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The Romance of Industry and Invention Part 3

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It is during the process of decoration that the ornate vases and figures make so many trips to the fire. The artist department is a very large and important one. The designers, however, are a cla.s.s of themselves.

They project the idea; it is the business of the artist, in these circ.u.mstances, to execute it. The painters are taken into the works as lads and trained for the special service. What you remark chiefly in going through the decorating rooms is the great facility of the artists.

You see a man with a plate or vase on which he is outlining a landscape, and you marvel at the rapid, accurate touches with which he does the work. Flowers, birds, and figures they can reproduce with great skill, and many of them are artists not merely in facility but in instinct.

They work with metallic colours only. They rely on copper, for instance, to give black and green, on iron to yield red hues, and so on; and the gold work is done with what seems to be a dirty brown paste, but is really pure gold mixed with flux and quicksilver. When the first wash is put on, the piece must be fired, so that the colours shall be burnt into the glaze. Then it returns to the painter, who adds the next touches so far as he can; the firing again follows; the piece is returned to him once more; and so on it goes till the work is complete.

It is therefore a highly technical business, especially as the colours change very much in the fire, and the painter has to work with full knowledge of the chemical processes in every firing. There is one form of the decorative process which is very singular--that is, the piercing work. The artist has the vase in the dried state before the firing, and with a tiny, sharp-pointed knife he cuts out little pieces according to the design in his mind, and produces an extremely beautiful perforated ware, the elaborate pattern and the lace-like delicacy of which almost repel the idea that the work is done by the unaided hand of man. In the colour processes, the work is virtually complete when the dull gold has been burnished; and the porcelain is then ready to be transferred to the showrooms, or exported to America, which is the greatest patron, at present, of Worcester art. America, however, failed to retain one lovely vase no less than four feet high, the largest ever made in the works; it was taken to the Chicago Exhibition and back without accident, and was then sold in England for one thousand pounds.



It is important to remember the distinction between 'pottery' and 'porcelain:' the porcelain is clay purified by the fire, whereas pottery leaves the oven as it entered it--clay. The purification of the ware is really an ill.u.s.tration of the process which sustains the artistic inspiration of the work. The gross, the vulgar, the mean are eliminated; a standard of beauty is set up, and to it every article must conform. It is to this ideal, sustained by a long succession of artists through a century and a half, that Worcester owes its world-wide reputation as the birthplace of some of the loveliest porcelain ever burnt in a kiln.

[Ill.u.s.tration: Chinese Porcelain Vase.]

[Ill.u.s.tration]

CHAPTER III.

THE SEWING-MACHINE.

Thomas Saint--Thimonnier--Hunt--Elias Howe--Wilson--Morey--Singer.

Although the sewing-machine has not put an end to the slavery of the needle, and although 'The Song of the s.h.i.+rt' may be heard to the accompaniment of its click and whirr, just as it was to the 'st.i.tch, st.i.tch' of Tom Hood's time, yet has it unquestionably come as a boon and a blessing to man--and woman. Its name now is legion, and it has had so many inventors and improvers that the present generation is fast losing sight of its original benefactors. Indeed, we take the sewing-machine to-day as an accomplished fact so familiar as to be commonplace. And yet that fact is a product of as moving a history as any in the story of human invention.

It is the growth of the last half-century, prior to which the real sewing-machine was the heavy-eyed, if not tireless, needlewoman, whose flying fingers seemed ever in vain pursuit of the flying hours.

Needlework is as old as human history, for we may see the beginnings of it in the ap.r.o.ns of fig-leaves which Mother Eve sewed. What instrument she used we know not, but we do know from Moses that needles were in use when the tabernacle was built. Yet, strange to say, it was not until the middle of last century that any one tried to supersede manual labour in the matter of st.i.tching. It is said that a German tailor, named Charles Frederick Weisenthal, was the first to attempt it, but for hand-embroidery only--with a double-pointed needle, eyed in the middle.

This was in 1755, and fifty years later, one John Duncan, a Glasgow machinist, worked out Weisenthal's idea into a genuine embroidering machine, which really held the germ of the idea of the 'loop-st.i.tch.'

But neither of these was a sewing-machine, and before Duncan's invention some one else had been seized with another idea.

This was a London cabinetmaker called Thomas Saint, who in or about 1790 took out a patent for a machine for sewing leather, or rather for 'quilting, st.i.tching, and making shoes, boots, spatterdashes, clogs, and other articles.' This patent, unfortunately, was taken out along with other inventions in connection with leather, and it was quite by accident that, some eighty years later, the specification of it was discovered by one who had made for himself a name in connection with sewing-machines. Even the Patent Office did not seem to have known of its existence, yet now it is clear enough that Thomas Saint's leather-sewing-machine of 1790 was the first genuine sewing-machine ever constructed, and that it was on what is now known as the 'chain-st.i.tch'

principle. Rude as it was, it is declared by experts to have antic.i.p.ated most of the ingenious ideas of half a century of successive inventors, not one of whom, however, could in all human probability have as much as heard of Saint's machine. This is not the least curious incident in the history of the sewing-machine.

In Saint's machine the features are--the overhanging arm, which is the characteristic of many modern machines; the perpendicular action of the Singer machine; the eye-pointed needle of the Howe machine; the pressure surfaces peculiar to the Howe machine; and a 'feed' system equal to that of the most modern inventions. Whether Saint's machine was ever worked in a practical workshop or not, it was unquestionably a practicable machine, constructed by one who knew pretty well what he was about, and what he wanted to achieve.

Now note the date of Thomas Saint's patent (1790), and next note the date of the invention of Barthelmy Thimonnier, of St Etienne, who is claimed in France as the inventor of the sewing-machine. In 1830, Thimonnier constructed a machine, princ.i.p.ally of wood, with an arrangement of barbed needles, for st.i.tching gloves, and in the following year he began business in Paris, with a partner, as an army clothier. The firm of Thimonnier, Pet.i.t, & Co., however, did not thrive, because the workpeople thought they saw in the princ.i.p.al's machine an instrument destined to ruin them; much as the Luddites viewed steam-machinery in the cotton districts of England. An idea of that sort rapidly germinates heat, and Thimonnier's workshop was one day invaded by an angry mob, who smashed all the machines, and compelled the inventor to seek safety in flight. Poor Thimonnier was absent from Paris for three years, but in 1834 returned with another and more perfect machine. This was so coldly received, both by employers and workmen in the tailoring trade, that he left the capital, and, journeying through France with his machine, paid his way by exhibiting it in the towns and villages as a curiosity. After a few years, however, Thimonnier fell in with a capitalist who believed in him and his machine, and was willing to stake money on both. A partners.h.i.+p was entered into for the manufacture and sale of the machine, and all promised well for the new firm, when the Revolution of 1848 broke out, stopped the business, and ruined both the inventor and the capitalist. Thimonnier died in 1857, in a poorhouse, of a broken heart.

This French machine was also on the chain-st.i.tch principle, but it was forty years later than Saint's. In between the two came, about 1832, one Walter Hunt, of New York, who is said to have constructed a sewing-machine with the lock-st.i.tch movement. Some uncertainty surrounds this claim, and Elias Howe is the person usually credited with this important, indeed invaluable invention. Whether Howe had ever seen Hunt's machine, we know not; but Hunt's machine was never patented, seems never to have come into practical working, and is, indeed, said to have been unworkable. There is, besides, in the Polytechnic at Vienna, the model of a machine, dated 1814, constructed by one Joseph Madersberg, a tailor of the Tyrol, which embodies the lock-st.i.tch idea--working with two threads. But this also was unworkable, and Elias Howe has the credit of having produced the first really practical lock-st.i.tch sewing-machine.

His was a life of vicissitude and of ultimate triumph, both in fame and fortune. He was born at a small place in Ma.s.sachusetts in 1819, and as a youth went to Boston, there to work as a mechanic. While there, and when about twenty-two years old, the idea occurred to him at his work of pa.s.sing a thread through cloth and securing it on the other side by another thread. Here we perceive the germ of the lock-st.i.tch--the two threads. Howe began to experiment with a number of bent wires in lieu of needles, but he lacked the means to put his great idea to a thorough practical test. Thus it slumbered for three years, when he went to board and lodge with an old schoolfellow named Fisher, who, after a while, agreed to advance Howe one hundred pounds in return for a half share in the invention should it prove a success. Thus aided, in 1845 Howe completed his first machine, and actually made himself a suit of clothes with it; and this would be just about the time of Thimonnier's temporary prosperity in alliance with the capitalist, Mogrini.

Feeling sure of his ground, Howe took bold steps to 'boom' his invention. He challenged five of the most expert sewers in a great Boston clothing factory to a sewing match. Each of them was to sew a certain strip of cloth, and Howe undertook to sew five strips, torn in halves, before each man had completed his one strip. The arrangements completed, the match began, and to the wonder of everybody, Howe finished his five seams before the others were half done with one seam.

But murmurs instead of cheers succeeded the victory. He was angrily reproached for trying to take the bread out of the mouth of the honest working-man, and a cry was raised among the workers (as it has been heard time and again in the history of industrial development) to smash the machine. Howe, indeed, had much difficulty in escaping from the angry mob, with his precious machine under his arm.

In Howe's experience we thus see one parallel with Thimonnier's; but there was another. The American was quite as poor and resourceless as the Frenchman, and the next step in Howe's career was that he went on tour to the country fairs to exhibit his machine for a trifling fee, in order to keep body and soul together. People went in flocks to see the thing as a clever toy, but no one would 'take hold' of it as a practical machine. And so, in despair of doing any good with it in America, Elias Howe, in 1846, sent his brother to England to see if a market could not be found for the invention there. The brother succeeded in making terms with one William Thomas, staymaker, in Cheapside, London, and he sent for Elias to come over.

The price to be paid by Thomas for the patent was two hundred and fifty pounds, but Howe was to make certain alterations in it so as to adapt it to the special requirements of the purchaser. While engaged in perfecting the machine, he was to receive wages at the rate of three pounds per week, and this wage he seems to have received for nearly two years. But he failed to achieve what Thomas wanted, and Thomas, after spending a good deal of money over the experiments, abandoned the thing altogether. Howe was thus astrand again, and he returned to America as poor as ever, leaving his machine behind him in p.a.w.n for advances to pay his pa.s.sage home. And yet there were 'millions in it.'

This was in the year 1849, and just about the time when Howe was returning to America, another American, named Bostwich, was sending over to England a machine which he had invented for imitating hand-st.i.tching, by means of cog-wheels and a bent needle. And a year or two after Howe's return, one Charles Morey, of Manchester, attempted to carry out the same st.i.tch on a somewhat different plan, but failed to find sufficient pecuniary support. Indeed, poor Morey had a tragic end, for, taking his machine to Paris in the hope of finding a purchaser there, he incurred some debt which he could not pay, and was clapped into the Mazas prison.

While there, he inadvertently broke the rules, and was shot by the guard for failing to reply to a challenge which he did not understand.

When Howe got back to the United States, he found a number of ingenious persons engaged in producing or experimenting in sewing-machines, and some of them were trenching on his own patent rights. He raised enough money, somehow, to redeem his p.a.w.ned machine in England, and then raised actions against all who were infringing it. The litigation was tremendous both in duration and expense, but it ended in the victory of Elias Howe, to whom, by the finding of the court, the other patentees were found liable for royalty. It is said that Howe, who as we have seen left London in debt, received, before his patent expired in 1867, upwards of two million dollars in royalties alone.

But ingenious men were now busy in both hemispheres in perfecting what, up till about fifty years ago, was regarded as nothing better than a clever toy. Besides Morey, the Manchester man we have mentioned, a Huddersfield machinist, named Drake, brought out a machine to work with a shuttle. About the same time, or a little later, a young Nottingham man, named John Fisher, constructed a machine with a sort of lock-st.i.tch movement, which he afterwards adapted to a double loop-st.i.tch. But Fisher's machine was intended rather for embroidering than for plain sewing.

Pa.s.sing over some minor attempts, the next great development was that of Allen Wilson, who, without having heard either of Howe's or of any other machine, constructed one in 1849, the design of which, he said, he had been meditating for two years. His first machine had original features, however much it may have been antic.i.p.ated in principle by Howe's patent.

In Wilson's second design, a rotary hook was subst.i.tuted for a two-pointed shuttle, and by other improvements he achieved a greater speed than had been attained by other inventors. Later still, he added the 'four-motion feed,' which is adopted on most of the machines now in general use.

This idea was an elaboration of a principle which seems to have first occurred to the unfortunate Morey. In Morey's machine there was a horizontal bar with short teeth, which caught the fabric and dragged it forward as the st.i.tches were completed. It took nearly thirty years, however, to evolve the perfect 'feed' motion out of Morey's first crude germ.

While Wilson was working away, perfecting his now famous machine, an observing and thoughtful young millwright was employed in a New York factory. One day a sewing-machine was sent in for repairs, and after examining its mechanism, this young man, whose name was Isaac Singer, confidently expressed his belief that he could make a better one. He did not propose either to appropriate or abandon the principle, but to improve upon it. Instead of a curved needle, as in Howe's and Wilson's machines, he adopted a straight one, and gave it a perpendicular instead of a curvular motion. And for propelling the fabric he introduced a wheel, instead of the toothed bar of the Morey design.

It need hardly be said that the Singer machine is now one of the most widely known, and is turned out in countless numbers in enormous factories on both sides of the Atlantic. It is not so well known, perhaps, that Singer, who was a humble millwright in 1850, and who died in 1875, left an estate valued at three millions sterling--all ama.s.sed in less than twenty-five years!

The machines of Howe, Wilson, and Singer were on the lock-st.i.tch principle, and the next novelty was the invention of Grover and Baker, who brought out a machine working with two needles and two continuous threads. After this came the Gibbs machine, the story of which may be briefly told.

About the year 1855, James G. Gibbs heard of the Grover and Baker machine, and having a turn for mechanics, began to ponder over how the action described was produced. He got an ill.u.s.tration, but could make nothing of it, and not for a year did he obtain sight of a Singer machine at work. As in the case of Singer with Wilson's machine, so Gibbs thought he could improve on Singer's, and turn out one less ponderous and complicated. He set to work, and in a very short time took out a patent for a new lock-st.i.tch machine. But he was not satisfied with this, and experimented away, with an idea of making a chain-st.i.tch by means of a revolving looper. This idea he eventually put into practical form, and took out a patent for the first chain-st.i.tch sewing-machine.

Since the days of Elias Howe, the number of patents taken out for sewing-machines has been legion--certainly not less than one thousand--and probably no labour-saving appliance has received more attention at the hands both of inventors and of the general public.

There is scarcely a household in the land now, however humble, without a sewing-machine of some sort, and in factories and warehouses they are to be numbered by the thousand. Some machinists have directed their ingenuity to the reduction of wear and tear, others to the reduction of noise, others to acceleration of speed, others to appliances for supplying the machine in a variety of ways, others for adapting it to various complicated processes of st.i.tching and embroidering. Some users prefer the lock-st.i.tch, and some the chain-st.i.tch principle, and each system has its peculiar advantages according to the character of the work to be sewn.

A recent development is a combination of both principles in one machine.

Mr Edward Kohler patented a machine which will produce either a lock-st.i.tch or a chain-st.i.tch, as may be desired, and an embroidery st.i.tch as well. By a very ingenious contrivance the machinery is altered by the simple movement of a b.u.t.ton, and (when the chain-st.i.tch is required) the taking out of the bobbin from the shuttle. If the embroidery st.i.tch is wanted, the b.u.t.ton is turned without removing the bobbin, and the lock-st.i.tch and chain-st.i.tch are combined in one new st.i.tch, with which very elaborate effects can be produced. It is said that the Kohler principle can be easily adapted to all, or most, existing machines.

[Ill.u.s.tration]

CHAPTER IV.

WOOL AND COTTON.

WOOL.--What is Wool?--Chemical Composition--Fibre--Antiquity of Shepherd Life--Varieties of Sheep--Introduction into Australia--Spanish Merino--Wool Wealth of Australia--Imports and Exports of Wool and Woollen Produce--Woollen Manufacture.

COTTON.--Cotton Plant in the East--Mandeville's Fables about Cotton--Cotton in Persia, Arabia, and Egypt--Columbus finds Cotton-yarn and Thread in 1492--In Africa--Manufacture of Cloth in England--The American Cotton Plant.

WOOL.

What is wool? 'The covering of the sheep, of course,' replies somebody.

Yes; but what _is_ it? Let us ask Professor Owen. 'Wool,' he says, 'is a peculiar modification of hair, characterised by fine transverse or oblique lines from two to four thousand in the extent of an inch, indicative of a minutely imbricated scaly surface, when viewed under the microscope, on which and on its curved or twisted form depends its remarkable felting property.' At first sight this definition seems bewildering, but it will bear examination, and is really more tangible than, for instance, Noah Webster's definition of wool: 'That soft curled or crisped species of hair which grows on sheep and some other animals, and which in fineness sometimes approaches to fur.' It is usually that which grows on sheep, however, that we know as wool, and the number of imbrications, serratures, or notches indicates the quality of the fibre.

Thus, in the wool of the Leicester sheep there are 1850--in Spanish merino, 2400--in Saxon merino, 2700, to an inch, and the fewer there are the nearer does wool approach to hair.

[Ill.u.s.tration: Wool-sorters at Work.]

Here is a still more minute description by Youatt, a great authority on wool: 'It consists of a central stem or stalk, probably hollow, or at least porous, and possessing a semi-transparency, found in the fibre of the hair. From this central stalk there springs, at different distances in different breeds of sheep, a circlet of leaf-shaped projections. In the finer species of wool these circles seemed at first to be composed of one indicated or serrated ring; but when the eye was accustomed to them, this ring was resolvable into leaves or scales. In the larger kinds, the ring was at once resolvable into these scales or leaves, varying in number, shape, and size, and projecting at different angles from the stalk, and in the direction of the leaves of vegetables--that is, from the root to the point. They give to the wool the power of felting.'

This is the estimate of the chemical composition of good wool: Carbon, 50.65; hydrogen, 7.03; nitrogen, 17.71; oxygen and sulphur, 24.61. Out of a hundred parts, ninety-eight would be organic, and two would be ash, consisting of oxide of iron, sulphate of lime, phosphate of lime, and magnesia. What is called the 'yolk' of wool is a compound of oil, lime, and potash. It makes the pile soft and pliable, and is less apparent on English sheep than on those of warmer countries, the merino sheep having the most 'yolk.'

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