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61 usinage
yzinaʒnom masculin1) ( fabrication avec une machine-outil) machining2) ( fabrication industrielle) manufacture* * *yzinaʒ nm1) [pièce, bois, métal] machining2) (= fabrication) manufacture* * *usinage nm1 ( fabrication avec une machine-outil) machining;2 ( fabrication industrielle) manufacture.[yzinaʒ] nom masculin -
62 Babbage, Charles
SUBJECT AREA: Electronics and information technology[br]b. 26 December 1791 Walworth, Surrey, Englandd. 18 October 1871 London, England[br]English mathematician who invented the forerunner of the modern computer.[br]Charles Babbage was the son of a banker, Benjamin Babbage, and was a sickly child who had a rather haphazard education at private schools near Exeter and later at Enfield. Even as a child, he was inordinately fond of algebra, which he taught himself. He was conversant with several advanced mathematical texts, so by the time he entered Trinity College, Cambridge, in 1811, he was ahead of his tutors. In his third year he moved to Peterhouse, whence he graduated in 1814, taking his MA in 1817. He first contributed to the Philosophical Transactions of the Royal Society in 1815, and was elected a fellow of that body in 1816. He was one of the founders of the Astronomical Society in 1820 and served in high office in it.While he was still at Cambridge, in 1812, he had the first idea of calculating numerical tables by machinery. This was his first difference engine, which worked on the principle of repeatedly adding a common difference. He built a small model of an engine working on this principle between 1820 and 1822, and in July of the latter year he read an enthusiastically received note about it to the Astronomical Society. The following year he was awarded the Society's first gold medal. He submitted details of his invention to Sir Humphry Davy, President of the Royal Society; the Society reported favourably and the Government became interested, and following a meeting with the Chancellor of the Exchequer Babbage was awarded a grant of £1,500. Work proceeded and was carried on for four years under the direction of Joseph Clement.In 1827 Babbage went abroad for a year on medical advice. There he studied foreign workshops and factories, and in 1832 he published his observations in On the Economy of Machinery and Manufactures. While abroad, he received the news that he had been appointed Lucasian Professor of Mathematics at Cambridge University. He held the Chair until 1839, although he neither resided in College nor gave any lectures. For this he was paid between £80 and £90 a year! Differences arose between Babbage and Clement. Manufacture was moved from Clement's works in Lambeth, London, to new, fireproof buildings specially erected by the Government near Babbage's house in Dorset Square, London. Clement made a large claim for compensation and, when it was refused, withdrew his workers as well as all the special tools he had made up for the job. No work was possible for the next fifteen months, during which Babbage conceived the idea of his "analytical engine". He approached the Government with this, but it was not until eight years later, in 1842, that he received the reply that the expense was considered too great for further backing and that the Government was abandoning the project. This was in spite of the demonstration and perfectly satisfactory operation of a small section of the analytical engine at the International Exhibition of 1862. It is said that the demands made on manufacture in the production of his engines had an appreciable influence in improving the standard of machine tools, whilst similar benefits accrued from his development of a system of notation for the movements of machine elements. His opposition to street organ-grinders was a notable eccentricity; he estimated that a quarter of his mental effort was wasted by the effect of noise on his concentration.[br]Principal Honours and DistinctionsFRS 1816. Astronomical Society Gold Medal 1823.BibliographyBabbage wrote eighty works, including: 1864, Passages from the Life of a Philosopher.July 1822, Letter to Sir Humphry Davy, PRS, on the Application of Machinery to the purpose of calculating and printing Mathematical Tables.Further Reading1961, Charles Babbage and His Calculating Engines: Selected Writings by Charles Babbage and Others, eds Philip and Emily Morrison, New York: Dover Publications.IMcN -
63 Lawrence, Richard Smith
SUBJECT AREA: Weapons and armour[br]b. 22 November 1817 Chester, Vermont, USAd. 10 March 1892 Hartford, Connecticut, USA[br]American gunsmith and inventor.[br]Richard S.Lawrence received only an elementary education and as a young man worked on local farms and later in a woodworking shop. His work there included making carpenters' and joiners' tools and he spent some of his spare time in a local gunsmith's shop. After a brief period of service in the Army, he obtained employment in 1838 with N.Kendall \& Co. of Windsor, Vermont, making guns at the Windsor prison. Within six months he was put in charge of the work, continuing in this position until 1842 when the gun-making ceased; he remained at the prison for a time in charge of the carriage shop. In 1843 he opened a gun shop in Windsor in partnership with Kendall, and the next year S.E. Robbins, a businessman, helped them obtain a contract from the Federal Government for 10,000 rifles. A new company, Robbins, Kendall \& Lawrence, was formed and a factory was built at Windsor. Three years later Kendall's share of the business was purchased by his partners and the firm became Robbins \& Lawrence. Lawrence supervised the design and production and, to improve methods of manufacture, developed new machine tools with the aid of F.W. Howe. In 1850 Lawrence introduced the lubrication of bullets, which practice ensured the success of the breech-loading rifle. Also in 1850, the company undertook to manufacture railway cars, but this involved them in a considerable financial loss. The company took to the Great Exhibition of 1851 in London, England, a set of rifles built on the interchangeable system. The interest this created resulted in a visit of some members of the British Royal Small Arms Commission to America and subsequently an order for 150 machine tools, jigs and fixtures from Robbins \& Lawrence, to be installed at the small-arms factory at Enfield. In 1852 the company contracted to manufacture Sharps rifles and carbines at a new factory to be built at Hartford, Connecticut. Lawrence moved to Hartford in 1853 to superintend the building and equipment of the plant. Shortly afterwards, however, a promised order for a large number of rifles failed to materialize and, following its earlier financial difficulties, Robbins \& Lawrence was forced into bankruptcy. The Hartford plant was acquired by the Sharps Rifle Company in 1856 and Lawrence remained there as Superintendent until 1872. From then he was for many years Superintendent of Streets in the city of Hartford and he also served on the Water Board, the Board of Aldermen and as Chairman of the Fire Board.[br]Further ReadingJ.W.Roe, 1916, English and American Tool Builders, New Haven; repub. 1926, New York; and 1987, Bradley, Ill. (provides biographical information and includes in an Appendix (pp. 281–94) autobiographical notes written by Richard S.Lawrence in 1890).Merritt Roe Smith, 1974, "The American Precision Museum", Technology and Culture 15 (3): 413–37 (for information on Robbins \& Lawrence and products).RTSBiographical history of technology > Lawrence, Richard Smith
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64 herstellen
herstellen v 1. GEN make, establish, build up, create (Kontakt, Beziehung); 2. IND make, fabricate, manufacture, produce (Produkt)* * *v 1. < Geschäft> Kontakt, Beziehung make, establish, build up, create; 2. < Ind> Produkt make, fabricate, manufacture, produce* * *herstellen
to make, to fabricate, to manufacture, to produce, to turn (put) out;
• Beziehungen herstellen to establish relations;
• Erfindungsgegenstand herstellen to produce an invention;
• in der Hauptsache für den Export herstellen to produce mainly for export;
• fabrikmäßig herstellen to manufacture, (Hausteile) to prefabricate;
• Gebäude wieder herstellen to restore a ruined building;
• Geschäftsbeziehungen zu jem. herstellen to establish business relations with s. o.;
• wirtschaftliches Gleichgewicht herstellen to establish an economic balance;
• Kontakt mit jem. herstellen to establish contact with s. o.;
• künstlich herstellen to synthesize;
• lagermäßig herstellen to make for stock;
• maschinell herstellen to machine;
• als Massenartikel herstellen to mass-produce;
• in der Minute 100 Stück herstellen to turn out a hundred a minute;
• Produkte maschinenmäßig herstellen to produce goods by machinery;
• serienmäßig herstellen to serialize;
• Verbindung mit jem. herstellen to make contact with s. o.;
• Waren herstellen to turn goods;
• Waren verschiedenster Beschaffenheit (Qualität) herstellen to manufacture goods in various qualities;
• Waren ohne außerbetriebliche Kräfte herstellen to manufacture articles without exterior help;
• zusammen herstellen to co-produce;
• Produktionsaufträge in einem fremden Werk herstellen lassen to hive off production. -
65 artefacto
m.1 device.artefacto explosivo explosive device2 appliance, mechanism, gimmick, artifact.* * *1 device, appliance (explosivo) explosive device2 (en arqueología) artefact* * *SM1) (Téc) device, applianceartefacto explosivo — bomb, explosive device
artefacto infernal — bomb, explosive device
artefactos de alumbrado — light fittings, light fixtures
artefactos del baño — Arg, Uru bathroom fixtures
2) (Arqueología) artefact, artifact (EEUU)3) (Aut) * old crock, jalopy *, old banger ** * ** * *= artefact [artifact], artifact [artefact], whatchamacallit, gizmo [gismo], contraption.Ex. An artefact is any object made or modified by man.Ex. There is also a review by Ken Bierman of the future of the catalog insofar as it is a physical artifact.Ex. In his book's section ' Watchamacallit' he forecasts that communication between user and machine will be through voice for entering text and a pen-like device for pointing.Ex. Within, you will find a pleathora of gadgets and gizmos, ranging from the ridiculous to the sublime.Ex. If you are in cahoots with the circle of power, you get your projects approved in no time, and in some cases, you can build the most hideous and unsightly contraption.----* artefacto explosivo = explosive device.* fabricar un artefacto = manufacture + artifact.* * ** * *= artefact [artifact], artifact [artefact], whatchamacallit, gizmo [gismo], contraption.Ex: An artefact is any object made or modified by man.
Ex: There is also a review by Ken Bierman of the future of the catalog insofar as it is a physical artifact.Ex: In his book's section ' Watchamacallit' he forecasts that communication between user and machine will be through voice for entering text and a pen-like device for pointing.Ex: Within, you will find a pleathora of gadgets and gizmos, ranging from the ridiculous to the sublime.Ex: If you are in cahoots with the circle of power, you get your projects approved in no time, and in some cases, you can build the most hideous and unsightly contraption.* artefacto explosivo = explosive device.* fabricar un artefacto = manufacture + artifact.* * *(instrumento) artefact; (dispositivo) deviceun artefacto incendiario an incendiary deviceCompuestos:voy a cambiar los artefactos del baño I'm going to get a new bathroom suite* * *
artefacto sustantivo masculino ( instrumento) artifact;
( dispositivo) device;
un raro artefacto a contraption
artefacto m (dispositivo) device
' artefacto' also found in these entries:
Spanish:
cierre
- desmontar
- desmontable
- explotar
English:
artifact
- artefact
- device
* * *artefacto nm1. [aparato] device;[máquina] machine;artefacto explosivo/incendiario explosive/incendiary deviceCSur artefactos de baño bathroom fixtures; RP artefacto eléctrico electrical household appliance; RP artefactos de iluminación light fittings and fixtures; CSur artefactos sanitarios bathroom fixtures2. [armatoste] contraption* * *m ( dispositivo) device* * *artefacto nm1) : artifact2) dispositivo: device* * *artefacto n device -
66 time
время; период; продолжительность || устанавливать время; распределять время; рассчитывать по времени; согласовывать во времени; синхронизироватьtime in use — время использования; время работы (напр. инструмента)
time on machine — время пребывания ( обрабатываемой детали) на станке
- acceleration timeto cut time — сокращать время (напр. обработки)
- access time
- activation time
- active maintenance time
- active repair time
- activity time
- actual in-cut time
- addition time
- additional time
- adjustable laser ramp-up time
- administrative time
- aggregate travel time
- air-cutting time
- arcing time of pole
- assembly time
- assessed mean time to failure
- ATC time
- attended running time
- attenuation time
- auxiliary time
- available machine time
- available machining time
- available time
- average access time
- average time
- base cycle time
- batch change time
- batch lead time
- batch run time
- block execution time
- block processing time
- bounce time
- braking time to standstill
- braking time
- break time
- breakdown time
- bridging time
- build time
- build-up time
- cam idle time
- cell production time
- changeover cut-to-cut time
- changeover time
- characteristic time
- charge time
- chip-cutting time
- chip-making time
- chip-to-chip toolchange time
- clock cycle time
- closing time
- combined travel/load time
- commissioning time
- component cycle time
- component inspection time
- component time
- computed machine time
- computing time
- control flow time
- control time
- conversion time
- correction time
- corrective maintenance time
- c-percentile storageability time
- c-percentile time to failure
- cumulative cutting time
- cure time
- current fall time
- current rise time
- cut time
- cutting time
- cut-to-cut time
- cycle time
- dead cycle time
- dead time
- debugging time
- delay time
- delivery time
- depalletizing time
- derivative action time
- derricking time
- detection time
- direct manufacture time
- disengaging time
- division time
- door-to-door time
- double-stroke time
- down time
- dry-cycle time
- dwell time
- effective cutting time
- effective dead time
- empty running time
- end-of-job time
- equispaced times
- equivalent running time for wear
- eroding time
- erosion time
- estimation time
- execution time
- exposure time
- fall time
- fast response time
- finishing time
- first-off machining time
- fitting time
- fixture lead time
- floor-to-floor time
- flow time
- forward recovery time
- frame time
- full brazing time
- full operating time
- full soldering time
- gate controlled turn-off delay time
- gate controlled turn-off fall time
- gate controlled turn-off time
- grinding time
- gripper-changing time
- head-changing time
- hobbing time
- holding time
- idle time
- index time
- indexing time
- innovation time
- in-process time
- integral action time
- interarrival time
- interoperation time
- interpolation delay time
- jaw-adjusting time
- job completion time
- job finish time
- laser interaction time
- laser shutter opening time
- laser weld tempering time
- laser-beam dwell time
- laser-beam interaction time
- lead time
- learning time
- loading time
- machine down time
- machine repair time
- machine run time
- machine slack time
- machine wait time
- machine-setting time
- machine-setup time
- machining floor-to-floor time
- machining time
- machining-cycle time
- maintenance down time
- maintenance time
- make time
- manual machining time
- manufacturing cycle time
- manufacturing lead time
- material to end product lead time
- maximum resetting time
- mean time between failures
- mean time to failure
- mean time to repair
- measuring run time
- metal-to-metal time
- minimum accelerating time
- minimum braking time
- move time
- moving time
- multiplication time
- NC machining time
- NC program debug time
- no-failure operating time
- noncut time
- noncutting time
- nonmachining time
- nonproductive machine time
- nonrequired time
- numerical processing time
- observed mean time to failure
- off-machine process time
- off-shift machine down time
- off-shift slack time
- opening time
- operate time
- operating spindle time
- operating time
- operation cycle time
- operation time
- operator's attention time
- operator's reaction time
- operator's time
- optimized contact time
- out-of-cut machine time
- out-of-cut time
- output cycle time
- overall cycle time
- overall lead time
- pallet change time
- pallet processing time
- pallet shuttle time
- parasitic time
- part turnaround time
- partial operating time
- part-waiting time
- payback time
- periodic time
- pickup time
- piece sequence time
- piece time
- planned loading time
- planning lead time
- planning time
- predicted mean time to failure
- preparatory time
- preset operating time before corrective adjustment
- preset operating time
- preset time
- probing time
- process response time
- process time
- processing time
- product development lead time
- product flow time
- product lead time
- production lead time
- production time per piece
- production time per unit
- production time
- productive time
- profiling time
- programming time
- prorated time
- protective power time
- pulse decay time
- pulse response time
- pulse rise time
- pulse time
- queue time
- queueing time
- rapid response time
- reading time
- readout time
- real time
- rechucking time
- recognition time
- recovery time
- release time
- releasing time
- remaining life time
- repair/down cost time
- required time
- reset time
- residence time of materials
- response time
- restoration time
- return time
- reverse recovery current fall time
- reverse recovery current rise time
- reverse recovery time
- rise time
- robot down time
- roughing time
- run time
- running time
- running-in time
- safety lead time
- sampling time
- scan time
- schedule time
- scheduled time
- sensing time
- series machining time
- service time of the tool
- servicing time
- servo update time
- setter time
- setting time
- settling time
- setup time
- ship time
- slack time
- soaking time
- software execution time
- specified no-failure operating time
- specified operating time
- specified time
- spindle cutting time
- spindle run time
- stabilization time
- stand time
- standard handling time
- standard piece time
- starting time
- start-up time
- station time
- station-to-station time
- step response time
- stopping time
- storage cycle time
- storage time
- storageability time
- switching time
- switch-over time
- system time
- table-indexing time
- tape-preparation time
- tape-turnaround time
- target build time
- target time
- teach time
- throughput time
- time of starting
- tool change time
- tool exchange time
- tool index time
- tool life time
- tool-cutting time
- tool-in-cut time
- tooling-response time
- tool-setup time
- tool-to-tool changing time
- total access time
- total changeover time
- total equivalent running time for strength
- total equivalent running time for wear
- total manufacturing cycle time
- total running time
- total sequence time
- to-the-minute time
- transfer time
- transient time
- transit time
- transition time
- traveling time
- turnaround time
- turn-off time
- turn-on time
- undetected failure time
- unit cycle time
- unit production time
- unit time
- up time
- update time
- updating time
- vehicle time per hour
- vehicle-use time
- waiting time
- wakeup time
- warm-up time
- wasted time
- work-change time
- work-cycle time
- work-in-process time
- wrench time
- zero ATC timeEnglish-Russian dictionary of mechanical engineering and automation > time
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67 Thimmonier, Barthélémy
[br]b. 1793 Saint-Etienne, France d. 1857[br]French inventor of the first sewing machine.[br]The sewing machine is probably the most universal and the most important machine in clothing manufacture, being used both industrially and domestically. It was also the first domestic consumer durable and was the first mass-produced machine to appear in the home. The first practical sewing machine was built during 1828 and 1829 by Barthélémy Thimmonier, a working tailor of Saint-Etienne in France. He came from a modest family and had never received any training as a mechanic, so his invention is all the more remarkable. He took out a patent in 1830 in his own name and that of Ferrand, a tutor of the Saint-Etienne School of Mines who had helped him financially. It was a chain-stitch machine made largely of wood and operated by a foot pedal with a large flywheel. The needle moved up and down through the cloth, which was placed on a platform below it. A second, hooked needle under the platform made a loop in the thread, which was caught when the first needle descended again.In 1841, Thimmonier was appointed to a senior position in a large Paris clothing factory engaged in the production of French army uniforms. He soon had eighty machines in use, but a mob of hand-sewers broke in, smashed the machines and nearly killed Thimmonier. In 1845, he had developed his machine so that it could make 200 stitches per minute and formed a partnership with Jean-Marie Magnin to build them commercially. However, the abdication of Louis Philippe on 21 February 1848 ended his hopes, even though patents were taken out in the UK and the USA in that year. The English patent was in Magnin's name, and Thimmonier died impoverished in 1857. His machine was perfected by many later inventors.[br]Bibliography1830, with Ferrand, (chain-stitch machine).Further ReadingA.Matagran, 1931, "Barthélémy Thimmonier (1793–1857), inventeur de la machine à coudre", Bull. Soc. Enc. Industr. nat. 130 (biography in French).J.Meyssin, 1914, Histoire de la machine à coudre: portrait et biographie de l'inventeur B.Thimmonier, 5th edn, Lyons (biography in French).M.Daumas, (ed.), 1968, Histoire générale des techniques, Vol. III: L'Expansion du machinisme, Paris (includes a description of Thimmonier's machine, with a picture).N.Salmon, 1863, History of the Sewing Machine from the Year 1750 (tells the history of the sewing machine).F.B.Jewell, 1975, Veteran Sewing Machines. A Collector's Guide, Newton Abbot (a more modern account).RLH -
68 Cartwright, Revd Edmund
[br]b. 24 April 1743 Marnham, Nottingham, Englandd. 30 October 1823 Hastings, Sussex, England[br]English inventor of the power loom, a combing machine and machines for making ropes, bread and bricks as well as agricultural improvements.[br]Edmund Cartwright, the fourth son of William Cartwright, was educated at Wakefield Grammar School, and went to University College, Oxford, at the age of 14. By special act of convocation in 1764, he was elected Fellow of Magdalen College. He married Alice Whitaker in 1772 and soon after was given the ecclesiastical living of Brampton in Derbyshire. In 1779 he was presented with the living of Goadby, Marwood, Leicestershire, where he wrote poems, reviewed new works, and began agricultural experiments. A visit to Matlock in the summer of 1784 introduced him to the inventions of Richard Arkwright and he asked why weaving could not be mechanized in a similar manner to spinning. This began a remarkable career of inventions.Cartwright returned home and built a loom which required two strong men to operate it. This was the first attempt in England to develop a power loom. It had a vertical warp, the reed fell with the weight of at least half a hundredweight and, to quote Gartwright's own words, "the springs which threw the shuttle were strong enough to throw a Congreive [sic] rocket" (Strickland 19.71:8—for background to the "rocket" comparison, see Congreve, Sir William). Nevertheless, it had the same three basics of weaving that still remain today in modern power looms: shedding or dividing the warp; picking or projecting the shuttle with the weft; and beating that pick of weft into place with a reed. This loom he proudly patented in 1785, and then he went to look at hand looms and was surprised to see how simply they operated. Further improvements to his own loom, covered by two more patents in 1786 and 1787, produced a machine with the more conventional horizontal layout that showed promise; however, the Manchester merchants whom he visited were not interested. He patented more improvements in 1788 as a result of the experience gained in 1786 through establishing a factory at Doncaster with power looms worked by a bull that were the ancestors of modern ones. Twenty-four looms driven by steam-power were installed in Manchester in 1791, but the mill was burned down and no one repeated the experiment. The Doncaster mill was sold in 1793, Cartwright having lost £30,000, However, in 1809 Parliament voted him £10,000 because his looms were then coming into general use.In 1789 he began working on a wool-combing machine which he patented in 1790, with further improvements in 1792. This seems to have been the earliest instance of mechanized combing. It used a circular revolving comb from which the long fibres or "top" were. carried off into a can, and a smaller cylinder-comb for teasing out short fibres or "noils", which were taken off by hand. Its output equalled that of twenty hand combers, but it was only relatively successful. It was employed in various Leicestershire and Yorkshire mills, but infringements were frequent and costly to resist. The patent was prolonged for fourteen years after 1801, but even then Cartwright did not make any profit. His 1792 patent also included a machine to make ropes with the outstanding and basic invention of the "cordelier" which he communicated to his friends, including Robert Fulton, but again it brought little financial benefit. As a result of these problems and the lack of remuneration for his inventions, Cartwright moved to London in 1796 and for a time lived in a house built with geometrical bricks of his own design.Other inventions followed fast, including a tread-wheel for cranes, metallic packing for pistons in steam-engines, and bread-making and brick-making machines, to mention but a few. He had already returned to agricultural improvements and he put forward suggestions in 1793 for a reaping machine. In 1801 he received a prize from the Board of Agriculture for an essay on husbandry, which was followed in 1803 by a silver medal for the invention of a three-furrow plough and in 1805 by a gold medal for his essay on manures. From 1801 to 1807 he ran an experimental farm on the Duke of Bedford's estates at Woburn.From 1786 until his death he was a prebendary of Lincoln. In about 1810 he bought a small farm at Hollanden near Sevenoaks, Kent, where he continued his inventions, both agricultural and general. Inventing to the last, he died at Hastings and was buried in Battle church.[br]Principal Honours and DistinctionsBoard of Agriculture Prize 1801 (for an essay on agriculture). Society of Arts, Silver Medal 1803 (for his three-furrow plough); Gold Medal 1805 (for an essay on agricultural improvements).Bibliography1785. British patent no. 1,270 (power loom).1786. British patent no. 1,565 (improved power loom). 1787. British patent no. 1,616 (improved power loom).1788. British patent no. 1,676 (improved power loom). 1790, British patent no. 1,747 (wool-combing machine).1790, British patent no. 1,787 (wool-combing machine).1792, British patent no. 1,876 (improved wool-combing machine and rope-making machine with cordelier).Further ReadingM.Strickland, 1843, A Memoir of the Life, Writings and Mechanical Inventions of Edmund Cartwright, D.D., F.R.S., London (remains the fullest biography of Cartwright).Dictionary of National Biography (a good summary of Cartwright's life). For discussions of Cartwright's weaving inventions, see: A.Barlow, 1878, The History and Principles of Weaving by Hand and by Power, London; R.L. Hills, 1970, Power in the Industrial Revolution, Manchester. F.Nasmith, 1925–6, "Fathers of machine cotton manufacture", Transactions of theNewcomen Society 6.H.W.Dickinson, 1942–3, "A condensed history of rope-making", Transactions of the Newcomen Society 23.W.English, 1969, The Textile Industry, London (covers both his power loom and his wool -combing machine).RLHBiographical history of technology > Cartwright, Revd Edmund
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69 Paul, Lewis
SUBJECT AREA: Textiles[br]d. April 1759 Brook Green, London, England[br]English inventor of hand carding machines and partner with Wyatt in early spinning machines.[br]Lewis Paul, apparently of French Huguenot extraction, was quite young when his father died. His father was Physician to Lord Shaftsbury, who acted as Lewis Paul's guardian. In 1728 Paul made a runaway match with a widow and apparently came into her property when she died a year later. He must have subsequently remarried. In 1732 he invented a pinking machine for making the edges of shrouds out of which he derived some profit.Why Paul went to Birmingham is unknown, but he helped finance some of Wyatt's earlier inventions. Judging by the later patents taken out by Paul, it is probable that he was the one interested in spinning, turning to Wyatt for help in the construction of his spinning machine because he had no mechanical skills. The two men may have been involved in this as early as 1733, although it is more likely that they began this work in 1735. Wyatt went to London to construct a model and in 1736 helped to apply for a patent, which was granted in 1738 in the name of Paul. The patent shows that Paul and Wyatt had a number of different ways of spinning in mind, but contains no drawings of the machines. In one part there is a description of sets of rollers to draw the cotton out more finely that could have been similar to those later used by Richard Arkwright. However, it would seem that Paul and Wyatt followed the other main method described, which might be called spindle drafting, where the fibres are drawn out between the nip of a pair of rollers and the tip of the spindle; this method is unsatisfactory for continuous spinning and results in an uneven yarn.The spinning venture was supported by Thomas Warren, a well-known Birmingham printer, Edward Cave of Gentleman's Magazine, Dr Robert James of fever-powder celebrity, Mrs Desmoulins, and others. Dr Samuel Johnson also took much interest. In 1741 a mill powered by two asses was equipped at the Upper Priory, Birmingham, with, machinery for spinning cotton being constructed by Wyatt. Licences for using the invention were sold to other people including Edward Cave, who established a mill at Northampton, so the enterprise seemed to have great promise. A spinning machine must be supplied with fibres suitably prepared, so carding machines had to be developed. Work was in hand on one in 1740 and in 1748 Paul took out another patent for two types of carding device, possibly prompted by the patent taken out by Daniel Bourn. Both of Paul's devices were worked by hand and the carded fibres were laid onto a strip of paper. The paper and fibres were then rolled up and placed in the spinning machine. In 1757 John Dyer wrote a poem entitled The Fleece, which describes a circular spinning machine of the type depicted in a patent taken out by Paul in 1758. Drawings in this patent show that this method of spinning was different from Arkwright's. Paul endeavoured to have the machine introduced into the Foundling Hospital, but his death in early 1759 stopped all further development. He was buried at Paddington on 30 April that year.[br]Bibliography1738, British patent no. 562 (spinning machine). 1748, British patent no. 636 (carding machine).1758, British patent no. 724 (circular spinning machine).Further ReadingG.J.French, 1859, The Life and Times of Samuel Crompton, London, App. This should be read in conjunction with R.L.Hills, 1970, Power in the Industrial Revolution, Manchester, which shows that the roller drafting system on Paul's later spinning machine worked on the wrong principles.A.P.Wadsworth and J.de L.Mann, 1931, The Cotton Trade and Industrial Lancashire, 1600–1780, Manchester (provides good coverage of the partnership of Paul and Wyatt and the early mills).E.Baines, 1835, History of the Cotton Manufacture in Great Britain, London (this publication must be mentioned, but is now out of date).A.Seymour-Jones, 1921, "The invention of roller drawing in cotton spinning", Transactions of the Newcomen Society 1 (a more modern account).RLH -
70 производство
ср.
1) production, manufacture издержки производства ≈ production costs кустарное производство ≈ handicraft industry ремесленное производство ≈ handicraft industry серийное производство ≈ repetition work массовое производство ≈ repetition work плановое производство ≈ planned production сталелитейное производство ≈ steel industry производство станков ≈ machine-tool industry стекольное производство ≈ glass-work гончарное производство ≈ ceramics средства производства ≈ means of production
2) plant, works, factory
3) (выполнение) execution
4) воен. promotionпроизводств|о -
1. с. (процесс) production;
(изготовление тж.) manufacture;
импортозамещающее ~ import-substituting production;
кооперированное ~ cooperative production;
крупносерийное ~ long/high-run production, large lot/large scale production;
массовое ~ high-volume production;
мелкосерийное ~ short-run/job-lot/limited production;
незавершённое ~ incomplete production;
отечественное ~ domestic production;
поточное ~ in line production;
прибыльное ~ profitable production;
серийное ~ production in bulk, gross production;
совместное ~ joint production;
экспортное ~ export production;
~ киноплёнки film manufacture;
средства ~а means of production;
~ стали steel manufacture;
~ бумаги рaреr production;
2. (отрасль промышленности) industry;
сталелитейное ~ steel industry;
3. (фабрика, завод) factory;
работать на ~е work at а factory/plant;
4. воен. (присвоение звания) promotion.Большой англо-русский и русско-английский словарь > производство
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71 Erzeugnis
Erzeugnis n GEN, IND product* * *n <Geschäft, Ind> product* * *Erzeugnis
produce, product[ion], manufacture, article, merchandise, turnout, make, work;
• Erzeugnisse wares;
• vom Einkommen des Durchschnittsverbrauchers abhängige Erzeugnisse responsive products;
• arbeitsintensive Erzeugnisse labo(u)r-intensive products;
• ausländische Erzeugnisse foreign-made products, articles of foreign manufacture;
• zum Verkauf bereitstehende Erzeugnisse products available for sale;
• deutsches Erzeugnis manufactured (made) in Germany;
• unser eigenes Erzeugnis domestic product;
• einheimisches Erzeugnis inland (domestic, home) produce, native product;
• einziges Erzeugnis sole product;
• englische Erzeugnisse goods of British production;
• fehlerhafte Erzeugnisse bad items, irregulars;
• fertiges Erzeugnis finished product;
• freie Erzeugnisse natural products;
• fremdländische Erzeugnisse goods of foreign origin;
• geistiges Erzeugnis brain child;
• genmanipulierte Erzeugnisse genetically modified products;
• gewerbliches Erzeugnis factory (industrial, manufactured) product;
• halb fertiges Erzeugnis semi-manufactured product;
• halb fertige Erzeugnisse (Bilanz) work in process (Br.) (progress, US);
• halb fertige und fertige Erzeugnisse (Bilanz) work in process and finished goods;
• maschinell hergestellte Erzeugnisse machine-made products;
• hoch qualifizierte Erzeugnisse high-quality (-class) goods, high-quality products, big-ticket items;
• hochwertige Erzeugnis high-value goods;
• industrielles Erzeugnis industrial product, manufacture, manufactured article;
• inländische Erzeugnisse home products (manufacture), domestics, native products, domestic articles;
• keramische Erzeugnisse pottery;
• kriegswichtige Erzeugnisse war goods;
• ladeneigenes Erzeugnis store-brand item (US);
• landwirtschaftliche Erzeugnisse agricultural commodities (produce), [farm] produce;
• literarische Erzeugnisse literary production;
• markenpflichtige Erzeugnisse coupon goods;
• minderwertige Erzeugnisse poor quality goods, inferior products;
• nachgeahmtes Erzeugnis counterfeit (imitative) product;
• patentiertes Erzeugnis patented article (product, item);
• preisgebundene Erzeugnisse price-bound merchandise;
• preisgestützte Erzeugnisse price-maintained goods;
• preisstabile Erzeugnisse price-maintained products (articles);
• nicht sortierte Erzeugnisse non-graded products;
• steuerpflichtiges Erzeugnis taxable product;
• teures Erzeugnis high-priced line;
• tiefgekühlte Erzeugnisse frozen goods;
• veredelte Erzeugnisse improved goods, finished products;
• ganzjährig zu verkaufendes Erzeugnis all-season product (US);
• schwer verkäufliches Erzeugnis hard-to-move product;
• vermietete Erzeugnisse products on lease;
• mit falschen Warenzeichen versehene Erzeugnisse misbranded products (US);
• versicherte Erzeugnisse insured goods;
• weggeworfene Erzeugnisse throwaway products;
• zollempfindliche Erzeugnisse sensitive products;
• Erzeugnisse aller Art goods, wares and merchandise;
• Erzeugnisse eines bestreikten Betriebes hot cargo;
• Erzeugnisse in der Fabrikation (Bilanz) work in progress (US) (process, Br.);
• Erzeugnisse der besten Güteklasse firsts;
• Erzeugnisse französischer Herkunft goods of French origin;
• Erzeugnisse eines Landes products of a country;
• Erzeugnisse des ökologischen Landbaus organic produce;
• Erzeugnisse mit gleich bleibenden Preisen price-maintained goods (articles);
• landwirtschaftliche Erzeugnisse, die keiner Produktionssteuerung bedürfen non-basic commodities;
• Erzeugnisse des Rindfleischsektors products in the beef chain;
• Erzeugnisse der Spitzentechnologie high-skill manufactures;
• Erzeugnis pflanzlichen Ursprungs vegetable product;
• Erzeugnis tierischen Ursprungs product of animal origin;
• Erzeugnisse mit hoher Zuverlässigkeit high-reliable products;
• Erzeugnisse absetzen to market products;
• Erzeugnis fördern to merchandise;
• Erzeugnisse aller Preisklassen führen to carry a full-price range;
• Erzeugniskontrolle durch den Auftraggeber im Herstellungsbetrieb source inspection;
• Erzeugniskostenrechnung product cost accounting;
• Erzeugnispalette production population;
• Erzeugniswerbung product advertising. -
72 construction
construction [kɔ̃stʀyksjɔ̃]feminine nouna. ( = action) constructionb. [de phrase] structurec. ( = édifice, bâtiment) building* * *kɔ̃stʀyksjɔ̃1) gén building2) Économie ( secteur industriel)3) Industrie manufacture4) Politique, Linguistique, Mathématique construction5) ( élaboration) construction* * *kɔ̃stʀyksjɔ̃ nf1) [pont, immeuble] construction, buildingen construction (maisons, immeubles) — under construction
site en construction INTERNET — site under construction
2) (= immeuble) building* * *construction nf1 ( bâtiment) building; les constructions gâchent le paysage the buildings ruin the landscape;2 ( édification) building; encourager la construction de logements et de routes to promote the building of housing and roads; en (cours de) construction under construction; bâtiment de construction ancienne/récente old/recent building;3 Écon ( secteur industriel) la construction the construction industry; secteur de la construction construction sector; entreprise de construction construction company;4 Ind manufacture; construction de moteurs engine manufacture; de construction japonaise made in Japan; construction aéronautique aircraft manufacturing; construction automobile car manufacturing; construction électrique electrical engineering; construction ferroviaire railway construction; construction mécanique mechanical engineering; construction navale shipbuilding;5 Pol construction; construction européenne/du socialisme construction of Europe/of socialism;7 Psych reconstruction;8 ( élaboration) construction; une pure construction de l'esprit pure imagination.[kɔ̃stryksjɔ̃] nom fémininla construction de la tour a duré un an it took a year to build ou to erect the tower[entreprise]————————de construction locution adjectivale2. JEUX————————en construction locution adverbialela maison est encore en construction the house is still being built ou still under construction -
73 produrre
"to produce;Herstellen;fabricar"* * *producedanni cause* * *produrre v.tr.1 ( generare, fruttare) to produce; to yield; to bear*; to raise: ( di miniera) to produce, to yield: quest'albero non produce frutti, this tree doesn't bear (o yield) any fruit; questo terreno produce grano, this land yields (o produces) corn; un terreno che produce poco, a piece of land that yields very little; la Spagna produce razze pregiate di ovini, Spain raises top breeds of sheep; questa miniera produce molto carbone, this mine produces (o yields) a lot of coal; produrre calore, to generate heat; l'acqua bollendo produce vapore, boiling water produces steam // le ghiandole endocrine producono ormoni, endocrinal glands produce (o secrete) hormones // il XVI secolo ha prodotto grandi artisti, (fig.) the 16th century produced a number of great artists // (fin.): produrre un interesse, to bear interest; produrre utili, to yield profits2 ( fabbricare) to produce, to make*, to manufacture, to turn out: questa fabbrica produce articoli di porcellana, this factory produces (o makes o manufactures) chinaware; questa macchina può produrre centinaia di fogli di carta al minuto, this machine can turn out hundreds of sheets of paper a minute; produrre centinaia di automobili al giorno, to produce (o to turn out) hundreds of cars a day // (econ.): produrre in eccesso, to overproduce; produrre in quantità insufficiente, to underproduce; produrre in serie, to mass-produce; produrre industrialmente, to manufacture3 (di scrittore, artista, produttore cinematografico ecc.) to produce: produce un romanzo all'anno, he produces (o brings out) a novel every year; questo scrittore ha prodotto poco negli ultimi anni, this writer has produced very little in the last few years; produrre una commedia, un film, to produce a play, a film4 ( causare, originare) to cause, to give* rise to (sthg.), to produce: l'esplosione fu prodotta dalla temperatura troppo alta, the explosion was caused by the excessive temperature; la pioggia produsse gravi danni, the rain caused great damage; alcuni cibi producono danni all'organismo, some foodstuffs have (o produce) harmful effects on one's organism; cadendo si è prodotto una ferita alla testa, he fell and cut his head; la sua condotta produsse molti guai, his behaviour gave rise to a lot of trouble; produrre l'effetto contrario, to produce the opposite effect; produrre un'emozione, to cause (o to give rise to) excitement (o an emotion); produrre un'impressione favorevole, to produce (o to create) a favourable impression5 ( esibire) to show, to exhibit, to produce: produrre il biglietto, to show one's ticket; produrre documenti, to produce (o to exhibit) documents // (dir.): produrre una prova, to introduce a piece of evidence; produrre un testimonio, to produce (o to call o to bring forward) a witness.◘ prodursi v.rifl. ( esibirsi) to appear: si è prodotto in una delle sue migliori interpretazioni di Amleto, he appeared in one of his best interpretations of Hamlet; egli si produsse nella parte di Amleto, he played Hamlet; produrre sulla scena, to appear on the stage◆ v.intr.pron. ( accadere) to happen, to occur, to come* about: i mutamenti che si sono prodotti negli ultimi anni, the changes that have come about in the last few years.* * *[pro'durre] 1.verbo transitivo1) (fabbricare) to produce, to manufacture, to turn out [beni, merci]2) agr. to bear*, to produce, to yield [frutti, raccolto]3) (generare, provocare) to produce [calore, effetto, elettricità, energia, suono]; to generate, to produce [ guadagno]4) cinem. mus. teatr. telev. to produce5) (creare) [era, paese] to produce [artista, scienziato]6) dir. to bring* forward [ testimone]2.produrre qcs. come prova — to produce sth. as proof
verbo pronominale prodursi1) [buco, rottura] to develop; [ situazione] to happen, to come* along2)* * *produrre/pro'durre/ [13]1 (fabbricare) to produce, to manufacture, to turn out [ beni, merci]; produrre in serie to mass- produce2 agr. to bear*, to produce, to yield [frutti, raccolto]3 (generare, provocare) to produce [calore, effetto, elettricità, energia, suono]; to generate, to produce [ guadagno]4 cinem. mus. teatr. telev. to produce5 (creare) [era, paese] to produce [artista, scienziato]; produrre un'opera d'arte to produce a work of artII prodursi verbo pronominale1 [buco, rottura] to develop; [ situazione] to happen, to come* along2 - rsi una ferita to cause oneself an injury. -
74 Thomas, William
SUBJECT AREA: Textiles[br]fl. 1850 London, England[br]English patentee of the lock-stitch sewing machine in Britain.[br]William Thomas, of Cheapside, London, was a manufacturer of shoes, umbrellas and corsets. He paid Elias Howe a sum of £250 to secure the British rights of Howe's 1846 patent for the lock-stitch sewing machine. Thomas persuaded Howe to go from the USA to England and apply his machine to the manufacture of shoes and corsets. Howe was to receive £3 per week, and in addition Thomas was to patent the machine in Britain and pay Howe £3 for every machine sold under the British patent. Patents for sewing machines were taken out in the name of W.Thomas in 1846 and 1848, and again in 1849. Howe did travel to Britain but quarrelled with Thomas after less than a year and returned to the USA. In 1853 Thomas started selling his own lock-stitch machine. There are patents in the name of W.F. Thomas for sewing machines, making button-holes bindings, etc., dating from 1853 through to 1864.[br]Bibliography1846, British patent no. 11,464 (sewing machine). 1848, British patent no. 12,221 (sewing machine). 1849, British patent no. 12,736 (sewing machine). 1853, British patent no. 1,026.1855, British patent no. 2,079.1856, British patent no. 740.1856, British patent no. 2,978.1860, British patent no. 1,631.1864, British patent no. 1,609.Further ReadingF.G.Harrison, 1892–3, Biographical Sketches of Pre-eminent Americans (includes an account of Howe's life).F.B.Jewell, 1975, Veteran Sewing Machines. A Collector's Guide, Newton Abbot (makes brief mention of Thomas).RLH -
75 машиностроение
1) General subject: machinery, mechanic engineering, engineering, mechanical engineering, machinery manufacturing2) Engineering: machine building, machine industry, machine-building, machine-building industry, manufacturing engineering3) Railway term: engine building4) Economy: machinery-producing industry, metal fabrication5) Diplomatic term: engineering industries6) Mechanic engineering: millwrighting7) Mechanics: machine construction8) Advertising: mechanical industry9) Business: engineering industry10) Education: machine engineering11) Automation: engineering manufacture, machine (building) industry, mechanical engineering industry12) Makarov: machine manufacturing -
76 обрабатывать
( стругом) blade, ( фотоматериалы) develop, handle, manufacture, treat, work* * *обраба́тывать гл.
work; ( придавать нужные свойства) treat; ( перерабатывать) processобраба́тывать гру́зы — handle goodsобраба́тывать да́нные — process dataобраба́тывать на то́чный разме́р — finish to sizeобраба́тывать на́черно — rough; метал. rough-machineобраба́тывать на́чисто — finish; метал. finish-machineобраба́тывать торе́ц по сфе́ре — machine [shape] the end to a sphereобраба́тывать по шабло́ну — profile [shape] to templateпоясо́к обраба́тывается по скользя́щей поса́дке — the shoulder is machined to a sliding fitобраба́тывать ре́занием ( на станке) — machineобраба́тывать ре́занием заодно́ — machine in blockобраба́тывать ре́занием по кали́бру — machine (accurate) to gaugeобраба́тывать ре́занием по размё́тке — machine to (the) scribe linesобраба́тывать ре́занием (то́чно) по чертежу́ — machine (accurate) to drawingобраба́тывать, напр. самолё́т, су́дно ( перед обратным или повторным рейсом) — turn around, e. g., an airplane, a ship -
77 Herbert, Sir Alfred Edward
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 5 September 1866 Leicester, Englandd. 26 May 1957 Kings Somborne, Hampshire, England[br]English mechanical engineer and machine-tool manufacturer.[br]Alfred Herbert was educated at Stoneygate School, Leicester, and served an apprenticeship with Joseph Jessop \& Sons, also of Leicester, from 1881 to 1886. In 1887 he was engaged as Manager of a small engineering firm in Coventry, and before the end of that year he purchased the business in partnership with William Hubbard. They commenced the manufacture of machine-tools especially for the cycle industry. Hubbard withdrew from the partnership in 1890 and Herbert continued on his own account, the firm being established as a limited liability company, Alfred Herbert Ltd, in 1894. A steady expansion of the business continued, especially after the introduction of their capstan lathe, and by 1914 it was the largest manufacturer of machine-tools in Britain. In addition to making machine-tools of all types for the home and export market, the firm acted as an agent for the import of specialist machine-tools from abroad. During the First World War Alfred Herbert was in 1915 appointed head of machine-tool production at the War Office and when the Ministry of Munitions was set up he was transferred to that Ministry as Controller of Machine Tools. He was President of the Machine Tools Trades Association from 1919 to 1934. He was elected a member of the Institution of Mechanical Engineers in 1892 and in 1921 was a founder member of the Institution of Production Engineers. Almost to the end of his long life he continued to take an active part in the direction of his company. He expressed his views on current events affecting industry in the technical press and in his firm's house journal.[br]Principal Honours and DistinctionsKBE 1917. Officier de la Légion d'honneur 1917. Order of St Stanislas of Russia 1918. Order of Leopold of Belgium 1918. Freeman of the City of Coventry 1933. President, Institution of Production Engineers 1927–9. Honorary Member, Institution of Mechanical Engineers 1941.Bibliography1948, Shots at the Truth, Coventry (a selection of his speeches and writings).Further ReadingD.J.Jeremy (ed.), 1984–6, Dictionary of Business Biography, Vol. 3, London, pp. 174–7 (a useful account).Obituary, 1957, Engineering, 183:680.RTSBiographical history of technology > Herbert, Sir Alfred Edward
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78 Johnson, Thomas
SUBJECT AREA: Textiles[br]fl. 1800s Englandd. after 1846[br]English developer of the sizing and beaming machine, and improver of the hand loom.[br]Thomas Johnson was an assistant to William Radcliffe c.1802 in his developments of the sizing machine and hand looms. Johnson is described by Edward Baines (1835) as "an ingenious but dissipated young man to whom he [Radcliffe] explained what he wanted, and whose fertile invention suggested a great variety of expedients, so that he obtained the name of the “conjuror” among his fellow-workmen". Johnson's genius, and Radcliffe's judgement and perseverance, at length produced the dressing-machine that was soon applied to power looms and made their use economic. Cotton warps had to be dressed with a starch paste to prevent them from fraying as they were being woven. Up to this time, the paste had had to be applied as the warp was unwound from the back of the loom, which meant that only short lengths could be treated and then left to dry, holding up the weaver. Radcliffe carried out the dressing and beaming in a separate machine so that weaving could proceed without interruption. Work on the dressing-machine was carried out in 1802 and patents were taken out in 1803 and 1804. These were made out in Johnson's name because Radcliffe was afraid that if his own name were used other people, particularly foreigners, would discover his secrets. Two more patents were taken out for improvements to hand looms. The first of these was a take-up motion for the woven cloth that automatically wound the cloth onto a roller as the weaver operated the loom. This was later incorporated by H.Horrocks into his own power loom design.Radcliffe and Johnson also developed the "dandy-loom", which was a more compact form of hand loom and later became adapted for weaving by power. Johnson was the inventor of the first circular or revolving temples, which kept the woven cloth at the right width. In the patent specifications there is a patent in 1805 by Thomas Johnson and James Kay for an improved power loom and another in 1807 for a vertical type of power loom. Johnson could have been involved with further patents in the 1830s and 1840s for vertical power looms and dressing-machines, which would put his death after 1846.[br]Bibliography1802, British patent no. 2,684 (dressing-machine).1803, British patent no. 2,771 (dressing-machine).1805, with James Kay, British patent no. 2,876 (power-loom). 1807, British patent no. 6,570 (vertical powerloom).Further ReadingThere is no general account of Johnson's life, but references to his work with Radcliffe may be found in A.Barlow, 1878, The History and Principles of Weaving by Hand and by Power, London; and in E.Baines, 1835, History of the Cotton Manufacture in Great Britain, London.D.J.Jeremy, 1981, Transatlantic Industrial Revolution. The Diffusion of Textile Technologies Between Britain and America, 1790–1830s, Oxford (for the impact of the dressing-machine in America).RLH -
79 Koenig, Friedrich
SUBJECT AREA: Paper and printing[br]b. 17 April 1774 Eisleben, Thuringia, Germanyd. 17 January 1833 Oberzell, near Würzburg, Germany[br]German inventor of the machine printing press.[br]Koenig became a printer and bookseller. Around 1800 he was among those who conceived the idea of mechanizing the hand printing press, which apart from minor details had survived virtually unchanged through the first three and a half centuries of printing. In 1803, in Sühl, Saxony, he designed a press in which the flat forme, carrying the type, was mechanically inked and passed to and from the platen. Whether this ma-chine was ever constructed is not known, but Koenig found little support for his ideas because of lack of technical and financial resources. So, in 1806, he went to England and was introduced to Thomas Bensley, a book printer off Fleet Street in London. Bensley agreed to support Koenig and brought in two other printers to help finance Koenig's experiments. Another German, Andreas Bauer, an engineer, assisted Koenig and became largely responsible for the practical execution of Koenig's plans.In 1810 they patented a press which was steam-driven but still used a platen. It was set to work in Bensley's office the following year but did not prove to be satisfactory. Koenig redesigned it, and in October 1811 he obtained a patent for a steam-driven press on an entirely new principle. In place of the platen, the paper was fixed around a hollow rotating cylinder, which impressed the paper on to the inked forme. In Bensley's office it was used for book printing, but its increased speed over the hand press appealed to newspaper proprietors and John Walter II of The Times asked Koenig to make a double-cylinder machine, so that the return stroke of the forme would be productive. A further patent was taken out in 1813 and the new machine was made ready to print the 29 November 1814 issue—in secrecy, behind closed doors, to forestall opposition from the pressmen working the hand presses. An important feature of the machine was that the inking rollers were not of the traditional leather or skin but a composite material made from glue, molasses and some soda. The inking could not have been achieved satisfactorily with the old materials. The editorial of that historic issue proclaimed, 'Our Journal of this day presents to the public the practical result of the greatest improvement connected with printing, since the discovery of the art itself Koenig's machine press could make 1,200 impressions an hour compared to 200 with the hand press; further improvements raised this figure to 1,500–2,000. Koenig's last English patent was in 1814 for an improved cylinder machine and a perfecting machine, which printed both sides of the paper. The steam-driven perfecting press was printing books in Bensley's office in February 1816. Koenig and Bauer wanted by that time to manufacture machine presses for other customers, but Bensley, now the principal shareholder, insisted that they should make machines for his benefit only. Finding this restriction intolerable, Koenig and Bauer returned to Germany: they became partners in a factory at Oberzell, near Würzburg, in 1817 and the firm of Koenig and Bauer flourishes there to this day.[br]Further ReadingJ.Moran, 1973, Printing Presses, London: Faber \& Faber.T.Goebel, 1956, Friedrich Koenig und die Erfindung der Schnellpresse, Würzburg.LRD -
80 Apparatebau
m; nur Sg. apparatus engineering, design and manufacture of apparatus* * *Ap|pa|ra|te|baum no plinstrument-making, machine-making* * *Ap·pa·ra·te·bau* * *
См. также в других словарях:
Machine (patent) — In United States patent law, a machine is one of the four principal categories of things that may be patented. The other three are a process (also termed a method), an article of manufacture (also termed a manufacture), and a composition of… … Wikipedia
machine tool — machine tooled, adj. a power operated machine, as a lathe, used for general cutting and shaping of metal and other substances. [1860 65] * * * Stationary, power driven machine used to cut, shape, or form materials such as metal and wood. Machine… … Universalium
manufacture — [ manyfaktyr ] n. f. • 1511 « travail manuel »; lat. médiév. manufactura 1 ♦ Vx Fabrication. Mod. École centrale des arts et manufactures. 2 ♦ (1623) Vx ou hist. Grande fabrique, établissement industriel utilisant surtout le travail à la main… … Encyclopédie Universelle
Manufacture d'armes de Saint-Étienne — Type Government owned corporation (Subsidiary of Nexter defense conglomerate) Industry Weapons Fate Annexed Successor Nexter Founded 1764 … Wikipedia
Machine vision — (MV System) is the application of computer vision to industry and manufacturing. Whereas computer vision is mainly focused on machine based image processing, machine vision most often requires also digital input/output devices and computer… … Wikipedia
Machine — Ma*chine (m[.a]*sh[=e]n ), n. [F., fr. L. machina machine, engine, device, trick, Gr. ?, from ? means, expedient. Cf. {Mechanic}.] 1. In general, any combination of bodies so connected that their relative motions are constrained, and by means of… … The Collaborative International Dictionary of English
Machine gun — Machine Ma*chine (m[.a]*sh[=e]n ), n. [F., fr. L. machina machine, engine, device, trick, Gr. ?, from ? means, expedient. Cf. {Mechanic}.] 1. In general, any combination of bodies so connected that their relative motions are constrained, and by… … The Collaborative International Dictionary of English
Machine screw — Machine Ma*chine (m[.a]*sh[=e]n ), n. [F., fr. L. machina machine, engine, device, trick, Gr. ?, from ? means, expedient. Cf. {Mechanic}.] 1. In general, any combination of bodies so connected that their relative motions are constrained, and by… … The Collaborative International Dictionary of English
Machine shop — Machine Ma*chine (m[.a]*sh[=e]n ), n. [F., fr. L. machina machine, engine, device, trick, Gr. ?, from ? means, expedient. Cf. {Mechanic}.] 1. In general, any combination of bodies so connected that their relative motions are constrained, and by… … The Collaborative International Dictionary of English
Machine tool — Machine Ma*chine (m[.a]*sh[=e]n ), n. [F., fr. L. machina machine, engine, device, trick, Gr. ?, from ? means, expedient. Cf. {Mechanic}.] 1. In general, any combination of bodies so connected that their relative motions are constrained, and by… … The Collaborative International Dictionary of English
Machine twist — Machine Ma*chine (m[.a]*sh[=e]n ), n. [F., fr. L. machina machine, engine, device, trick, Gr. ?, from ? means, expedient. Cf. {Mechanic}.] 1. In general, any combination of bodies so connected that their relative motions are constrained, and by… … The Collaborative International Dictionary of English