a+history+of+reading

Giffard, Baptiste Henry Jacques (Henri)

SUBJECT AREA: Aerospace, Steam and internal combustion engines

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b. 8 February 1825 Paris, France

d. 14 April 1882 Paris, France

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French pioneer of airships and balloons, inventor of an injector for steam-boiler feedwater.

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Giffard entered the works of the Western Railway of France at the age of 16 but became absorbed by the problem of steam-powered aerial navigation. He proposed a steam-powered helicopter in 1847, but he then turned his attention to an airship. He designed a lightweight coke-burning, single-cylinder steam engine and boiler which produced just over 3 hp (2.2 kW) and mounted it below a cigar-shaped gas bag 44 m (144 ft) in length. A triangular rudder was fitted at the rear to control the direction of flight. On 24 September 1852 Giffard took off from Paris and, at a steady 8 km/h (5 mph), he travelled 28 km (17 miles) to Trappes. This can be claimed to be the first steerable lighter-than-air craft, but with a top speed of only 8 km/h (5 mph) even a modest headwind would have reduced the forward speed to nil (or even negative). Giffard built a second airship, which crashed in 1855, slightly injuring Giffard and his companion; a third airship was planned with a very large gas bag in order to lift the inherently heavy steam engine and boiler, but this was never built. His airships were inflated by coal gas and refusal by the gas company to provide further supplies brought these promising experiments to a premature end.

As a draughtsman Giffard had the opportunity to travel on locomotives and he observed the inadequacies of the feed pumps then used to supply boiler feedwater. To overcome these problems he invented the injector with its series of three cones: in the first cone (convergent), steam at or below boiler pressure becomes a high-velocity jet; in the second (also convergent), it combines with feedwater to condense and impart high velocity to it; and in the third (divergent), that velocity is converted into pressure sufficient to overcome the pressure of steam in the boiler. The injector, patented by Giffard, was quickly adopted by railways everywhere, and the royalties provided him with funds to finance further experiments in aviation. These took the form of tethered hydrogen-inflated balloons of successively larger size. At the Paris Exposition of 1878 one of these balloons carried fifty-two passengers on each tethered "flight". The height of the balloon was controlled by a cable attached to a huge steam-powered winch, and by the end of the fair 1,033 ascents had been made and 35,000 passengers had seen Paris from the air. This, and similar balloons, greatly widened the public's interest in aeronautics. Sadly, after becoming blind, Giffard committed suicide; however, he died a rich man and bequeathed large sums of money to the State for humanitarian an scientific purposes.

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Principal Honours and Distinctions

Croix de la Légion d'honneur 1863.

Bibliography

1860, Notice théorique et pratique sur l'injecteur automoteur.

1870, Description du premier aérostat à vapeur.

Further Reading

Dictionnaire de biographie française.

Gaston Tissandier, 1872, Les Ballons dirigeables, Paris.

—1878, Le Grand ballon captif à vapeur de M. Henri Giffard, Paris.

W.de Fonvielle, 1882, Les Ballons dirigeables à vapeur de H.Giffard, Paris. Giffard is covered in most books on balloons or airships, e.g.: Basil Clarke, 1961, The History of Airships, London. L.T.C.Rolt, 1966, The Aeronauts, London.

Ian McNeill (ed.), 1990, An Encyclopaedia of the History of Technology, London: Routledge, pp. 575 and 614.

J.T.Hodgson and C.S.Lake, 1954, Locomotive Management, Tothill Press, p. 100.

PJGR / JDS

Gilpin, Thomas

SUBJECT AREA: Canals

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b. 18 March 1728 Chester County, Pennsylvania, USA

d. 30 April 1778 Winchester, Virginia, USA

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American manufacturer.

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Thomas Gilpin belonged to a wealthy Quaker family descended from Joseph Gilpin, who had emigrated from England in 1696. He received little formal education and was mainly self-educated in mathematics, surveying and science, in which subjects he was particularly interested. With estates in Delaware and Maryland, he was involved in farming and manufacturing. He moved to Philadelphia in 1769, which further extended his activities. With his fortune he was able to indulge his interest in science, and he was one of the original members of the American Philosophical Society in 1769. He wrote papers on the wheat fly, the seventeen-year locust and the migration of herrings. It was through this Society that he became friendly with Benjamin Franklin, to whom he wrote on 10 October 1769 setting out his proposals for and advocacy of a canal linking the Elk River on Chesapeake Bay with the Delaware River and Bay, thereby cutting off a long haul of several hundred miles for vessels around Cape Charles with a dangerous passage unto the Atlantic Ocean. Gilpin also invented a hydraulic pump that delighted Franklin very much. Gilpin had visited England in 1768 during the formation of his ideas for the Chesapeake \& Delaware Canal, and probably visited the Bridgewater Canal while there. Despite his pressing advocacy the canal had to wait until after his death, but later his son Joshua, a director from 1803 to 1824, saw the canal through many difficulties although he had resigned before the official opening in 1829. At the outbreak of the American War of Independence, in 1777, Gilpin, together with other Quakers, was arrested in Philadelphia owing to suspicions of his loyalty on the grounds that as a Quaker he refused to sign the Oath of Allegiance. He was later exiled to Winchester, Virginia, where he died in April 1778.

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Further Reading

1925, "Memoir of Thomas Gilpin", Pennsylvania Magazine of History and Biography.

R.D.Gray, 1967, The National Waterway: A History of the Chesapeake and Delaware Canal, 1769–1985, Urbana: Illinois University Press.

JHB

Girard, Philippe de

SUBJECT AREA: Textiles

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b. 1775 France

d. 1845

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French developer of a successful flax-heckling machine for the preparation of fibres for power-spinning.

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Early drawing and spinning processes failed to give linen yarn the requisite fineness and homogeneity. In 1810 Napoleon offered a prize of a million francs for a successful flax-spinning machine as part of his policy of stimulating the French textile industries. Spurred on by this offer, Girard suggested three improvements. He was too late to win the prize, but his ideas were patented in England in 1814, although not under his own name. He proposed that the fibres should be soaked in a very hot alkaline solution both before drawing and immediately before they went to the spindles. The actual drawing was to be done by passing the dried material through combs or gills that moved alternately; gill drawing was taken up in England in 1816. His method of wet spinning was never a commercial success, but his processes were adopted in part and developed in Britain and spread to Austria, Poland and France, for his ideas were essentially good and produced a superior product. The successful power-spinning of linen thread from flax depended primarily upon the initial processes of heckling and drawing. The heckling of the bundles or stricks of flax, so as to separate the long fibres of "line" from the shorter ones of "tow", was extremely difficult to mechanize, for each strick had to be combed on both sides in turn and then in the reverse direction. It was to this problem that Girard next turned his attention, inventing a successful machine in 1832 that subsequently was improved in England. The strick was placed between two vertical sheets of combs that moved opposite to each other, depositing the tow upon a revolving cylinder covered with a brush at the bottom of the machine, while the holder from which the strick was suspended moved up and down so as to help the teeth to penetrate deeper into the flax. The tow was removed from the cylinder at the bottom of the machine and taken away to be spun like cotton. The long line fibres were removed from the top of the machine and required further processing if the yarn was to be uniform.

When N.L.Sadi Carnot's book Réflexions sur la puissance motrice du feu, was published in 1824, Girard made a favourable report on it.

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Further Reading

M.Daumas (ed.), 1968, Histoire générale des techniques, Vol. III: L'Expansion du

Machinisme, Paris.

C.Singer (ed.), 1958, A History of'Technology, Vol. IV, Oxford: Clarendon Press. T.K.Derry and T.I.Williams, 1960, A Short History of Technology from the Earliest

Times to AD 1900, Oxford.

W.A.McCutcheon, 1966–7, "Water power in the North of Ireland", Transactions of the Newcomen Society 39 (discusses the spinning of flax and mentions Girard).

RLH

Greathead, James Henry

SUBJECT AREA: Civil engineering, Mining and extraction technology

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b. 6 August 1844 Grahamstown, Cape Colony (now South Africa)

d. 21 October 1896 Streatham, London, England

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British civil engineer, inventor of the Greathead tunnelling shield.

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Greathead came to England in 1859 to complete his education. In 1864 he began a three-year pupillage with the civil engineer Peter W. Barlow, after which he was engaged as an assistant engineer on the extension of the Midland Railway from Bedford to London. In 1869 he was entrusted with the construction of the Tower Subway under the River Thames; this was carried out using a cylindrical wrought-iron shield which was forced forward by six large screws as material was excavated in front of it. This work was completed the same year. In 1870 he set himself up as a consulting engineer, and from 1873 he was Resident Engineer on the Hammersmith and Richmond extensions of the Metropolitan District Railway. He assisted in the preparation of several other railway projects including the Regent's Canal Railway in 1880, the Dagenham Dock and the Metropolitan Outer Circle Railways in 1881, a new line from London to Eastbourne and a number of Irish light railways. He worked on a bill for the City and South London Railway, which was built between 1886 and 1890; here compressed air was used to prevent the inrush of water, a method for tunnelling which was generally adopted from then on. He invented apparatus for the application of water to excavate in front of the shield as well as for injecting cement-grout behind the lining of the tunnel.

He was joint engineer with Sir Douglas Fox for the construction of the Liverpool Overhead Railway, and held the same post with W.R.Galbraith on the Waterloo and City Railway; he was also associated with Sir John Fowler and Sir Benjamin Baker in the construction of the Central London Railway. He died, aged 52, before the completion of some of these projects.

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Further Reading

Obituary, 1896, Proceedings of the Institution of Mechanical Engineers.

O.Green, 1987, The London Underground: An Illustrated History', London: Ian Allan (in association with the London Transport Museum).

P.P.Holman, 1990, The Amazing Electric Tube: A History of the City and South London

Railway, London: London Transport Museum.

IMcN

Haupt, Hans

SUBJECT AREA: Domestic appliances and interiors

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fl. c.1930 Berlin, Germany

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German inventor of the telescopic umbrella.

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Few biographical details are known of Hans Haupt, other than that he invented the telescopic umbrella in Berlin in 1930. His device gave protection from rain and sun similar to that provided by Samuel Fox's lightweight steel-framed device of 1874, but it was much more compact when folded.

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Further Reading

There is a brief mention in I.McNeil (ed.), 1990, An Encyclopaedia of the History of Technology, London: Routledge, p. 853; and in C.Singer (ed.), 1958, A History of Technology, Vol. IV, Oxford: Clarendon Press.

RLH

Heilmann, Josué (Joshua)

SUBJECT AREA: Textiles

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b. 1796 Alsace

d. 1848

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Alsatian inventor of the first machine for combing cotton.

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Josué Heilmann, of Mulhouse, was awarded 5,000 francs offered by the cotton spinners of Alsace for a machine that would comb cotton. It was a process not hitherto applied to this fibre and, when perfected, enabled finer, smoother and more lustrous yarns to be spun. The important feature of Heilmann's method was to use a grip or nip to hold the end of the sliver that was being combed. Two or more combs passed through the protruding fibres to comb them thoroughly, and a brush cylinder and knife cleared away the noils. The combed section was passed forward so that the part held in the nip could then be combed. The combed fibres were joined up with the length already finished. Heilmann obtained a British patent in 1846, but no machines were put to work until 1851. Six firms of cotton spinners in Lancashire paid £30,000 for the cotton-combing rights and Marshall's of Leeds paid £20,000 for the rights to comb flax. Heilmann's machine was used on the European continent for combing silk as well as flax, wool and cotton, so it proved to be very versatile. Priority of his patent was challenged in England because Lister had patented a combing machine with a gripper or nip in 1843; in 1852 the parties went to litigation and cross-suits were instituted. While Heilmann obtained a verdict of infringement against Lister for certain things, Lister also obtained one against Heilmann for other matters. After this outcome, Heilmann's patent was bought on speculation by Messrs Akroyd and Titus Salt for £30,000, but was afterwards resold to Lister for the same amount. In this way Lister was able to exploit his own patent through suppressing Heilmann's.

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Bibliography

1846, British patent no. 11,103 (cotton-combing machine).

Further Reading

For descriptions of his combing machine see: W.English, 1969, The Textile Industry, London; T.K.Derry and T.I.Williams, 1960, A Short History of Technology from the Earliest Times to AD 1900, Oxford; and C.Singer (ed.), 1958, A History of Technology, Vol.

IV, Oxford: Clarendon Press.

RLH

Hoe, Richard March

SUBJECT AREA: Paper and printing

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b. 12 September 1812 New York, USA

d. 7 June 1886 Florence, Italy

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American inventor of the rotary printing press.

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He was the son of Robert Hoe, a printer who improved the cylinder press invented by David Napier. At the age of 15 he entered his father's business, taking full control of it three years later. Newspaper publishers demanded ever-increasing speeds of output from the printing press, and Hoe was one of those who realized that the speed was limited by the reciprocating action of the flat-bed machine. In 1846 he constructed a rotary press in which a central cylinder carried the type and flat sheets of paper were fed to smaller impression cylinders ranged around it. This kind of press, with four impression cylinders, was first used to print the Philadelphia Public Ledger in 1847, and was able to print 8,000 papers per hour. Such presses reigned supreme for newspaper printing in many countries for twenty-five years: in 1857, for example, The Times had a ten-feeder machine making 20,000 impressions per hour. Even so, the quest for speed, now limited by the single-sheet feed, continued. William Bullock (1813–67) introduced continuous roll or web feed for the Philadelphia Inquirer in 1865, and the next year The Times followed suit with the web-fed Walter press. In 1871 Hoe devised a machine that combined all the advantages of the existing machines, producing a rotary, web, perfecting (printing on both sides of the paper at once) machine, first used in the office of the New York Tribune. Ten years later the Hoe Company devised a folding machine to fold the copies as they came off the press: the modern newspaper printing press had arrived. In addition to his contributions to the printing industry, Hoe was a good employer, arranging free evening classes and other welfare services for his apprentices.

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Further Reading

R.Hoe, 1902, A Short History of the Printing Press, New York. S.D.Tucker, A History of K.Hoe \& Co. New York.

LRD

Holabird, William

SUBJECT AREA: Architecture and building, Civil engineering

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b. 11 September 1854 American Union, New York, USA

d. 19 July 1923 Evanston, Illinois, USA

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American architect who contributed to the development of steel framing, a type of structure that rendered possible the erection of the skyscraper.

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The American skyscraper was, in the 1870s and 1880s, very much the creation of what came to be known as the Chicago school of architecture. It was the most important American contribution to the urban architectural scene. At this time conditions were ripe for this type of office development, and in the big cities, notably Chicago and New York, steeply rising land values provided the incentive to build high; the structural means to do so had been triggered by the then low costs of making quality iron and steel. The skyscraper appeared after the invention of the passenger lift by Otis and the pioneer steel-frame work of Jenney. In 1875 Holabird was working in Jenney's office in Chicago. By 1883 he had set up in private practice, joined by another young architect, Martin Roche (1855–1927), and together they were responsible for the Tacoma Building (1887–9) in Chicago. In this structure the two front façades were entirely non-load-bearing and were carried by an internal steel skeleton; only the rear walls were load-bearing. The design of the building was not revolutionary (this had to wait for L.H. Sullivan) but was traditional in form. It was the possibility of being able to avoid load-bearing outer walls that enabled a building to rise above some nine storeys, and the thirteen-storeyed Tacoma Building pointed the way to the future development of the skyscraper. The firm of Holabird \& Roche continued in the following decades in Chicago to design and construct further high-quality, although lower, commercial buildings such as those in South Michigan Avenue and the McClurg Building. However, they are best remembered for their contribution in engineering to the development of high-rise construction.

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Further Reading

F.Mujica, 1929, History of the Skyscraper, Paris: Archaeology and Architecture Press. C.W.Condit, 1964, The Chicago School of Architecture: A History of Commercial and

Public Building in the Chicago Area 1875–1925, Chicago: University of Chicago Press. J.W.Rudd (compiler), 1966, Holabird and Roche: Chicago Architects, American Association of Architectural Bibliographers.

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