pit coal, earth coal, and brush fuel, which will prove to be the best and most profitable business
an invention that ever was known or invented in England in these many years. The concluding words
were true enough, for to what dimensions has the iron industry spread not only in England,
but in other civilized countries, since the employment of coal in the smelting furnaces. The United
States alone produced in 192 iron pig worth nearly 60 million pounds. And in England,
Germany, France, and Sweden also, the industries connected with iron ranks six.
second to that of agriculture. Sturtivant did not do much more than put a large number of words
purposely vague and mystifying on paper. The real introducer of coal as a smelting agent was undoubtedly
Dud Dudley, son of Edward Lord Dudley of Dudley Castle in Worcestershire. His patent for melting iron ore
with coal and furnace with bellows dates from 1620, but his invention was born before its time.
Never did inventor encounter more discouragement and active persecution than poor Dud,
whose private success aroused fears among rival Ironmasters that the use of coal would,
by increasing output, seriously lower prices. His life was one long struggle against heavy odds,
and when he died, at the age of 85 years, he had only sown the seeds of the revolution,
which afterwards overtook smelting methods in Britain.
Abraham Darby was one of the first ironmasters to rely on coal fuel.
He made a large fortune out of casting iron pots at Coalbrookdale, South Shropshire,
and his successors fairly established his methods.
At Merth or Tidville, Mr. Richard Crochet was in 1812,
turning out 10,000 tons of bar iron yearly,
thanks to the proximity of clay ironstone to good coal,
and the invention by Henry Court of the method of school,
squeezing the impurities out of iron bars by passing them through rollers.
The discovery of the black-band ironstone deposits of the western counties of Scotland in 181
led to the establishment of a thriving iron industry there.
And from that time onward, King Cole has been the great partner of King Iron.
Some of the most remarkable iron deposits occur as mountains of ore,
which can be quarried out like slate or marble by open-cast workings.
Near Bilbao in the Spanish province of Biscay are the most wonderful hematite mountains in Europe,
from which vast quantities of ore are got every year by a large army of miners.
The iron deposits form huge basins or quarries in the primeval beds of limestone.
Lying within a radius of 10 or 12 miles from tidewater,
they have lent themselves readily to the cheapest possible forms of transport.
Wire tramways connect the principal mines with wars of their own,
which steamers can lie alongside of and receive cargo as fast as it can be tumbled into them.
In the lower parts of Bilbao, the riverside is gridironed with iron rails running in from the mines.
Ever since the 16th century, Bilbao has exported iron,
the excellence of which was so well established in Elizabeth's reign that rapiers of high quality were known as Bilbo's. Between 1860 and 191, no fewer than 100 million tons of ore were mined, averaging about 48% of metal, and the output still reaches 5 million tons annually.
The Somorostro Hills contained two huge masses of ore, the Monte Triano and the Monte Matamoros,
The former is 3,080 yards long and varies in thickness from a few feet to 30 yards.
The latter has a length of 1 and a quarter miles and a maximum width of nearly half a mile.
These are worked out by lifts or terraces along which run railways.
The miners drill holes 15 to 20 feet deep and put in heavy charges of dynamite,
which, when exploded, detached large masses of ore.
The record blast moved 6,000 tons. From the workings, the ores carried to the sea coast on elevated ropeways, spanning hill and valley, capable of transporting thousands of tons a day. After the Rio Tinto, the iron mines of Biscay form Spain's most valuable mineral asset.
Other remarkable deposits are to be found in Elba and in Algeria, where at Ein Morka exists a large.
bed of hematite and magnetite 100 feet thick. The Swedish iron mines of
Donamora are world famous, having been worked for over 400 years. From these mines
come the purest iron known to exist, magnetite yielding 66% of metal. So very
excellent is the ore that the owners limit its production to 50,000 tons per
annum and keep the price at a figure which is possible only from the fact
Dona Mora ore has no rival.
Originally worked open cast, the vein is now attacked through shafts nearly a thousand feet deep,
under very modern conditions, which include the use of electric light throughout the workings.
With the approaching exhaustion of the Donomora vein,
European smelters are looking about for new Swedish iron fields,
and a rich strike has been made near Gellivere, a small town north of the Arctic Circle,
which will soon become the most northerly important mining center of Europe.
In this district, the ore lies in bodies 300 feet thick,
said to contain at least 250 million tons.
To connect these fields with salt water, two railways have been built,
the one to Lulia on the Baltic, the other across Norway to the Ophoton Fjord,
where the warm waters of the Gulf Stream keep the coast ice-free all the year round.
The ore contains over 62% of metallic iron so that the value of this iron mountain can hardly be estimated.
In the future, a Mexican deposit, the Cerro de Mercado, will become very valuable.
It measures a mile in length, a third of a mile in width, and rises from 400 to 650 feet above the surrounding plain.
Humboldt thought that the mountain must be an immense aerolite, though he was undoubtedly mistaken.
People of the country, deceived by the luster of the ore, mistook pieces for more precious metals,
hence the belief among them that the chero must conceal in its bowels untold stores of gold and silver,
that its value is nevertheless enormous cannot be doubted.
An expert who reported on the chero in 1858 said,
the bulk of the hill is 60 million cubic varas.
A varas is a Spanish measure equal to 33 and one quarter.
inches. As the specific weight of the mountain is five times greater than that of water, I found that
the quantity of metal amounts to 250 million net tons, which melted will produce at the rate of
50 percent the quantity of metallic iron. The quantity may be overestimated, but many fortunes
must lie in that mass. It is curious that, in spite of the enormous quantities of iron which
their country contains. The Mexicans until comparatively recently regarded iron as a precious metal,
too precious to use in the manufacture of carts and plows. A peculiar feature of the chero-macado
is the number of ant-heaps covering its surface, each heap composed of myriads of round iron ore pellets
of equal size. The natives use this ready-made small shot for sporting purposes. When iron ore is found
far below the surface, the methods of mining it closely resemble those used in gold quartz or coal mining
and therefore need receive no special attention. But the great surface deposits of the Lake Superior
region, which now furnish so large a proportion of the world's iron, are worked on a system which is
somewhat different from those in use elsewhere and deserves as mentioned. The Iron District of Lake
Superior extends in a line running across northern Michigan, Wisconsin, and Minnesota, and includes
the Marquette, Menominee, Georgiebic, Vermillion, and Masabi ranges of hills. All the mines lie within
100 miles of the lake, with which they are connected by rail, as also with Lake Michigan.
The varieties of ore found are magnetite and hematite, where the ore occurs as veins with a very
sharp dip, a shaft is sunk through the rock under the vein, and a heading is driven horizontally
through the ore as soon as the depth of about 60 feet below the surface has been reached,
and a level is driven along the vein for some 8 to 10 yards. The ore is then dug out,
working upwards by the overhand stoping method, timber being placed to support the roof.
When the miners reach the roof, they extend the original level another length,
but leave the oar over this alone, and sometimes for another eight to ten yards.
This block they excavate like the first, and then blast away all the timber supports.
The roof caves in, filling the chamber, and the central pillar is then worked out and caved.
The vein has now had a block 30 yards or so long, 60 feet high, and of its own breadth excavated.
The shaft is sunk another 60 feet, and the process continues.
till perhaps a depth of 1,000 feet is reached.
The chief advantage of this method is
that the amount of rubbish overhead is kept constant at all depths,
the original roof traveling down the vein as the shaft and working sink.
Where deposits are bowl-shaped,
but have a considerable overburden or covering of useless material,
the same plan, somewhat modified, is pursued.
A vertical shaft, 100 feet deep, is sunk
through the containing rock, and levels are driven into the heart of the ore body.
From these, timber rises, or small shafts, are worked upwards to within a few feet of the overburden,
some to act as ladderways, the others as shoots down which to pour the ore into skips waiting in the
level below. A horizontal slice, seven feet thick, is excavated under the surface soil,
and when a sufficient area has been robbed, the floor is covered with rough planks to make a firm roof for the next slice, and the props are blasted.
The surface of the ground sinks in, leaving a visible depression. Slice after slice is thus taken away, and when the main gallery is reached, the shaft is sunk further.
Another level is driven, more shoots and ladderways are worked, and the same series of excavating operations is repeated.
Finally, an immense chasm indicates the former position of the ore body. To a being to whom a year
seemed but an hour, the sinking of the surface would be most mysterious, for not a single worker
is in sight. A third method, called the milling method, utilizes the shaft and the gallery,
but the overburden is first stripped, and the ore, excavated as in an open cast, is poured down
minor shafts into the gallery and hoisted through the main shaft. Under certain circumstances,
this is a more economical way of working than hoisting direct from the surface of the exposed
ore body. Where possible, that is to say, where the ore is sufficiently soft and the deposits lie near
the surface, a cutting is made through the ore and steam shovels are used. In the Masabi district,
the ore lies on the slopes of the hills and immense masses with little soil above it.
The steam shovels used are similar to those known in Great Britain as steam navvies,
but are larger and more powerful.
Those of the most modern type have three separate pairs of cylinders and one boiler.
They weigh 92 tons and cost about 1,900 pounds each.
One machine has filled 233-25-ton ore wagons,
or a total of 5,825 tons in nine hours.
But this is a record performance.
Five tons of ore can be lifted by the machine each stroke,
and five full-weight lifts will fill a wagon.
Ten men, exclusive of the train men,
are required to work the machine,
which consumes about four centa-weight of coal an hour.
The mountain iron mine is half a mile long by 1,200 feet broad,
and at present 85 feet deep.
It has worked in horizontal slices of 20 feet,
the vertical range of the steam shovel.
Removal of the surface soil as required is also performed by the machine.
A train of 10 to 12, 25-ton wagons is run alongside a steam shovel
and is worked forward by a locomotive as fast as the wagons are filled.
It is then drawn out, sorted, and made up into longer trains
for transport to the docks on Lake Superior.
These trains usually consist of 44 wagons, whether full or empty.
Whilst one engine is attending a steam shovel, another is preparing a set of empties to replace
those drawn out full.
In this way, the work is almost continuous.
Thanks to this expeditious handling, the ore, though pure and rich, is supplied to purchasers
at ten pence per ton on the wagons.
In the last chapter, we noticed the value of Connellsville Coke for smelting purposes.
Now Connellsville and the Lake Superior ore deposits are far apart,
though each forms the complement of the other in the production of high-grade Bessemer steel.
To transport ore to Connellsville or Coke to Michigan would be equally economical
as it takes about one ton of coke to smelt the same weight of ore.
But for the rolling mills and other steel-prearing machinery,
Steam coal would be needed, and accordingly Pittsburgh in the Pennsylvania coal fields,
was chosen as the point to which both ore and coke should be brought.
The ore is conveyed on large trucks direct from the mine to the lake ports,
where it is transferred to special boats in much the same manner as coal,
though more expeditiously.
A vessel of 5,000 tons can be filled in a couple of hours.
From Duluth, the chief loading port, the ore carrier,
to the Sioux-St. Marie locks between Lake Superior and Huron. The largest lock is 900 feet long
and 60 feet wide, and is said to rank first in the world for size. From Lake Huron, the ship passes
through the Erie Canal to the Erie Lake and heads for Cleveland, the chief receiving port. Here,
machinery of the most modern type scoops the ore from the vessels hold and dumps it either on huge
stockpiles, containing millions of tons against the time when it will be needed for the furnaces,
or transfers it directly to 50-ton trucks, which will be hauled by mighty locomotives to Pittsburgh.
At that town, the ore is stocked or tipped into buckets, which convey it to the tops of the furnaces.
Here we will leave it, as the scope of this book does not cover the story of steel manufacture.
We may notice, however, that thanks to the cheapness of transport and the ease with which both coal and ore or mined,
a ton of Bessemer pig can be produced at Pittsburgh for about 33 shillings, or for nearly 20 shillings less than at Middlesboro.
No wonder that English ironmasters are feeling the pinch of foreign competition.
The Lake Superior ore beds yield about 15 million tons yearly, and the Misabi on the Mesaubi,
Iron Mountain alone will not be exhausted till some 500 million tons more have been removed,
so that this immense iron district, noted also for its copper and coal deposits,
will continue to supply Pittsburgh for many years to come.
But we must not forget that at least as much again as mined in Pennsylvania, Missouri,
which has its own Iron Mountain, New Jersey, Virginia, Colorado, New York, and other states.
Furthermore, the United States yield only three-eighths of the world's iron and steel.
There are immense iron ore beds in China, Siberia, Russia, Australia, and Africa, which have as yet
scarcely been touched. In truth, we cannot imagine a time when the world will be so denuded
of iron that the happy possessor of a nail will, like Captain Cook's Oteitin-Chief,
receive no small emolument by letting out the use of it to his neighbors for the purpose of boring holes
when their own methods failed or were thought too tedious. Well, has this age been styled, the age of iron?
End of Chapter 19. Chapter 20 of The Romance of Mining. This is a Librevox recording. All Librevox recordings
are in the public domain. For more information or to volunteer, please visit Librevox.org.
mining by Archibald Williams. Marble Quarries. Carara. Greek Marbles. The town of Carrara.
The quarries. How marble is blasted. Bringing down the hillsides. The Litsatura. Road transport.
The miners of Carrara. Marble in Britain, Algeria and India. The marble beds of Vermont.
Electricity and harness. In the north of Tuscany, ranged in a line parallel to
the sea coast, you will see on your map the three towns of Karara, Massa, and Seraveza.
From the environs of these towns come the famous statuary marble, to which Karara has given its
name. Marble of a pure white hue, and so free from foreign matter that, when broken,
it shows a texture much like that of sugar. The Greeks, a race of famous sculptors,
quarried their marble from Mounts Patriculus and Hymetus, or sent overseas for it to the island
of Paros. If you wish to make acquaintance with Pentilic Marble, visit the British Museum,
where the Elgin Marbles, removed from the Parthenon at Athens in 1816, may be seen.
Beautiful indeed is the smooth limestone in which the Greek artists materialize their ideals.
But the marble of Carrara is almost, if not quite, as perfect as that used by the Athenians.
For a thousand years the Tuscan marble hills have resounded with the blows of hammers and picks, and later with the crash of explosions.
Augustus boasted that, thanks to Carrara, he had left Rome a city of marble palaces, though he found it one of brick.
The old Roman working still pit the hillsides. Long after they fell into disuse, the great Florentine, Michelangelo, and Antonio Canova,
hewed their immortal statuary out of Karada and marble, which today still remains without a rival.
Avenza is the port from which the marble is sent all over the world.
Blocks of all weights, from 40 tons downwards, cover the key and glisten in the intense Italian
sunlight. They have been brought down from the quarries by road and rail.
Karada itself, a town of about 30,000 inhabitants, is five miles from the coast. The railway leading
it runs over marble ballast and through tunnels driven through solid marble. Every siding is full of
marble-laden trucks. The town appears to be one vast workshop, where everybody, from small children to
old grandfathers, lives by his chisel and mallet. In the lower rooms of the houses, all kinds of
carvings are in progress. Here mantle shells are being smoothed and polished. There are tombstones.
The sculptor of artistic statuary also has his studio here.
He comes to the marble. It is cheaper than to have the marble set to him.
The streets remind one of Juvenal's account of Rome. They are filled with wanes,
creaking beneath their white loads, and hauled by long strings of horned oxen,
whose movements are spurred by drivers perched on the yokes.
Like Johannesburg, Carrara is a city of dust, but here the dust is snowy,
and comes not from piles of rock rubbish, but from the workshops.
The town is indeed interesting,
but the visitor would be disappointed if he had to leave the neighborhood
without first visiting the quarries where the brown quarrymen blast and hack
and cut the marble from the living rock.
As the hills are practically solid marble,
there is no need to tunnel for it.
Beginning at the foot of a slope,
the workmen cut into its sides
until a gigantic semi-circle has eaten far back into the mountain.
Large masses are detached by dynamite,
which is placed in very carefully drilled holes,
and in such quantities as to separate without splitting the marble.
The first visible sign of the operation
is the sight of masses tumbling down the mountainside,
30 and 50-ton blocks looking like mere pebbles.
The distances are enormous,
but the animated black specks,
which one knows to be men, are clearly silhouetted against the surrounding whiteness.
Something like a black ant suddenly makes its appearance and blows a sonorous blast on a horn.
Other horns, numbers of them, take up the warning note, the sound gradually dying away in the distance.
Then more ants are visible, swarming to the shelter of a bomb-proof or casemate.
After the last horn has ceased sounding, not a soul is to be seen.
then comes the boom, the rattle, and the falling pebbles, and presently the ants swarm out again,
apparently from all sides, and proceed to drill more holes and put in fresh blasts.
The men must love the sound of that horn, for it means a ten minutes loaf for them.
The easiest part of the work has now been done.
It doesn't take long to drill a few holes and insert charges,
but the removal of the blocks to the sea coast is a tedious, somewhat dangerous,
and very laborious business. And in some quarries, the job is done by contracts made with the hauliers,
locally called Lizzatura and Caravana. The former only undertake the lowering of marble,
after it has been roughly squared, from the spot where it comes to rest after blasting to the nearest
wagon track, or to the railway. Certain paths have been selected down the marble-covered slopes,
over which the blocks will slide most easily by force of gravitation.
the difficulty is not so much to pass the material down as to prevent its going too fast and causing damage to itself and to anything it may encounter
watch these litzatura at work they have produced screw jacks and levers with which they slowly raise a block on to a solid sleigh of hard beech wood ropes or rather cables for they measure from three to five inches in diameter are then passed round the block
now if you use your eyes well you will see ranged at intervals down the slope stout posts driven into the loose stones and rubbish by means of the ropes law enforces the use of three and the posts the stone is gradually allowed to slide down the track
As soon as it begins to move, a man places a second skid in its path, and when it has passed over the
first, this is picked up by a follower, who hands it to a man perched on the stone to be soaked
and handed forward again. The same three or four skids are thus used in rotation, over and over
again. The men who lay the skids naturally run the greatest risks, and occasionally the ropes
break, and one is killed. At last the descent is accomplished. It now only
remains to raise the block onto wagon or truck. This process includes a great deal of shouting and yelling,
by which the workers, apparently, try to drown the sensations of severe muscular exertion.
The screwjacks once more come into action, and levers are requisitioned. The men tug and strain,
working with the harmony born of much practice, and the moment soon comes when they can fling down
their tools and make a rush for the nearest wine shop. The caravana now get their
if road transport is used. The wagons have very powerful brakes, wherewith to control the descent
on the downgrades. Water has worn down the road until it suggests the bed of a mountain torrent
rather than a track for wheels, and the going is far from easy. Remember that some of these blocks
weigh as much as four traction engines, and you know how one of these machines will impress the
surface of a well-made road. The people engaged in this employment, writes Mr. Hart, which is
practically hereditary, are a fine, sturdy, hard-working race of mountaineers. They are true
highlanders, and not in the least like the Italians of the towns. Many of them have to climb
three, four, and even six miles before reaching the scene of their labors. Their wages or
earnings range from 15 shillings to one pound per week, and they generally work in. They generally work
gangs, each gang being under the control of a headman, who is more or less one of themselves
with the difference that he has saved or made money, and it is with him that the owners usually
contract for the quarrying and transport of the marble. The 400 quarries of the Carrara
neighborhood employ nearly 7,000 men and produce 185,000 tons of marble annually. At Avenza,
the marble is worth about three pounds per ton.
Though the British Isles afford no single center of marble quarrying operations to compare with
Karara, they can claim some fine deposits. South Devon yields marbles of rich tints and handsome markings.
Black marble comes from Galway, Kilkenny, and Derbyshire. Near Swanage, the famous Purebeck,
of a modelled greenish-gray, is quarried. In Algeria are beds of the beautiful,
so-called onyx marble, very transparent, with delicate yellow and brown tints. The glorious Taj Mahal
at Agra in India is built of marble from the Makranah quarries at Rajputana. The United States
marble industry ranks second to that of Italy. In South Vermont, round the town of Proctor,
are huge beds of the precious limestone, through which diamond drills have been sunk to a depth of
over 200 feet without entering any other substance. The Sheldon Quarry, the deepest marble pit in the
world, has its bottom 250 feet below the surface, yet there are at present no signs of exhaustion.
Much of the marble is got by open-cast working, but in places where the overburden is heavy,
great caves have been hollowed out in the hillsides, so large that several thousand people could
promenade in them comfortably. In Vermont, explosives are not much used. Their place being taken by
electrically or steam-driven machinery, which cuts long and deep channels through the marble,
dividing it into great blocks, which are separated from their beds by wedges. A stream, the Otter Creek,
has been harnessed to turbines of 300 horsepower for the generation of electric current and to
sawmills in which the blocks are cut in ground. The electricity generated is a
applied to all kinds of machinery, from the giant gantry cranes, which pile 30-ton lumps as easily as if
they were bricks, and the monster lathes turning the surface of pillars 25 feet long, to small mechanical chippers,
wherewith the monumental mason traces intricate designs on headstones. It also helps to convey sand
for the sawing of the blocks into slabs, on a cableway, which crosses a mountain from the sand-beds two-and-a-half-mile-distance.
The Otter Creek is thus responsible, in one way, for making Proctor the center of the state's marble industry.
One company alone quarries from 60,000 to 70,000 tons annually.
End of Chapter 20.
Chapter 21 of the Romance of Mining.
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read by Ted Linehart
The Romance of Mining
by Archibald Williams
Stone and Granite Quarries
at Corsham and Box
Stations on the Great Western Railway
situated respectively at the eastern and western
ends of the famous tunnel excavated by Brunel
you will see trucks laden with large blocks of white stones
standing in the sightings
and also piles of the same material in the station yards
This stone is that named after the neighboring city of Bath, which is almost entirely built of it.
The characteristics which make it specially valuable for building purposes are its freedom from grain,
its ability to resist the effects of long exposure to the air, and the ease with which it can be cut and carved.
The hills surrounding Bath are largely composed of this ulite or freestone, which is quarried from them,
and dispatched in huge quantities to all parts of Great Britain, and even to Canada, Africa, and India.
The mining of Bathstone is no new industry.
The Romans during their occupation of Britain soon discovered the worth of the ulite
and used it for the fine and interesting buildings which still encircle the hot mineral springs
which draw so many invalids to Bath.
The excellence of their preservation, though they have existed now for more than
2,000 years, testifies to the wisdom of the Romans in selecting their material.
Bath Abbey was built of the same stone by the Saxons, who also used it for the fine
abbey at Malmesbury. This stone apparently came from the box quarries, which, so tradition
tells us, owed their discovery to St. Aldhelm, the first abbot of Malmesbury, who, as he
rode over the hill, threw down his glove and bade his men dig there,
as they would find great treasure, meaning the quarry.
The same saint also erected the Saxon Church at Bradford on Avon,
which, though very small, is one of the finest specimens of Saxon architecture in the country.
Centuries later, famous country residences were built of stone brought from Bach's,
Longleet, the residence of the Marquis of Bath, Laycock Abbey near Chipponham,
Bowwood, the seat of the Marquis of Landsdown,
Corsham Court, the home of Lord Methuen, and more modern mansions such as Westonbert and Whitley Court.
The two men who may be considered to be the founders of the great industry that now engages so many of the folk living near the box tunnel were Ralph Allen and John Wood.
Alan came to Bath in 1715 and four years later established a system of buy and cross posts, which was the forerunner of our present postal service.
Seeing the necessity for a good supply of building stone in a neighborhood which had become the fashionable resort of Londoners,
Alan reopened the quarries on Coombe Down and also those on Hampton Down.
He was ably seconded by wood, an architect of high repute, whose genius is stamped on many of the streets, squares, crescents, etc., which still render Bath remarkable,
and at the time when they were built attracted people from the metropolis.
chiefly due to Woods' efforts that Bo Nash succeeded in making the city a pleasure as well as a health
resort. In 1737, Allen built a stately mansion at Pryor Park. The foundations alone consumed 8,000 tons of
bath stone. The superstructure, 30,000 tons. Even to the sash bars of the basement windows,
every external detail was made of the stone. The pile is more than a quarter of a mile long from
wing to wing. Pope, the poet, wrote of it as extremely comfortable, and a contemporary as
a noble seat which sees all bath, and which was built probably for all bath to see. In short,
Alan made a huge fortune out of his post in quarries, and prior park was the outward visible sign of
it. Since Alan's time, the industry has increased enormously on account of the facilities of
transport which the railway affords. It is an interoperable.
fact that the driving of the box tunnel, which was at the time regarded as an act of folly,
led to the discovery of vast stone deposits, which have been mined, until now the hills are
honeycombed with over 60 miles of workings. Speaking generally, bath stone is got from underground
chambers, at its being driven into the deposits. Ulight is found at depths ranging from 100 to 120 feet
below the ground surface, sandwiched in between strata of comparatively useless stone. The seams
ranged from 20 to 30 feet in thickness. The mines, for such they should be termed, rather than quarries,
are of enormous extent. Indeed, there are no similar works in Great Britain which penetrate
so many miles underground, and none in which men enjoy such immunity from bad air and falls.
The box quarries run under the down for miles, and the quarrymen residing in that neighborhood prefer, when the weather is bad, to walk to their work through them rather than over the surface, though they have to light their steps with a small hand lamp.
Year after year, fresh chambers are opened, their position being carefully shown on a large map kept in the manager's office.
A glance at this map will make you wonder how anybody can ever find his way through the maze.
Stories are told of people who have been driven by curiosity to explore abandoned workings,
with the result that they have lost their way and either starve to death or been reduced to extremities
before being found by search parties. And indeed such tales can be easily believed. So far-reaching
are the quarries that a visitor can enter them at box and travel straight ahead till he emerges
at Corsham, miles away, having actually passed over Brunel's tunnel. For a description of the
working methods practiced in the quarries, we are indebted to Mr. T. Sturge Cotterrell, the manager of
the Baoth Stone Firms, Limited. The system generally used is an inversion of that used in coal
mines. The coal miner undercuts the face so that a mass may fall away and break, but building stone
so worked would make a valueless rubbish heap. The freestone miner, therefore, commences operations
above the stone. With the aid of adds-shaped picks to which longer handles are fitted as the work
proceeds, he cuts a deep, horizontal groove eight or nine inches high and extending six to seven feet
back into the rock. It is evident that the removal of this thin layer of material
immediately under the ceiling will disclose any weakness in the roof as effectively as if the stone
had been excavated from ceiling to floor. And any tendency to settle is at once detected and guarded against.
Assuming that the holing has not revealed any signs of danger, the miners now get out their one-handled saws,
insert them at each end of the groove, and cut through the stone vertically and at right angles to the face,
until the first natural horizontal parting is reached.
The block has now been detached on top at each end and below.
At the back it still is solid with a rock.
Levers are driven into the bed or parting at the bottom of the block
and weighted and shaken till it breaks off at the back.
It is then drawn down by crane power,
and the broken end and the bed are dressed with an axe
so as to make the block shapely before loading it on a trolley.
for removal from the chamber.
As soon as one block has been got out,
the workmen can attack others at the back as well with their saws,
so that all farther breaking off is rendered unnecessary.
At each face, or heading of work,
a 10-ton crane is erected in such a position as to command the hole.
These cranes are now constructed telescopically,
so as to accommodate themselves to slight variations in the headings,
arising from differences in the depths of the valuable beds and the expense otherwise attended on frequent alteration of the crane is thus avoided.
After a block of freestone has been loosened in situ, a Lewis bolt is led into its face, and it is drawn out horizontally by the crane.
The removal of the first stratum leaves sufficient space for the workmen to hole out another groove in the new face,
and also to make more vertical cuts down the first face, so that the face soon has a terraced appearance.
Hand-holling has, to a certain extent, been replaced here, as in coal mines, by a mechanical apparatus hailing from America and worked with compressed air.
The star-like head of the picker, striking the face many times a minute, soon pulverizes the stone, which is scraped out with a special scoop.
Of course, large pillars of stone are left to support the roof.
The toughest varieties of stone will withstand a crushing pressure of about 200 tons to the square foot,
or one and a third tons to the square inch.
In the Monks Park and Corsham workings, the stalls or chambers can be driven to a width of 25 to 30 feet without danger of caving.
But in the box ground quarry, the largest save space.
span is limited to 20 feet. The stone blocks, after being detached, are measured and marked. As a rule,
they do not exceed seven tons, though for special purposes, nine to ten tons is attained. Horses are
used to transport the blocks through the tunnels or to the bottom of shafts where a powerful engine
hauls them to the surface. These horses are fine animals as regards both their strength and
intelligence. The miners are proud of their dumb helpers and will give you examples of their knowingness.
A typical yarn is spun of an old leader whose ear told it that a truck approaching from behind
had evidently broken loose and that to stay on the track would mean certain death. The sagacious
animal therefore jumped into a truck nearby, though it must have judged its position by instinct
as the place was pitch dark and thus saved its life.
The stones are stacked in large heaps on the downs from March till September,
have the natural moisture dried out of them and become seasoned to weather changes.
From Corsham and Bach stations, the blocks are sent by rail to all parts of the kingdom
or to seaports where they are put aboard ship for the colonies.
Another famous Ulytic stone, closely resembling the Baoth, is that of the Portland Peninsula in South Dorsetshire.
About half of the peninsula is in the hands of the Baoth stone firms who work over 100 quarries.
The government finds employment for convict labor in other parts of the island, but most of the actual stone getting is done by the free worker.
Nature has behaved kindly in Portland, for the stone lies open to the sky, and is sweetly.
split by fissures, which greatly aid its removal, conducted on the system already described,
except that no holing is required. In 1994, no fewer than 90,000 tons of Portland Stone were sold
by the Baoth Stone firms, a considerable portion of which went to build the new war office in Whitehall.
A member of Parliament asked in the House why the stone necessary for these government contracts
was not obtained by convict labor from government property.
The reply was that if the nation relied on convict labor,
the new war office would not be ready for occupation for a thousand years.
One glance at the convict quarryman, says the Stone Trades Journal,
is sufficient to prove their inefficiency as workmen,
though their labor is anything but light, and industry is everywhere.
But the lack of scientific arrangement,
so absolutely essential in the management of a quarry and the scarcity of necessary plant,
only one crane is visible from the outer world,
render a result totally inadequate to the amount of energy expended,
only small blocks being one,
which are used in the ubiquitous Admiralty works.
The Portlander is born a quarryman and grows a clear-eyed, clear-skinned Hercules.
The heavy manual exertion required makes them,
deliberate in their movements, and from the few accidents that occur in their dangerous occupation,
marks them as careful and intelligent workmen. A curious custom renders these Portlanders vastly
interested in their work. From time immemorial, in the event of a man dying intestate,
his real property was divided equally between his sons. In the event of land being concerned,
it was either literally walled off into the requisite number of strips or an undivided ownership was acquired.
As the stone industry grew, the value of their land increased with leaps and bounds,
with a result that today there are many men working in the quarries and earning, say, two pounds a week,
who are in receipt of royalties amounting from 50 to 100 pounds per annum,
derived from the stone one from their own land.
In the stone yards near the quarries, circular saws, having diamond tips to their teeth, cut up blocks as if they were wood, and lathes and planning machines are always busy.
Every week, 2,000 cubic feet of finished work and 1,000 cubic feet of saw and stone leave the yards.
So great has been the demand for Portland Stone recently that the company has over 1 million feet of stone in store for any emergency,
and constantly adds to it.
There is said to be enough stone on the island
to withstand the drain for centuries.
In fact, the promontory is just one big mass of useful material.
Another stone to which reference should be made in this chapter is granite,
and the mention of granite takes us at once to Aberdeen,
where over 9,000 people find employment in quarrying and shaping this stubborn rock.
The pharaohs used granite freely for their statue,
and temples, but on account of its extreme hardness, it has not been what may be called a popular
stone until quite recently, when the introduction of mechanical tools and improved processes
has rendered its working much more easy than it was formerly. What Allen and Wood were to Bathstone,
John Fife and Alexander MacDonald, have been to granite. Of these, the former, greatly advanced
quarrying methods, the latter, the process,
of dividing and dressing the stone.
The quarries in the Aberdeen district are numerous,
and also those of Peterhead,
whence comes the beautiful red granite,
often seen in company with Aberdeen Gray.
The workings are open-cast,
and somewhat resemble the Carrara quarries.
Here no hand-sawing can be done.
Gunpowder must be used to detach lumps,
the holes for the charges being made by hand-drilling,
or, and this is now becoming the fashion,
by rock drills, which can bore a hole eight feet deep in an hour or so.
The number of holes required depends on the size and the position of the block.
Perhaps two or three suffice, or a dozen may be wanted.
But whatever the number, the blasting must be done carefully
so as not to split the granite into several pieces.
Sometimes two blasts are employed,
the first only partially detaching the granite,
the second finishing the separation.
Of course, the block leaves the face in a rough condition and must be trimmed up.
This is done not with an axe or a chisel, but by splitting along the grain with wedges.
Over the quarry runs a stout steel cable, securely anchored at each end,
and along it travels a carrier driven by a steam engine hauling on an endless rope.
A fall rope, passing over a wheel in the carrier, is lowered into the quarry and made fast to the block,
which has already been moved to a position below the cable by a powerful crane.
At the signal, the engine man starts as machinery,
and the granite cube, weighing perhaps five or six tons,
is swung aloft, one, two, three hundred feet,
until it reaches the carrier and is then drawn horizontally to the bank,
where the material is sorted out and committed to railway truck or wagon.
All sizes of stuff from the largest block,
to mere chips have their use. Waste not want-not is the motto which the quarry master lives up to.
About 10 miles west-northwest of Aberdeen on the River Don is Chemne, where a record blast was made some years ago.
No paltry half-dozen tons were the object of attack, but a regular mountain.
To insert the charges effectively, it was necessary to drive a tunnel right through the mass,
with branches to points on the intended line of cleavage.
Two and a half tons of powder were placed in the berths
and joined up with an electric circuit.
Everybody was ordered to a distance,
and then the man in charge pressed a button.
Bang! The earth shook.
Before the rumbling had died away,
70,000 tons of granite had parted company with the mother rock
and were ready for the soyers and blasters.
This huge mass, when reduced to manageable blocks, furnished loads for 9,000 trucks.
As compared with the handling of bath and other soft stones, the treatment of granite is slow throughout.
It is slow work blasting it, slow work sawing or splitting it, slow work carving it, slow work polishing it.
As for the sawing, a tooth saw would lose its edge in a moment when brought into contact.
with granite, but if you use a band of steel having a smooth edge and keep between it and the
granite a mixture of water and iron sand, the blade will gradually sink down into the block,
a few inches in the hour, though it seldom, if ever, comes into actual contact with a stone
in the bottom of the cut. The chipping of designs is now done largely with pneumatic chisels,
and the rounding of long pillars is performed by lathes.
The cutting tool does not shave off the surface as the pillar revolves, but chips it.
We might describe the polishing of granite,
but as this scarcely falls under the category of mining,
we must pass to our next subject, stones of a much more valuable nature.
End of Chapter 22 of the Romance of Mining.
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The Romance of Mining by Archibald Williams.
The Burma Ruby Mines
The value of the Oriental Ruby, its composition and qualities,
the Burma Ruby Fields,
A Curious Law, annexation by Great Britain,
least by the Burma Ruby Mine's
company. Their engineers' difficulties. Attacks on the Bayon. Spiders Hill. Tagoon Nangang.
A fine stone found. Operation in Moguk Valley. Methods of working. Testing the stones.
Native miners. The ruby shops of Magook. Electric power. Troubles from inundations.
We have already mentioned the fact that the Oriental ruby is more valuable than the diamond,
weight for weight. Mr. Edwin Streeter, an expert in such matters,
affirms that a ruby, weighing five carrots, is worth ten times more than a five-carat at diamond,
and that the proportion grows rapidly in favor of the ruby with an increase of weight.
Casting about for actual figures, we find that an eleven-carat ruby sold in London a few years ago,
fetch 7,000 pounds, whereas a diamond of 11 carots would not, according to ordinary
reckonings, be worth more than 1,000 pounds at the utmost.
Footnote.
The value of a cut diamond is roughly reckoned by assuming one carrot to be worth 8 pounds,
and multiplying this by the square of the number of carrots that the gem weighs.
Thus, an 11-carat diamond equals 8 pounds times 11 times 11, equals 9.
968 pounds. In footnote. The Oriental ruby is a variety of the substance called
Karundum, which is chemically known as an oxide of aluminum. It is interesting to notice
that while the oxide is so rare and valuable, silicate of aluminum forms the basis of all
clays and that the sulfate is familiar as alum. When tinged with blue, Kerundum is named
sapphire, with yellow oriental topaz.
with green oriental emerald,
with purple oriental amethyst.
The adjective makes all the difference.
The ordinary emerald, for instance,
has as its basis silica, an oxide of silicon.
And the ordinary amethyst is also silica,
colored by oxide of manganese.
Apart from its value, the true oriental ruby
is interesting on account of its extreme hardness,
which yields only to that of the diamond,
and sometimes to that of the sapphire,
and also because it is found in very few places.
In fact, nearly all the rubies ever mined come from a comparatively small district in Upper Burma,
round Magoch, 70 miles north of Mandalay.
The rubies are occasionally found in Australia, Borneo, and Afghanistan.
They are too few to affect the trade.
Little is known of the early history of the Burma ruby industry.
It is said that Mogok and the neighboring village of Kajai,
at Pien were obtained in 1595 from a shan ruler in exchange for the town of Tagong on the Irrawaddy.
Until 1885, that is for nearly three centuries, the ruby ground was owned by the Burmese kings,
who had such a liking for the pigeon blood-colored stones that the possession by a private
individual of a ruby worth more than 70 pounds was a crime, since any gem of that value
was considered to belong to the crown.
The obvious thing happened, that anyone who found a big stone probably broke it up and sold it as several separate jewels.
To prevent rubies going out of the country, the ruby fields were forbidden ground to Europeans.
In 1885, Great Britain annexed Upper Burma, and the right of working the ruby grounds in the Moghuk region,
not already occupied, was granted to Monsieur Streeter and Company at a rent of 26,66 pounds a year,
plus 16.66% of the net profits.
They subsequently handed over their concession
to the present Burma Ruby Mines Company,
who held their lease from the government till 1932.
The area of the stone tract is 400 square miles,
which sounds a very fine slice of territory.
But when the company's chief engineer arrived at Mogok,
he found that the pick of the country, i.e. in the valleys,
was already occupied,
and that he would have to confine his operations to the jungle-covered hillsides
without any indication of good ground to guide him.
The labor supply was altogether inadequate,
and the only means of communication with the outer world
was a cart road 60 miles long leading to the Irrawaddy.
In bad weather, the road was a swamp.
Of houses fit for Europeans, there were none.
The company proceeded to buy out the valley owners.
Even then, the water difficulties were such as to make them abandon the Moguk Valley altogether
and try their luck again at the Cayet Pin Valley eight miles distant.
In the middle of this rises a conical peak with a Burmese name signifying the hill of spiders.
Long-legged spinners have been associated with gold, and perhaps their presence is considered
a good omen for the gemseeker also.
At any rate, local tradition held that in the earth-filling the hills,
hillside caves, there existed the pigeon-blood ruby more abundantly than anywhere else.
Vigorous efforts were made to get to the bion or ruby ground in the caves and under the slopes
at the base of the hill. It was even hoped that excavation might reveal a ruby-bearing volcanic
pipe similar to those which contained the famous diamond blue ground at Kimberley.
By a curious stroke of luck, the very first day's washing yielded a splendid stone, the only good one
found there. The spider hill workings were in many cases tunnels driven into the hillside.
This method of extractive bion didn't pay, as the actual number of miners was limited by the size
of the heading. It was therefore determined to try washing over large masses of ground in a valley,
that of Tegun Nindang, what a terrible name, being selected. Power to work the pumps in the
washer was supplied by a water wheel put half a mile off and transmitted to the mine by an endless
wire rope, according to the system then largely used in Switzerland. The results were quite satisfactory,
for in addition to a steady output of small stones, the most valuable gem that has yet rewarded the
company, a fine stone weighing 18 and a half carrots in the rough, and 11 carats when cut, was exhumed.
Unfortunately, the deposit soon gave out and the machinery had to be moved again, this time back
to the Moguk Valley. Here, in a strip about two miles long and three furlongs broad,
the ruby miners are now hard at work. The chief mines are the Shubantha and Redhill at the north end,
and the Jung Zone at the south. Operations began in April 1894, since which date several
millions of truckloads of ground have been washed over. The method of working, the engineers hardly claim
for the name of system is this. First of all, a pit is sunk, 10 feet square and 25 feet deep,
and a centrifugal pump is placed in it. The ground all round is then gradually loaded into trucks
and hauled away to the washer. Any water encountered being led into the pit from which the pump removes
it. This process continues until the level of the mine reaches the bottom of the pumping pit,
or the quantity of water exceeds the capacity of the pump, in which case it becomes necessary
to sink the pit further and increase the pumping power.
The workmen are Chinese Shans, called Tayyoks, or Mangthas,
who dress themselves in blue jackets and trousers and live on rice, dried fish,
salt pork, tea, and opium.
The drug is said to be a necessity, for without it they go to pieces,
though when supplied they are good and willing workers.
These men lo the bione into trucks,
which are hitched onto an endless rope drawn up a slope
and tipped into the screens through which,
after being well shaken and disintegrated, it passes into the washing pans 14 feet in diameter.
Rows of steel teeth set in revolving drums, churn up the clay mass. The clay and lighter gravel run off
into a safety pan, and the heavier gravel containing the precious stones is left behind,
about 1% of the original contents of the washer. At the end of each shift, a door in the pan,
bottom is opened, and the deposit falls into trucks with covers, which are locked until the
sorders are ready to treat the loads. The sorters tip the deposit into a large bin,
also locked from which it slowly dribbles into a revolving screen covered with different sizes of meshing.
The sand is eliminated at once, and the clean deposit falls through in five sizes,
the largest direct on to a sorting table, the other four into a pulsator, which further
separates the heavier from the lighter stuff. No natives are allowed to handle the larger sizes.
The temptation might be too strong for their morals, and the English sorters conduct the next
operation of working the stuff round and round in a sieve immersed in a tub of water till the rubies
have gravitated to the bottom. The sieve is then smartly turned upside down on a table,
so that the rubies are at the top and can be picked out by hand. Every afternoon the day's
find is taken to the office where the inferior and worthless stones are handed over to the agent.
early next morning he sorts the largest stones himself and watches while Berman
Helpers sort the rest into 14 qualities. The best stones go to the London market. The worst are
sold by auction once a fortnight to local dealers. These are natural gamblers and will run up
prices if, say they think that a lump of red curundum may have a valuable center. Most
probably it has not, but the chance makes them bid heavily against one another. In the
The ruby ground are found spinels, which both in color and general appearance, closely resemble the true ruby.
The best method of testing is to put the jewels under dichrooscope, where the ruby shows two distinct colors if viewed from different directions,
whereas a spinel and garnet show the same color.
Besides the company, there are the native miners who have to pay the company a royalty of 20 rupees a month for every man they employ.
The company keep up a staff of English inspectors
to see that they do not work with more men than licenses have been paid for.
The natives cannot, of course, go to the expense of pumps and patent washers,
yet they manage to extract the stones very thoroughly.
They either sink a pit into the bion or follow it up through the crevices in the rock
and bring the dirt to the surface to be washed in small basket folds and picked over by hand.
A third method is to turn small hill streams on a deposit of
buy-own and wash it down the hillside into a sort of long tom, which holds the heavier constituents,
but allows the rubbish to pass through. Half the houses in Magog are shops, where these traders may
be seen squatting round a metal plate on which the stones for sale are displayed, haggling over prices.
There is also a regular stone market outside the town. The rainfall in this region is terrific.
Twenty-five inches have been registered in four days in the valley. On the hill,
hills, the precipitation was probably heavier. With great open pits to be kept free from the results
of such deluges, the engineers often find themselves in a difficulty, and it has been decided to drive
a drainage tunnel through the hill on one side of the Muguk Valley, which will not only curb the river
flowing through, but also empty the water from the mines by gravity. The tunnel will be over a mile
long and have a section of seven by seven feet. The water has, however, it's usually,
A dam has been built across the valley some distance below the town to impound a lake which
is led through stone channels and pipes to the powerhouse, where three electric generators
develop some hundred horsepower. On one occasion, a land strip carried away the channel and piping,
and by stopping the generators through the mine pumps out of action, so that the mines gradually
filled with water. To prevent the recurrence of such a disaster, the open channel has been replaced
by a tunnel driven through the solid rock. In addition to this electrically transmitted water power,
the company have a good deal of high pressure water laid on direct to the machines.
In the hills surrounding Moguk Valley, ditches have been cut, starting from a mountain torrent,
and running along the hillside for miles till they reach the pipelines which lead the water down
to its work. Some ditches are the company's own construction. Others have been bought from
native owners who show great ingenuity in contouring the grade round the hills, and who expect
a good price for their water rights. Several rich valley deposits have not been touched as yet,
and even when they have been worked over, there will still remain the hillsides which are
a fit subject for hydrolycing in the manner already described in our chapter on California.
End of Chapter 22
Chapter 23 of The Romance of Mining
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Recording by Avayi in January, 2003.
The Romance of Mining by Archibald Williams.
Chapter 23.
Salt Mines
Salt
Its value as a dietic
And distribution.
Rock salt
Rine Springs
The salt industry in Cheshire, Staffordshire and Worcestershire.
The salt mines of Vilichka,
a subterranean city,
art and industry combined.
The day's work.
Searching the miners for salt.
The wonders of the mine.
The Lito Ballroom.
Salt Chapel.
A vast chamber.
A railway station
in the depths.
A saline sticks.
The salt plains of Colorado.
Plowing the salt.
A fine sight.
The only mineral which figures in man's ordinary diet is salt.
Almost from the earliest times of which we have any record,
the value of salt as a seasoning and digestive
has been very distinctly recognized.
Though man can live without salt,
an instinct tells him to,
to use it with certain kinds of food, and many species of animal also evints a passionate appetite
for chloride of sodium. This substance is, fortunately, very widely distributed. To begin with,
the ocean is strongly impregnated with it, and on any seashore a supply may be easily obtained
by evaporation. Many extensive deserts testify by their salt deposits to a time when the sea
once covered them. But the most important source of salt is undoubtedly the rock-like strata,
which are found in many countries, sometimes outcropping as large hills of salt, sometimes
sandwiched in between strata of all geological ages, except the earliest. It is curious that
bitumen, coal and petroleum often occur in proximity to salt, and some scientists go so far as to
suppose that salt plays a part in the formation of the last.
England is the chief salt-producing country, and Cheshire, Staffordshire and Worcestershire
are the counties where the largest deposits occur, Cheshire taking first place.
Droitwich in Cheshire has been celebrated for its witches or salt springs ever since the
Roman occupation, and the word Salary, Latin Salarium, is due to the fact that salt
was made a part of the Roman soldiers pay.
Salt has been made in England from natural brine springs for centuries,
but the mining of the rock salt deposits,
through which water must flow to become thus impregnated,
is a comparatively modern industry in these islands.
The Cheshire beds were discovered in 1670 by men boring for coal
and have been mined ever since.
The salt is sometimes so hard that it has to be blasted with gunpowdered.
By far the largest proportion of English salt is the result of evaporating brine that has been pumped up from the surface of the rock salt strata through large boreholes specially made.
About this system, there is nothing at all romantic.
The brine is merely poured into large open pans or tanks heated beneath by furnaces,
and the water is driven off until salt forms by precipitation and can be drawn to the sun.
sides. If natural percolation is not sufficient to keep the brine wells filled with water,
large quantities are poured down through boreholes. About two million tons of salt are produced
yearly in England, Cheshire being responsible for more than three quarters of the total. The effects
of the industry are very visible at Northwich and Winsford, where houses and chimney stacks
are so far out of the perpendicular, and the country so indented by the
depressions, often filled with water, that a visitor might easily imagine that an earthquake had passed that way.
The settling of the surface and of whatever it carries is due to the constant removal of the salt down below,
just as in coal districts the land overlying a bed sometimes sinks when the props or pillars in the workings give way.
Vast as are the English deposits, they must yield the palm for extent, if not for,
productiveness to those of Villalitschka in Galicia, about 90 miles from Krakow,
which are deservedly the most famous in the world. In this region, there is a mass of salt
which is estimated to measure 500 miles in length, 20 miles in breadth, and 1,200 feet in
thickness. Villelichka is the chief point of attack on this prodigious bulk. For nearly 800 years,
men have been hacking at the salt, and their labors have left a veritable underground city,
which is one of the showplaces of Europe, often visited by royalty itself.
As preface to a short account of these wonderful mines, we should mention that they are the
property of, and are controlled by, the Austrian government, which derives no mean revenue
from the sale of the salt. In a coal, iron, silver, lead, copper, or, and, and, and,
or a mercury mine, you may see many strange and curious sights,
but none to compare with those of Villalichka.
The material which surrounds the visitor is eminently suited to fine effects,
when illumined by electricity or candles,
white salt sparkling with the prismatic hues of light from countless tiny facets.
Recognizing that a commercial undertaking could here be combined with magnificent artistic effects,
The workers in these depths have, while removing some of the mineral, so decorated the face of what remains, that now one may travel through and past chapels, altars, ballrooms, pillars, and thrones, all hewn from the solid rock salt.
Salt staircases lead you from one floor to another. Chandeliers of salt hang from the roof. Statues of salt adorn the walls. Everywhere is salt, so skillfully should be able to be.
shaped as to prove that the artistic feeling must be strong among the miners.
The mines have a length of about two, three-quarter miles along the bed, and there are eight levels.
In the topmost three are the sites which tourists crouch to see.
Down below, the premises are for business only.
Though it has been asserted that people have been born and have lived all their lives in this
subterranean city, there is no foundation for such a statement, unless, indeed, the writer has
become confused between humans and horses, which last certainly do spend the whole of their
lives from birth to death far removed from the daylight. We may turn our attention first to the work
of the mines, which is conducted by about 1,000 miners. Working eight hours a day, they raise between
them some 60 to 70,000 tons of salt per annum, quarrying it out from immense chambers,
which are carefully supported with timber work in the roof. The chambers are duly named in
honor of some well-known person and act as storehouses in which to keep the salt until it can
be drawn by rail to the central raising shaft of the mine. Such care is exercised in the excavations
that accidents are very rare, though in the annals,
of Villelichka, there are recorded some terrible disasters, resulting from fire or the flooding
of the mine by a subterranean lake. On account of the whiteness of everything around,
the galleries are much more effectively illumined by the miners' lamps than the workings of a coal mine,
and the air is kept very pure by its contact with the mineral, so that both men and animals
enjoy good health. At the end of the day, the miners' assessment,
send to the surface in lifts, and when all are up, the shafts are locked.
One would hardly think that salt is a commodity worth stealing, or that, if stolen,
the authorities would object to the theft of a mere pinch from an inexhaustible deposit.
But salt is a taxable commodity, and it appears that at one time so much of it was smuggled
out in boots and pockets that every man was searched when leaving work as if he were an
employee in a diamond or gold mine. The practice is still continued, though in a perfunctory way,
as the miners are too well paid to care about augmenting their income dishonestly.
Now for the workers of the mine. Near the entrance stands a block of buildings, the offices of the
manager, where visitors are kindly provided with overalls suited to the exploration of the
caves below. The outfits worn by royalty are carefully laid.
labeled with the name of the wearer and the date of the visit.
You can descend either in an hydraulic lift
or by a staircase hewn out in the salt.
When the stranger reaches the mine,
their bursts open his view a little world,
the beauty of which is scarcely to be imagined.
He beholds a spacious plain containing a kind of subterranean city
with houses and roads,
all scooped out of one vast rock of salt,
as bright and glittering as crystal,
while the blaze of the lights continually burning for the general use
is reflected from the dazzling columns
which support the lofty arched vaults of the mine,
which are beautifully tinged with all the colors of the rainbow
and sparkle with the luster of precious stones,
affording a more splendid and fairy-like aspect
than anything above ground can possibly exhibit.
The illumination for spectacular purposes,
the buy is carried out by the authorities on a specified scale, ranging from five pounds,
ten shillings downwards. For the highest figure, all the electric lamps and candles in the
mine are lit, and fireworks are let off to show the remoter corners. The first level is 216 feet
below the surface. It contains the famous Leto ballroom, excavated 150 years ago, where many
festive gatherings, presided over by the Emperor, have been held. One end of the room is adorned
with a colossal Austrian eagle, and with transparencies painted on slaps of salt. In an alcove at the
other end of the room stands a throne of green, the crystals of which flash a green and ruby red.
It is on this that the Emperor sits when he comes to the mines. Even older than the ballroom
is St. Anthony's Chapel,
close by, which dates from
1698, and may be
considered the religious center of
the mines. It is reputed
to be the work of a single miner
who has beautified it with many
fine carvings, all executed
in salt. Services
are held regularly in the chapel,
and on the 3rd of July
there is a special mass,
attended by many people,
who flock in from near and far.
There are other shrines and
chapels, the finest being the queens, which, in addition to the splendid altar of salt,
exhibits on one wall a view of Bethlehem, also worked in salt, while overhead hangs an elaborate
salt chandelier. In the second level is the Mikhailovits chamber, 59 feet long, 92 feet wide,
and 118 feet high, which has remarkable acoustic properties. The third floor contains a railway's
station where the 25 miles of the mine tracks converge, and also a restaurant for the refreshment
of visitors and workers. To quote the words of Mr. James W. Smith, who was responsible for the
interesting description of the mines in the Strand magazine, which has already been laid under
contribution, five or six tables on one side of the line are often crowded with diners and
drinkers of beer, who seem thoroughly to enjoy themselves under the hundred lights scattered
over the front of the station. Several massive chandeliers of salt try to outweigh in brilliancy
the glow of the illumination from these incandescent lights. In some respects, this scene,
with its busy waiting crowd, its converging rails, its twinkling lights, and the rumble
of the train and the tunnel nearby, recalls the impression which one gets while
standing at an English railway station on a moonless starlit night.
As a contrast to the ballrooms, chapels and station, there is a subterranean lake,
navigated by a boat hauled along on a rope. In fact, there are 16 lakes, but only one is
included among the lions. Almost as remarkable as the Vyelitska mines, though in quite a
different fashion, is the wonderful salt farm on the Colorado.
River, where 1,000 acres of solid salt are plowed, hoed and piled up as if it were mere earth.
It occupies a depression in the midst of the Colorado desert just north of the boundary line
separating California from Mexico. This dip is 264 feet below sea level, and in it,
salt has been deposited by the evaporation of saline water in past ages. About 13 years ago,
river overflowed its banks,
dissolved the salt scattered in the
depression, and when the water
had evaporated, there lay in the
bottom of the basin a blindingly
white sheet of the mineral.
So intense was the glare from
it that no person could venture
onto it unless equipped
with deeply colored glasses.
Its value
being obvious, a company
was formed to work the deposit.
Never was salt more easily
got. All that one
had to do was to draw plows over the surface to loosen the salt, which could then be collected
into heaps and carted away as soon as all moisture had been dried out by the sun. A special plow
was devised for the industry, a machine mounted on four wheels with a heavy beak which cuts into
the salt and piles it on either side of the track in two long ridges. It is pulled backwards and forwards
by a rope operated by a steam engine.
So intense is the heat that Europeans cannot endure it,
and Indians or Japanese have to be employed.
Even they suffer from optic inflammation,
despite their coloured glasses,
and also from a perpetual thirst,
induced no doubt by the saline particles of which the air is full.
The deposit has a thickness varying from one to eight inches,
In places, springs underlie the crust,
but they are so impregnated with salt
that they cannot dissolve any more,
and therefore give little trouble.
No sooner has a crust been removed by the plough,
then another begins to form,
so that at present it appears as if the supply of salt were inexhaustible.
When thoroughly dry, the heaps are put on trucks
and transferred to the meals at Salton,
which grind the mineral into a fine powder,
and otherwise prepare it for market, either as a table salt or for commercial purposes.
Though painfully brilliant during the daytime, the salt fields is a thing to be visited for its
spectacular effects. A moonlit night should be chosen. Then the spectacle is weirdly magnificent.
The rose of glistening pyramids, the glitter of the moonlight from the facets of millions of crystals,
The distant background of low black hills, the expanse and stillness of the shadowless plain,
strike one with awe and wonder that can never be forgotten.
End of Chapter 23
Chapter 24 of The Romance of Mining
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The Romance of Mining by Archibald Williams, sulfur mining.
The uses of sulfur, its occurrence, the sulfur deposits of Sicily,
Papa Catapetal, a romantic incident, a perilous adventure,
Signor Corchado explores the crater, the miners at work,
mountains of sulfur in Japanese territory, its exploitation and removal,
Grim Surroundings
Sulfur can hardly be termed an article of diet,
though in combination with treacle,
it is considered wholesome fare for children,
if taken in small quantities.
You may remember the dramatic episode recorded by Dickens
in connection with the Dothboys Hall,
when Wackford Squeers, Jr.,
was stood on his head in a large bowl of the mixture
by the infuriated victims of a bill of fare
in which brimstone and treacle played two prominent apart.
Sulfur has a medicinal value, undoubtedly,
but its chief uses are for the manufacture of gunpowder and sulfuric acid,
and for the volcanization of India rubber.
It occurs chiefly, one, as natural sulfur, almost pure in the craters of volcanoes,
two, intermingled with earth and rock, three, in combination with metals.
We have already referred to the sulfides of mercury, silver, lead, and iron, from the last of which, iron pyrrites, sulfur can be extracted in commercial quantities.
At present, the great sulfur beds of Sicily yield the largest part of the world's supply.
These are of volcanic origin.
The sulfur mines of Catania, Gergenti, Palermo, and Caltanocetia give employment to some 30,000 people and yield
about 400,000 tons of sulfur a year.
A network of galleries is driven through the deposits
and great chambers are hollowed out,
often 100 feet high,
central pillars being left for support.
The ore is placed in stone-lined pits,
having a sloping floor,
covered up with rubbish, and lit at the top.
The combustion of part of the sulfur
produces sufficient heat to melt out the rest,
which accumulates on the floor,
and is drawn off into molds holding about a hundredweight each.
By this primitive method, the ore is made to yield from 10 to 20 percent by weight of sulfur,
according to quality.
The neighborhood of the kilns is to be avoided,
as it is even less pleasant than the calcining district of the Rio Tinto.
There is probably no more extraordinary mine in the world
than that worked for sulfur in the crater of Papacatapaget.
metal, 18,000 feet above sea level.
Nearly 400 years ago, a party of Cortez's followers,
headed by Francisco Montano, made the terrible ascent
to the crater in search of sulfur for the manufacture of gunpowder,
as the supplies brought from Europe were exhausted.
The Spaniards, five in number, climbed to the very edge of the crater,
which presented an irregular ellipse at its mouth,
more than a league in circumference.
Its depth might be from 800 to a thousand feet.
A lurid flame burned gloomily at the bottom,
sending up a sulfurous steam, which, cooling as it rose,
was precipitated on the sides of the cavity.
The party cast lots, and it fell to Montano himself
to descend in a basket into this hideous abyss,
into which he was lowered by his companions to the depth of 400 feet.
This was repeated several times,
till the adventurous cavalier had collected a sufficient quantity of sulfur for the wants of the army.
This doughty enterprise excited general admiration at the time.
Cortez concludes his report of it to the Emperor of Spain,
with the judicious reflection that it would be less inconvenient on the whole
to import their powder from Spain.
But sulfur is scarce in Mexico,
and the idea of robbing Papa Catapedal's deposits was fascinating.
Indians used to descend with baskets and gather small quantities, for which they found a ready sail.
In 1850, a Signor Corchado thought that a regular mine might be established in the crater,
and accompanied by some Indians, and armed with an iron bar, ropes, and some sailcloth,
undertook an expedition to the summit.
The ascent was so toilsome that only Corchado, and one Indian reached the top,
where the former fainted through loss of blood and fatigue,
the Indian, being unskilled in first aid,
covered him up with the sailcloth and started down the mountain to get assistance.
Meanwhile, Corchado revived and crawled a little way down the wall of the crater
to escape the intense cold of the snowy slopes.
The heat so revived him that he brought down the bar, sailcloth, and rope,
with the intention of exploring the horizontal or bottom of the
crater, and while he was engaged in fixing up his apparatus, the relief party arrived.
Some scory was collected and taken down to Puebla, where an analysis showed so large a
percentage of sulfur that the crater was denounced as a mine. Capital, having been raised,
a rough tackle was rigged up for the use of workmen and the hoisting of the mineral.
Mr. R. A. Wilson, in his Mexico, gives the following short account of a.
descent, which is sufficiently interesting to quote.
We followed a narrow footpath until we reached a shelf, where we were seated in a skid,
and lit down by a windless 500 feet or so, to a landing place, from which we clambered downward
to a second windlass and a second skid, which was the most fearful of all, because we were
dangling about without anything to steady ourselves.
As we descended before the mouth of one of those yawning caverns, which are
called the breathing holes of the crater. They are so-called from the fresh air and horrid sounds
that continually issue from them. But we shut our eyes and clung fast to the rope as we whirled round
and round in mid-air until we reached another landing place around 500 feet lower. From that point
we clambered down as best we could until we came among the men digging up cinders, from which
sulfur in the form of brimstone is made.
The cinder deposits have been pretty well worked out by General Ochoa, who took over the mine,
but sulfur is continually forming around these sulfataras, or vents, of which there is a large
number. Labor is somewhat difficult to obtain, as the working conditions are far from pleasant,
though there is no special mortality among the men who work in gangs, weak and weak about,
and camp in rough sheds in the crater.
When a storm or earthquake occurs, their position is uncomfortable,
but rendered tolerable by a judicious supply of spirits
and leaves of the coca plant,
which enable the chewer to undergo great fatigue.
In spite of the physical difficulties attending it,
the Papa Catapadal sulfur industry flourishes,
or at least did so until quite recently.
And if the proprietor still makes a good profit
he certainly deserves it. Another interesting sulfur region is situated in the realms of the
Mikado, on a little island halfway between the most northern point of the Japanese mainland
and the southernmost point of Kamchatka. The island, named Itrofu, contains three volcanic
mountains, about 3,000 feet high, of almost pure sulfur. Volcanic vapors pouring through
countless fissures in the ground as well as from the craters are perpetual.
increasing the deposits, which have been calculated to total over 2 million tons of pure mineral.
Early in May 1898, some enterprising Japanese prospectors suggested to a firm of American
engineers who had their headquarters at Yokohama that they should join forces to mine this vast
accumulation of valuable material. Concessions were got from the Japanese government of several
square miles, including this the most extensive sulfur deposit in the world, and a preliminary
survey of the locality was made. The island lies off the regular ocean routes, and is so far north
that its coasts are icebound for half the year. A surveying party, accompanied by Japanese
engineers and a guide, sailed from Yokohama to Mooro Bay near the volcanoes, and after suffering
great privations discovered that the immense sulfur cones lay about two miles from the coast,
though fortunately there was a natural decline leading gently down from the mountains to the excellent
anchorage of Moyoro. This being so, the transport of sulfur from the deposits to ships
could easily be affected by means of a cableway carried on large trestles. As soon as the winter
snows had melted in 1890, Mr. E.W. Fray's,
A New York engineer arrived in Itrofu, with a large gang of Japanese laborers, tools,
timber, wire, rope, and other supplies to exploit the property in the interests of the company
formed with Japanese and American capital. Five months of hard work saw the completion
of a rope transmission plant from the base of the sulfur cones to the sea level and of buildings
to house men and material.
The next year, the plant was put in full working order.
The yellow crystals were dug out of the hill
and shoveled into iron buckets,
suspended at intervals of 300 feet from the cableway,
which ran down to the sea on one side of the trestles,
and back again on the other,
so as to form an endless rope.
The weight of the full buckets keeps the rope in motion,
the empty buckets being returned on the uptrack
by the descent of the full ones.
The speed of travel can be regulated by friction brakes,
acting on a drum round which the cable passes in the upper terminus.
In the course of five months,
10,000 tons of sulfur were mined and transported to sea level,
and 6,000 tons were shipped to the refinery at Hakodate, Japan.
The quantities mined annually have since increased,
but it will take many years to approach even appreciating,
the exhaustion of the supply which nature has so generously included within the domain of the chrysanthemum.
Sterility and desolation are distinguishing features of a neighborhood where sulfur abounds.
The fumes utterly destroy vegetable life.
We have already had a picture of a sulfur inferno,
but the following short description from the pen of Mr. William H. Crawford is interesting
and therefore may be fittingly reproduced.
The writer's first view of the deposits,
after a long and tedious trip,
showed clouds of steam pouring from several places
near the summits of the hills,
and far down along the sides
glistened immense patches of dull yellow,
which were occasionally lost to sight,
as a fickle breeze wafted the vapors
in such a way that the brighter yellow sulfur
of the summit could be seen.
On climbing to the top, the hills were found to consist of almost pure sulfur,
inasmuch as diggings at every conceivable place brought up the yellow crystals.
The sulfurous vapors which poured from subterranean depths were suffocating,
and instead of issuing from only a few places, as it seemed, when viewed from a distance,
the whole cap of each hill was really honeycombed,
and each outlet was continually adding to the stock of the whole, day by day.
as the vapors were condensed.
End of Chapter 24, read by Will Caffey, Oregon, December 2022.
Chapter 25 of The Romance of Mining.
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Romance of Mining by Archibald Williams
The Perils of Mining
dangers incurred by the miner.
Fire, falls, poisonous gases and disease,
falls, safety catches for cages,
fire damp, choke damp, white damp,
ventilation, the surest safeguard,
the safety lamp,
Electric lamps. The Wats Town Disaster.
120 lives lost. Other notable disasters.
Extraordinary endurance of entombed persons.
John Brown. Joe. The Snaefell Lead Mine Disaster.
A dramatic account of the effects of white damp.
How wearisome and painful the life of a miner is at best.
Only those who have earned their bread in underground prisons can know.
From the most ancient times, writes Gamboa,
the toils of the mine have served as a punishment for slaves,
a torment for martyrs, and a means of revenge for tyrants.
According to the grave description of Plautus,
mining is attended with every pain that hell can inflict,
and, indeed, that poet considers the torments of hell less insufferable.
The Crown Laws of Spain appointed the raising of ore as an appropriate punishment for vagabonds,
being an occupation of incessant labor, and continually exposed to imminent risks,
in view of which it is said that the Belgians named a mine shaft La Fos,
the grave intentionally, and in Cornwall, the old open workings on a load were called
coffins if Simonin's record is to be trusted. The conditions under which mining, taken as a whole,
are now conducted, are such as to render some of the above words inapplicable to the modern
industry. Only in a very few parts of the globe are criminals condemned to drag out their lives
in subterranean prisons urged by the lash of brutal taskmasters. The abuses which once made
the coal mines notorious have been swept away, and in all kinds of mines, rules and regulations
safeguard the health and life of the miner.
There still remain, nevertheless, a sufficiency of dangers to render the miners calling a distinctly hazardous one.
The coal miner, in particular, runs daily risks, for, in addition to the falling roof, the inrush of water, the overwound cage, the broken rope, and the premature explosion of blasting charge, he incurs the fearful,
peril of asphyxiation and fire.
We must further remark that, besides the more sudden and dramatic calamities, which may
overtake the minor, he is subject to the subtle but no less deadly attacks of disease,
pneumonia arising from sudden changes of temperature, consumption caused by inhaling dust,
and miners worm, a disorder of the intestines.
The falling in of the roof of a mine can be prevented only by the greatest care in leaving
proper pillars or by a system of strong timbering.
The science of roof staying is now so well understood that few extensive disasters occur from premature caving in.
Generally, a fall is heralded by unmistakable signs,
cracking in the roof, the flaking off of small pieces, the bulging of pillars and timbers,
which give the men fair warning.
When a fall does take place, its effects are not limited to the area immediately underneath.
For the sudden expulsion of air through the galleries has been,
known to lift cars from the track and smash them against the walls, and even to sweep away
the timbering of the galleries. A case is recorded in which a man was sitting at the entrance
to a level eating his dinner when a fall occurred in a distant chamber. The air rush caught him
and dashed him so violently against the wall of coal close by that he was killed on.
the spot. We seldom hear nowadays of a cage falling down a shaft, for not only are the steel hoisting
ropes very durable and trustworthy, but every cage is also provided with a safety catch,
which, in case of the rope breaking, comes into action and jams its teeth into the cage
guides. The most deadly foes of the coal miner, in particular,
are the gases given off by coal.
Betuminous coal gives off carbureated hydrogen or marsh gas, CH4.
The result of vegetable decomposition underwater.
Some of this gas was imprisoned during the formation of the coal
and being under high pressure is ready to escape
when a miner opens a crevice in which it has collected.
Sometimes a large body of gas is suddenly tapped and rushes out into the workings.
Being only half as heavy as air, it naturally rises to the roof,
and when mixed with from 4 to 12 times its volume of atmospheric air becomes highly explosive.
Should it then come into contact with a naked light,
the effects are fearful, almost comparable with those of gunpowder.
A terrible flood of fire rushes through the galleries, scorching and igniting anything it meets.
A loud report at the pit head, accompanied by smoke and flying fragments, tells those above that a
pitiable disaster has overtaken those below.
The fire damp, as the carbureated hydrogen is called by the miners, leaves a deadly residue behind it,
choke damp or carbonic acid gas. The product of combustion, which, being heavier than air,
sinks to the bottom of the levels and galleries, and speedily suffocates any living thing it encounters.
The miners may escape the actual expectancy. The miners may escape the actual expanse.
by flinging themselves on their faces while the conflagration rushes overhead.
But unless they are soon on their feet and manage to reach a part of the mine not swept by the flames,
the choke damp will claim them as victims.
A third gas, carbon monoxide, or white damp, is even more fatal than choke or black damp.
It is the result of imperfect combustion.
Even if it does not kill on the spot, it has more or less permanent effects on a person who has inhaled it,
as it is most difficult to expel from the system.
The best safeguard against explosions and suffocations is continuous ventilation of all workings.
In old times, a minor,
called the penitent, on account of the resemblance of his dress to that of a cowled monk,
was sent through the workings of some mines, after the other miners had finished their day's labor,
armed with a lighted taper to ignite any small bodies of fire damp that might have accumulated during the day.
Sometimes he met a dangerously large volume, with results fatal to himself,
so that the office of penitent or firemen required a brave man to fill it.
Before ventilating machinery and methods were sufficiently perfect to thoroughly scour the mines,
the safety lamp, invented by Sir Humphrey Davy and George Stevenson,
was of prime importance, and even now is the only form of lamp used in many months,
used in many minds.
The flame is encased with a wire gauze cylinder,
having 784 apertures or meshes to the square inch.
Under ordinary conditions,
flame will not pass through a gauze of this kind
as the heat of gas burning on one side
is rapidly dissipated by the wire.
The presence of a small percentage of fire damp
is shown by the behavior of the flame, which becomes smoky.
If the percentage is high, the cylinder becomes full of a pale blue flame,
and the lamp grows so hot that it must be removed beyond the gas zone as quickly as possible.
In spite of this useful invention, many disastrous explosions have occurred,
generally through carelessness on the part of a miner who opens his lamp to light a pipe or another lamp that has gone out.
Constant association with danger makes men reckless and ready to take the chance.
Footnote.
Faraday once watched the preparations for a blast being made in a mine
by the light of a candle stuck in a lump of clay on the floor
close to a sack.
Where's your gunpowder? he asked.
That be it your sitting again, replied the man, pointing to the sack in question.
End of footnote.
Even if the lamps are pat-locked, someone may have a key that fits them.
In some minds, therefore, a magnetic lock is fitted,
consisting of an iron plunger forced into a recess by a recess by a
strong spring, locking the two parts of the lamp together. The lamp can be unlocked only by placing
the lamp over a powerful electromagnet, kept at the lamp station, which overcomes the force of the
spring and draws down the plunger. Electric devices are also used for lighting the lamp
without reopening it.
In the future, the oil lamp will doubtless be replaced by the electric portable lamp
supplied with current from a small accumulator or a primary cell forming part of the apparatus.
Accumulator or secondary battery lamps are popular on the continent
and have been introduced into some Durham collieries.
The objection alleged against them is that they do not give warning of fire or choke damp,
being quite independent of the outer atmosphere.
Whether this is a reasonable objection may be doubted,
yet it was in a mine of which the galleries are lit by electricity,
the Watson Coler, in the Ronda Valley, Gladmorgenshire,
that one of the most terrible mining disasters of recent,
years occurred. At 12.30 p.m. on Wednesday, July 12, 1905, a tremendous explosion in the upcast
shaft through the village of Watstown into a panic. The sound was compared to that of the discharge
of a park of artillery, and its force was such as to break windows in houses hundreds of yards away. At
the time,
121 men,
including the manager of the mine,
Mr. W. Meredith,
were at work in number one pit,
the upcast,
and nearly 1,000 in number 2 pit,
the downcast.
News of the disaster spread like wildfire.
The mountain roads were soon alive
with people hurrying to the pit head
to get news of friends and
relations who might have been entombed.
Culinary managers and medical men for miles round
left their work and hastened to give what help they could.
The force of the explosion and its after effects
had fortunately been confined to the upcast.
Amid most pathetic scenes, all the workers in pit number two
were brought safely to the surface.
But from the other shaft there came no reply in answer to the many signals sent down, and the worst was feared.
The pit-head gear had been wrecked by the explosion, and the ventilation shaft was badly damaged,
so that it was some time before rescuers, plenty of whom are always ready to risk their lives in the service of humanity, could descend.
At the shaft bottom, four men were discovered, two still alive.
One of these died shortly after being brought to the surface.
The other, Matthew Davies, a lampman, was the only survivor of the 121 men who went down the shaft
for the morning shift.
He owed his life to his presence of mind in wetting the collar of his coat,
and holding it over his mouth to exclude the choke damp.
Proceeding along the airways, the relief party found ten bodies,
including that of Mr. Meredith, and then were brought to a halt by a fall of roof.
When the debris had been pierced, 70 more bodies were discovered,
some terribly mutilated, others in a sitting posture and uninjured.
One of the relief party said that bread and cheese lay about
and that the men were evidently having their dinner when the accident occurred.
In most cases, death must have been practically instantaneous.
One old miner lay as if asleep,
his features perfectly calm and undisturbed,
though a leg had been broken in two places.
Thus, in a fume,
moments, 120 lives had been blotted out. Such a calamity might be expected to scare many men
from earning their livelihood under conditions which render a like fate possible for them.
But no, explosions, falls, and floodings all come in the day's work and are soon forgotten.
The minor is somewhat of a fatal list, and, after all, the percentage of deaths from accidents
among his class is low, considering the risks.
Terrible as the Wats Town disaster was, it by no means represents the most tragic episode
of its kind.
In 1857, 180 men were killed by an explosion at London.
Hill Colerie, and it Oaks Colery in October 1866, no fewer than 364 poor fellows perished.
Even more tragic than an explosion, which is usually mercifully swift in its effects, is the
walling up of a party of miners by a fall. We have already mentioned the Hartley Colliery disaster which
shocked the world in 1862. The beam of the pumping engine broke and fell down the shaft,
killing on the spot five men who were ascending in the cage. Had the deaths been limited to that
number, little notice would have been taken of the affair. But, unfortunately, the 40-ton iron beam
on its way down detached large lumps of the shaft wall and an impenelior. And an impenetrable,
mass of wood and rubbish accumulated at a point 138 yards from the surface,
sealing the only means of egress for the 199 men and boys below.
These all perished from suffocation, though desperate efforts were made to reach them.
Two instances are on record in which entombed persons have lived for extraordinary periods
without food. In October 1835, a big fall took place in the Kilgrammy pit of the Little
Gervon-Colfield-Earsher. All the men escaped except one, John Brown, who returned to fetch
his jacket and had his egress blocked by a second, smaller fall. A fortnight later,
search was made for his body, and the searchers thought they heard,
that poor Brown could still be alive they could hardly believe and accordingly attributed the
noises to his spirit. However, the attack on the fall was continued and on the 23rd day after the
accident the open workings beyond were reached. Here they found Brown still alive, but so wasted
that his backbone could be felt by anyone laying a hand on the pit of his stomach.
When the poor collier reached the light of day,
his body and beard were seen to be covered by a fungus that grows upon decaying timber props,
a sight never seen before, but the rescue had come too late,
and in three days poor Brown died.
His remarkable record of endurance cut on the stone which marks his grave in Bailey Churchyard
is eclipsed by that of the well-sinker Jiro, who, with a companion, was entombed for 30 days in the bottom of a well near Leone.
To reach them it was necessary to sink a second shaft and drive a cross-heading, a very slow operation,
which would not have been persevered with had not the workers been encouraged by tapings below.
All Europe watched the extraordinary fight with death that Plucky Girot made.
His comrade died and his body lay rotting at his side.
On the 30th day, Girot was extracted, his body amass of gangrenic sores from contact with the corpse.
Like Brown, he had lived only to die a few days after his rescue.
An extraordinary instance of bite-damp poisoning occurred in 1898 at the Snafell lead mine,
the Isle of Man.
It is remarkable from the fact that several people, including Professor C. Lanav Foster,
one of the Royal Inspectors of Mines was almost asphyxiated, but being rescued in time,
recovered and have recorded their personal experiences. It appears that a fire took place
among the timber of the 130 fathom level, owing probably to a lighted candle being carelessly
allowed to touch a prop. The combustion produced the deadly carpenters. The combustion produced the deadly carpenters.
carbon monoxide which killed 20 miners. Two days after the accident, Professor Lanav Foster,
with three other men, descended the mine to test the air. What happened will best be given
in the words of the professor's personal report to Her Majesty's Secretary of State, which is at once
extremely interesting and pathetic. On the 13th May,
I did not notice any unpleasant symptoms while in the mind, but after having been on the surface
for a little time, I had a decided headache across the forehead. On the following day, we did not
go down below the 100 level and felt no inconvenience whatever in any shape or form.
On the 15th, there was certainly a feeling that the air, as we descended, was less good than on the
previous day. But this in no way interfered with my work, such as testing the air from platform
to platform below the 115. Nor was my power of deciding that it was unsafe to descend to the
corpse itself in any way impaired. I cannot recall any symptoms undoubtedly due to carbon monoxide
until I reached the 115 level after having climbed rapidly up.
the ladders, when Captain Culey gave the alarm that he was feeling ill. The poison took effect most
suddenly. Probably its action was accelerated by the exertion of climbing rapidly. I felt decidedly queer
when I reached the level and thought a drop of brandy might revive me. I took out my little
brandy flask, but already my fingers seemed incapable of doing the work properly, and someone
unscrewed the stopper for me. I took a small sip and sat down. Everything then seemed in a world,
and the atmosphere seemed to be a dense white fog. This must have been, as far as I can judge,
a little before 1 p.m., for we went down precisely at noon,
and allowing full time for the descent and testing the air from platform to platform below the 115,
I do not think an hour had elapsed after leaving the surface before we were taken ill.
Sitting next to me was Mr. Williams, and within a few feet were Captain Reddickliff and Henry Clegg,
the men who had remained all the time at the 115 level,
at all events had not descended as low as we did, had started to climb to the surface,
but of their starting I have no recollection. A curious fact is that we all sat without moving
or trying to escape. The foot of the ladder was close by, yet none of us made any effort to go to
it and ascend even a single rung. We none of us tried to walk a dozen. We, none of us, tried to walk a
seven steps, which would have led us to the other side of the shaft partition, where we all knew
that there was a current of better air. We simply sat on and on. Mr. Williams remained motionless,
like a statue. Captain Reddickliff, on the other hand, was shouting and groaning nearly all the time,
while Clegg was moving his arms. Of all this, I was perfectly conscious.
though rooted to my seat.
By my side was one of the pipes conveying compressed air,
in which a hole had been punched some days before.
I was perfectly conscious that fresh air was a good thing for me,
and I frequently leant over and put my mouth to the hole and inhaled a good breath.
How soon I realized that we were in what is commonly called a tight place,
I cannot say. But eventually, from long force of habit, I presume, I took out my notebook.
At what o'clock I first began to write I do not know, for the few words written on the first
page have no hour put to them. They were simply a few words of goodbye to my family, badly
scribbled. The next page is headed 2 p.m. and I perfectly well recollect taking out my watch from time to time.
As a rule, I do not take a watch underground, but I carried it on this occasion in order to be sure that I left
the rat long enough when testing with it. In fact, my note on the day of our misadventure was fifth ladder.
Rat, two minutes at man, meaning by the side of the corpse.
My notes at 2 p.m. were as follows.
2 p.m. Goodbye. We are all dying.
Your Clement. I fear we are dying. Goodbye.
All my darlings all. No help coming.
Goodbye. We are dying. Goodbye. Goodbye. We are dying. No help comes.
Goodbye. Goodbye. Goodbye.
Then later, partly scribbled over some goodbyes, I find.
We saw body at 130 and then all became affected by the bad air.
We have got to the 115 and can go no further.
The box does not come in spite of our ringing for help.
It does not come, does not come.
I wish the box would come.
Captain R is shouting.
My legs are bad.
and I feel very illegible. My knees are illegible. The so-called ringing was signaling to the surface by striking the airpipe, with a hammer or bar of iron. We had agreed upon signals before we went down. There is writing over other writing as if I did not see exactly where I placed my pencil. And then, I feel as if I were dreaming. No real
Goodbye, goodbye, goodbye, I feel as if I were sleeping.
2.15, we are all done. No, illegible, or scarcely any. We are done. We are done. Go do, buy, my darlings.
Here it is rather interesting to note that go do instead of good. Before very long,
the freshmen who had climbed down to rescue us seemed to have arrived and explained that
The box was caught in the shaft.
Judging by my notes, I did not realize thoroughly that we should be rescued.
Among them occur the words, no pain.
It is merely like a dream.
No pain.
No pain.
For the benefit of others, I say no pain at all.
No pain.
No pain.
I frequently wrote the same sentence over and over again.
My last note on reaching the surface tells of that resistance to authority, which likewise appears to be a symptom of the poisoning.
These notes afford ample confirmation of the effect produced by carbonic oxide poisoning of causing reiteration.
I wrote the same words over and over again unnecessarily.
The condition I was in was rather curious. I had absorbed enough of the poison to paralyze me to a certain extent and dull my feelings, but at the same time my reason had not left me.
The general sensation was like a bad dream, and yet I was able to reason properly and write intelligibly, though in a disjointed fashion.
I have been asked whether some of my notes may not have been written automatically or unconsciously.
If there had been merely a goodbye to my wife and children, I might have been doubtful on the subject.
As I find in my notebook I used some wording identical with that of a letter addressed to my wife,
which I had written as a matter of prudence before leaving Laxie on the morning of my first descent.
After my visit to the mine on the previous afternoon, I knew there was some risk to be encountered,
and I simply penned the letter for use in case things should go wrong.
Fortunately, the letter was not wanted.
Holy apart from my farewells, it seems to me from my notes that I was recording things correctly
and that my brain was reasoning properly.
I do not think I ever lost consciousness in the mine.
Mr. Williams, on the other hand, and Captain Radcliffe, though not absolutely unconscious,
did not recognize the lapse of time, for they thought that only about ten minutes passed
between my calling out all up at once and their arrival at the surface.
In reality, nearly two hours had gone by.
That the numbness of the fingers recorded in my notes was no fancy is proved by the fact that I burnt my wrist and hand with my candle while sitting underground, and had no notion that I had done so until a friend in the evening called my attention to a big blister.
I dare say this was five hours or more after the burn. I think there certainly was a feeling.
of acceleration on reaching the top of the shaft.
I was quite able to walk and was in full possession of my senses,
for I at once asked Dr. Miller to take a little of my blood
so that it might be tested spectroscopically.
He tied a bandage around my arm,
and when one of my veins was well swollen,
he inserted a hypodermic syringe,
but no blood could be drawn.
He then tried Mr. Williams in the same way, but again without success.
That the puncture was deep is proved by the scar, which is still apparent.
About an hour after I came up, I sent off a telegram to my wife,
which I reproduce in order to show that the effects of the carbon monoxide
in producing unnecessary repetitions had not worn off.
I am perfectly right. Do not believe any report to the contrary. I repeat, I am perfectly right,
Clement. Address Peverill Douglas. Though feeling quite able to walk to Laxey, a distance of about
four miles, I took the advice of Dr. Miller and went down with some others in a trap. One of the
miners who was with us was vomiting from time to time.
and by and by I felt a desire to be sick, Elsa, and put my finger down my throat with the idea of assisting nature, but without effect.
Soon after this, I became unconscious for a few minutes. It was not a true fainting, but something of the nature of an epileptiform seizure, as I am told that I was a little convulsed, though I never had anything in the nature.
of a fit before.
Dr. Haldane has pointed out that seizures of this description are not uncommon after
carbonic acid poisoning.
On getting to the hotel at Laxie, I laid down on the sofa with a headache, and Mr. Williams
suffered from headache and vomiting.
On arriving at Plentidna, three days after the accident, I happened to pass our family
doctor, and he told me afterwards that he at once noticed that the color of my face was strange.
A few days after I got back from the island the first time, about the 21st or 22nd of May,
I noticed my heart. It could scarcely be called palpitation, as I understand palpitations to be,
for there did not seem to be any increased rapidity of its action, but I would,
was conscious of its beating. As a rule, I am not. This passed off, and then on 1st and 2nd of June,
I noticed it very decidedly again, so much so that I went to my doctor. He sounded me and said
the heart was all right, though there was one sound which was not very distinct. This consciousness
of having a heart still returns from time to time, though only to a slight extent.
On the 19th of May, I suffered much from headache, not regularly, but intermittently.
The headache lasted for several days, and the feeling in the legs was very apparent.
It was an aching in the legs from the knee to the ankle.
A coldness from the knees to the soles of the feet was also noticeable.
It came on occasionally for a considerable time.
The headaches continued it in.
intervals for some time, and lasted certainly for some months after the accident.
Indeed, I cannot say that they have disappeared altogether. Whether these headaches are still
a consequence of the poisoning or not, I am unable to say. I have, at the risk of being wearisome,
given the above account of the mental phenomena accompanying partial poisoning by carbonic oxide,
because it is possible that they may be of assistance to those who are investigating the subject from a scientific point of view end of chapter twenty five end of the romance of mining by archibald williams
