Neue Deutsche Biographie

Halske, Johann Georg

SUBJECT AREA: Electricity, Telecommunications

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b. 30 July 1814 Hamburg, Germany

d. 18 March 1890 Berlin, Germany

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German engineer who introduced precision methods into the manufacture of electrical equipment; co-founder of Siemens \& Halske.

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Halske moved to Berlin when he was a young man, and in 1844 was working for the university, at first independently and then jointly with F. Bötticher, developing and building electric medical appliances. In 1845 he met Werner von Siemens and together they became founder members of the Berlin Physics Society. It was in Halske's workshop that Siemens, assisted by the skill of the former, was able to work out his inventions in telegraphy. In 1847 the two men entered into partnership to manufacture telegraph equipment, laying the foundations of the successful firm of Siemens \& Halske. At the outset, before Werner von Siemens gave up his army career, Halske acted as the sole manager of the firm and was also involved in testing the products. Inventions they developed included electric measuring instruments and railway signalling equipment, and they installed many telegraph lines, notably those for the Russian Government. When gutta-percha became available on the market, the two men soon developed an extrusion process for applying this new material to copper conductors. To the disappointment of Halske, who was opposed to mass production, the firm introduced series production and piece wages in 1857. The expansion of the business, particularly into submarine cable laying, caused some anxiety to Halske, who left the firm on amicable terms in 1867. He then worked for a few years developing the Arts and Crafts Museum in Berlin and became a town councillor.

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Further Reading

S. von Weihr and H.Götzeler, 1983, The Siemens Company. Its Historical Role in the Progress of Electrical Engineering 1847–1983, Berlin (provides a full account).

Neue Deutsche Biographie, 1966, Vol. 7, Berlin, pp. 572–3.

S.von Weiher, 1972–3, "The Siemens brothers, pioneers of the electrical age in Europe", Transactions of the Newcomen Society 45:1–11.

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Hipp, Matthäus

SUBJECT AREA: Electronics and information technology, Horology

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b. 25 October 1813 Blaubeuren, Germany

d. 3 May 1893 Zurich, Switzerland

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German inventor and entrepreneur who produced the first reliable electric clock.

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After serving an apprenticeship with a clock-maker in Blaubeuren, Hipp worked for various clockmakers before setting up his own workshop in Reutlingen in 1840. In 1842 he made his first electric clock with an ingenious toggle mechanism for switching the current, although he claimed that the idea had occurred to him eight years earlier. The switching mechanism was the Achilles' heel of early electric clocks. It was usually operated by the pendulum and it presented the designer with a dilemma: if the switch made a firm contact it adversely affected the timekeeping, but if the contact was lightened it sometimes failed to operate due to dirt or corrosion on the contacts. The Hipp toggle switch overcame this problem by operating only when the amplitude of the pendulum dropped below a certain value. As this occurred infrequently, the contact pressure could be increased to provide reliable switching without adversely affecting the timekeeping. It is an indication of the effectiveness of the Hipp toggle that it was used in clocks for over one hundred years and was adopted by many other makers in addition to Hipp and his successor Favag. It was generally preferred for its reliability rather than its precision, although a regulator made in 1881 for the observatory at Neuchâtel performed creditably. This regulator was enclosed in an airtight case at low pressure, eliminating errors due to changes in barometric pressure. This practice later became standard for observatory regulators such as those of Riefler and Shortt. The ability of the Hipp toggle to provide more power when the clock was subjected to an increased load made it particularly suitable for use in turret clocks, whose hands were exposed to the vagaries of the weather. Hipp also improved the operation of slave dials, which were advanced periodically by an electrical impulse from a master clock. If the electrical contacts "chattered" and produced several impulses instead of a single sharp impulse, the slave dials would not indicate the correct time. Hipp solved this problem by producing master clocks which delivered impulses that alternated in polarity, and slave dials which only advanced when the polarity was changed in this way. Polarized impulses delivered every minute became the standard practice for slave dials used on the European continent. Hipp also improved Wheatstone's chronoscope, an instrument that was used for measuring very short intervals of time (such as those involved in ballistics).

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Principal Honours and Distinctions

Honorary doctorate, University of Zurich 1875.

Further Reading

Neue deutsche Biographie, 1972, Vol. 9, Berlin, pp. 199–200.

"Hipp's sich selbst conrolirende Uhr", Dinglers polytechnisches Journal (1843), 88:258– 64 (the first description of the Hipp toggle).

F.Hope-Jones, 1949, Electrical Timekeeping, 2nd edn, London, pp. 62–6, 97–8 (a modern description in English of the Hipp toggle and the slave dial).

C.A.Aked, 1983, "Electrical precision", Antiquarian Horology 14:172–81 (describes the observatory clock at Neuchâtel).

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Ilgner, Karl

SUBJECT AREA: Electricity

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b. 27 July 1862 Neisse, Upper Silesia (now Nysa, Poland)

d. 18 January 1921 Berthelsdorf, Silesia

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German electrical engineer, inventor of a transformer for electromotors.

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Ilgner graduated from the Gewerbeakademie (the forerunner of the Technical University) in Berlin. As the representative of an electric manufacturing company in Breslau (now Wroclaw, Poland) from 1897, he was confronted with the fact that there were no appropriate drives for hoisting-engines or rolling-plants in steelworks. Two problems prevented the use of high-capacity electric motors in the mining as well as in the iron and steel industry: the reactions of the motors on the circuit at the peak point of stress concentration; and the complicated handling of the control system which raised the risks regarding safety. Having previously been head of the department of electrical power transmission in Hannover, he was concerned with the development of low-speed direct-current motors powered by gas engines.

It was Harry Ward Leonard's switchgear for direct-current motors (USA, 1891) that permitted sudden and exact changes in the speed and direction of rotation without causing power loss, as demonstrated in the driving of a rolling sidewalk at the Paris World Fair of 1900. Ilgner connected this switchgear to a large and heavy flywheel which accumulated the kinetic energy from the circuit in order to compensate shock loads. With this combination, electric motors did not need special circuits, which were still weak, because they were working continuously and were regulated individually, so that they could be used for driving hoisting-engines in mines, rolling-plants in steelworks or machinery for producing tools and paper. Ilgner thus made a notable advance in the general progress of electrification.

His transformer for hoisting-engines was patented in 1901 and was commercially used inter alia by Siemens \& Halske of Berlin. Their first electrical hoisting-engine for the Zollern II/IV mine in Dortmund gained international reputation at the Düsseldorf exhibition of 1902, and is still preserved in situ in the original machine hall of the mine, which is now a national monument in Germany. Ilgner thereafter worked with several companies to pursue his conception, became a consulting engineer in Vienna and Breslau and had a government post after the First World War in Brussels and Berlin until he retired for health reasons in 1919.

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Bibliography

1901, DRP no. 138, 387 1903, "Der elektrische Antrieb von Reversier-Walzenstraßen", Stahl und Eisen 23:769– 71.

Further Reading

W.Kroker, "Karl Ilgner", Neue Deutsche Biographie, Vol. X, pp. 134–5. W.Philippi, 1924, Elektrizität im Bergbau, Leipzig (a general account).

K.Warmbold, 1925, "Der Ilgner-Umformer in Förderanlagen", Kohle und Erz 22:1031–36 (a detailed description).

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Kegel, Karl

SUBJECT AREA: Mining and extraction technology

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b. 19 May 1876 Magdeburg, Germany

d. 5 March 1959 Freiberg, Saxony, Germany

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German professor of mining who established the mining of lignite as a discipline in the science of mining.

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Within the long tradition of celebrated teachers at the Mining Academy in Freiberg, Kegel can be considered as probably the last professor teaching the science of mining who was able to cover all the different disciplines. As was the case with a number of his predecessors, he was able to combine theoretical research work with the teaching of students and to support his theories with the practical experience of industry. He has apprenticed at the Mansfeld copper mines, went to the School of Mines at Eisleben (1896–8), worked as an engineer with various mining companies and thereafter became a scholar of the Berlin Mining Academy (1901–4). For twelve years he taught at the Bochum School of Mining until, in 1918, he was appointed Professor of Mining at Freiberg. There, one year later, as a new approach, he introduced lectures on brown-coal mining and mineral economics. He remained Professor at Freiberg until his first retirement in 1941, although he was active again between 1945 and 1951.

In 1924 Kegel took over a department at the State Research Institute for Brown Coal in Freiberg which he extended into the Institute for Briquetting. In this field his main achievement lies in the initially questioned theory that producing briquettes from lignite is a molecular process rather than the result of bituminous factors. This perception, among others, led Rammler to produce coke from lignite in 1951. Kegel's merits result from having established all the aspects of mining and using lignite as an independent subdiscipline of mining science, based on substantial theories and an innovative understanding of applied technologies.

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Bibliography

1912, Bergmännische Wasserwirtschaft, Halle (Saale). 1931, Lehrbuch der Bergwirtschaft, Berlin.

1941, Bergmännische Gebirgsmechanik, Halle (Saale). 1948, Brikettierung der Braunkohle, Halle (Saale).

1953, Lehrbuch des Braunkohlentagebaus, Halle (Saale).

Further Reading

E.Kroker, "Karl Kegel", Neue deutsche Biographie, Vol. XI, p. 394 (a reliable short account).

Bergakademie Freiberg (ed.), 1976, Karl Kegel 1876–1959. Festschrift aus Anlaß seines

100. Geburtstages, Leipzig (contains substantial biographical information).

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Keller, Friedrich Gottlieb

SUBJECT AREA: Paper and printing

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b. 27 June 1818 Hainichen, Saxony, Germany

d. 8 September 1895 Krippen, Bad Schandau, Germany

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German inventor of wood-pulp paper.

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The son of a master weaver, he originally wished to become an engineer, but while remaining in the parental home he had to follow his father's trade in the textile industry, becoming a master weaver himself in 1839 at Hainichen. He was a good observer and a keen model maker. It was at this stage, in the early 1840s, that he began experimenting with a new material for papermaking. Until then the raw material had been waste rag from the textile industry, but the ever-increasing demands of the mechanical printing presses, especially those producing newspapers, were beginning to outstrip supply. Keller tried using pine wood ground with a wet grindstone. The mass of fibres that resulted was then heated with water to form a thick brew which he then strained through a cloth. By this means Keller obtained a pulp that could be used for papermaking. He constructed a simple grinding machine that could disintegrate the wood without splinters; this was used to make paper in the Altchemnitzer paper mill, and the newspaper Frankenberger Intelligenz-und Wochenblatt was the first to be printed on wood-pulp paper. Keller could not secure state funds to promote his invention, so he approached an expert in papermaking, Heinrich Voelter, Technical Director of the Vereinigten Bautzener Papierfabrik. Voelter put up 700 thaler, and in August 1845 the state of Saxony granted a patent in both their names. In 1848 the first practical machine for grinding wood was produced, but four years later the patent expired. Unfortunately Keller could not afford the renewal fee, and it was Voelter who developed the process of wood-pulp papermaking under his own name, leaving Keller behind. Without this invention, the output of paper from the mills could not have kept pace with the demands of the printing industry, and the mass readership that these technological developments made possible could not have been served. It is no fault of Keller's that wood-pulp paper contains within itself the seeds of its own deterioration and ultimate destruction, presenting librarians of today with an intractable problem of preservation. Keller's part in this technical breakthrough is established in his "ideas" notebook covering the years 1841 and 1842, preserved in the museum at Hainichen.

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Further Reading

Neue deutsche Biographie. VDI Zeitschrift, Vol. 39, p. 1,238.

"EineErfindungvon Weltruf", 1969, VDI Nachrichten. Vol. 29, p. 18.

Clapperton, History ofPapermaking Through the Ages (provides details of the development of wood-pulp papermaking in its historical context).

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Kind, Karl Gotthelf

SUBJECT AREA: Mining and extraction technology

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b. 6 June 1801 Linda, near Freiberg, Germany

d. 9 March 1873 Saarbrücken, Germany

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German engineer, pioneer in deep drilling.

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The son of an ore miner in Saxony, Kind was engaged in his father's profession for some years before he joined Glenck's drillings for salt at Stotternheim, Thuringia. There in 1835, after trying for five years, he self-reliantly put down a 340 m (1,100 ft) deep well; his success lay in his use of fish joints of a similar construction to those used shortly before by von Oeynhausen in Westphalia. In order to improve their operational possibilities in aquiferous wells, in 1842 he developed his own free-fall device between the rod and the drill, which enabled the chisel to reach the bottom of the hole without hindrance. His invention was patented in France. Four years later, at Mondorf, Luxembourg, he put down a 736 m (2,415 ft) deep borehole, the deepest in the world at that time.

Kind contributed further considerable improvements to deep drilling and was the first successfully to replace iron rods with wooden ones, on account of their buoyancy in water. The main reasons for his international reputation were his attempts to bore out shafts, which he carried out for the first time in the region of Forbach, France, in 1848. Three years later he was engaged in the Ruhr area by a Belgian-and English-financed mining company, later the Dahlbusch mining company in Gelsenkirchen, to drill a hole that was later enlarged to 4.4 m (14 1/2 ft) and made watertight by lining. Although he had already taken out a patent for boring and lining shafts in 1849 in Belgium, his wooden support did not qualify. It was the Belgian engineer Joseph Chaudron, in charge of the mining company, who overcame the difficulty of making the bottom of the borehole watertight. In 1854 they jointly founded a shaft-sinking company in Brussels which specialized in aquiferous formations and operated internationally.

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Principal Honours and Distinctions

Chevalier de la Légion d'honneur 1849.

Bibliography

1842, Anleitung zum Abteufen von Bohrlöchern, Luxembourg.

Further Reading

H.G.Conrad, "Carl Gotthelf Kind", Neue deutsche Biographie 10:613–14.

D.Hoffmann, 1959, 150 Jahre Tiefbohrungen in Deutschland, Vienna and Hamburg, pp. 20–5 (assesses his technological achievements).

T.Tecklenburg, 1914, Handbuch der Tiefbohrkunde, 2nd end, Vol. VI, Berlin, pp. 36–9 (provides a detailed description of his equipment).

J.Chaudron, 1862, "Über die nach dem Kindschen Erdbohrverfahren in Belgien ausgeführten Schachtbohrarbeiten", Berg-und Hüttenmännische Zeitung 21:402–4, (describes his contribution to making Kind's shafts watertight).

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