family-of-parts manufacturing

family-of-parts manufacturing

Автоматика: обработка (технологического) семейства деталей

family-of-parts manufacturing

обработка семейства деталей, обработка технологического семейства деталей

family-of-parts manufacturing cell

Автоматика: ГПМ для обработки (технологических) семейств деталей

family-of-parts manufacturing cell

ГПМ для обработки семейств деталей, ГПМ для обработки технологических семейств деталей

family-of-parts manufacturing cell

ГП-модуль для обработки ( технологических) семейств ( деталей)

manufacturing

1) производство; изготовление || производственный; промышленный; технологический

2) обработка

•

- lights-out manufacturing

- advanced manufacturing
- agile manufacturing
- batch manufacturing
- batch-lot manufacturing
- cell manufacturing
- cellular manufacturing
- computer-aided manufacturing
- computer-assisted manufacturing
- computer-integrated manufacturing
- conventional manufacturing
- data-driven manufacturing
- die-mold manufacturing
- discrete batch manufacturing
- discrete component manufacturing
- discrete parts manufacturing
- engineering manufacturing
- environmentally conscious manufacturing
- extensive manufacturing
- family-of-parts manufacturing
- feature-based manufacturing
- flexible automated manufacturing
- flexible manufacturing
- gear manufacturing
- hands-off manufacturing
- high-mix manufacturing
- high-variety manufacturing
- high-velocity manufacturing
- high-volume manufacturing
- high-volume/low-variety manufacturing
- human integrated manufacturing
- human-centered manufacturing
- infrequent small lot manufacturing
- integrated manufacturing
- just-in-time manufacturing
- large-batch manufacturing
- large-scale manufacturing
- laser-integrated flexible manufacturing
- lean manufacturing
- low-staffed manufacturing
- low-variety manufacturing
- low-volume/high-variety manufacturing
- market integrated manufacturing
- mass manufacturing
- mass-production manufacturing
- medium-batch manufacturing
- medium-run manufacturing
- medium-volume manufacturing
- metal-working manufacturing
- mid-variety manufacturing
- mid-volume/mid-variety manufacturing
- minimally manned manufacturing
- multipart manufacturing
- multiproduct manufacturing
- NC manufacturing
- near-net-shape manufacturing
- physically integrated manufacturing
- process-specialized manufacturing
- quantity manufacturing
- quick-change manufacturing
- random manufacturing
- random order manufacturing
- real-time manufacturing
- sales integrated manufacturing
- series manufacturing
- short-series manufacturing
- six sigma manufacturing
- small-batch manufacturing
- small-lot manufacturing
- small-scale manufacturing
- unmanned manufacturing
- untended manufacturing
- zero defect manufacturing

cell

1) гибкий производственный модуль, ГПМ

2) гибкая производственная ячейка, ГПЯ

3) станочный участок

4) камера; секция; ячейка

5) элемент, гальванический элемент

•

- assembly cell

- automated manufacturing cell
- automated turning cell
- automated work cell
- circular sawing cell
- CNC machining center cell
- combined cell
- complex part cell
- component cells
- computer-controlled cell
- computer-driven cell
- counter cell
- crankshaft cell
- creep feed cell
- damped cell
- design-to-manufacturing cell
- desired-value cell
- dew cell
- discrete cell
- DNC flexible machining cell
- drilling cell
- dry cell
- dual-robot cell
- duplex machining cell
- EDM FMS cell
- electrical discharge machining cell
- electrochemical cell
- electrochemical machining cell
- emission cell
- extrusion trim cell
- family-of-parts manufacturing cell
- FFS cell
- final machining cell
- fir-tree grinding cell
- fir-tree milling cell
- flexible assembly cell
- flexible bending cell
- flexible drilling-and-milling manufacturing cell
- flexible fabricating cell
- flexible machining cell
- flexible manufacturing cell
- flexible production cell
- flexible turning cell
- FMS sheet metal cell
- FMT cell
- focused-layout cell
- force load cell
- forming cell
- gear hobbing cell
- gear manufacturing cell
- gear shaping cell
- grinding cell
- group technology cell
- group technology-based cell
- GT cell
- heat-treatment cell
- HMC cell
- honing cell
- horizontal machining cell
- inspection cell
- integrated cell
- integrated turning cells
- lathe cell
- lathe machining cell
- light-sensitive cell
- limited-manned cell
- load cell
- machine tool cell
- machining cell
- machining-center cell
- magnetic cell
- manned cell
- manufacturing cell
- measuring cell
- memory cell
- metalforming production cell
- milling and boring cell
- milling cell
- minimum manned cell
- mixed GT cell
- modular FMS cell
- multiaxis cell
- multirobot cell
- NC cell
- NC machine tool cell
- near-term cell
- noise testing cell
- one-machine cell
- on-line inspection cell
- operating cell
- opposed-spindle turning cell
- optimum work cell
- palletizing cell
- partially-manned flexible machining cell
- part-processing cell
- part-washing cell
- photoconductive cell
- photovoltaic cell
- piezoelectric crystal-type load cell
- pilot cell
- pneumatic cell
- position-sensitive photoelectric cell
- pressure cell
- processing cell
- production cell
- rechargeable cell
- reverse-engineering cell
- RGV-served cell
- robot-controlled machining cell
- robotic assembly cell
- robotic cell
- robotic machining cell
- robotic work cell
- robot-integrated cell
- robotized measuring cell
- robot-loaded cell
- robot-welding cell
- sandwiched liquid crystal cell
- sawing cell
- sealant cell
- secondary cell
- self-contained machining cell
- self-sufficient cell
- semimanned cell
- shallow-junction solar cells
- sheet-metal cell
- single-machine cell
- single-manufacturing cell
- spur helical bevel gear cell
- stand-alone cell
- standard cell
- storage cell
- store cell
- strain-gage load cell
- superconductor memory cell
- target cell
- test cell
- testing cell
- thermoelectric cell
- three-core cell
- three-unit flexible manufacturing cell
- time cell
- total parts-processing cell
- turned parts cell
- turning cell
- turning/milling cell
- two-machining-center cell
- two-unit flexible manufacturing cell
- unattended machining cell
- unattended production cell
- unmanned machining cell
- unmanned production cell
- versatile machining cell
- versatile manufacturing cell
- vertical internal milling machine cell
- VMC cell
- work cell

ГПМ для обработки (технологических) семейств деталей

Automation: family-of-parts manufacturing cell

обработка (технологического) семейства деталей

Automation: family-of-parts manufacturing

ГПМ для обработки семейств деталей

Automation: (технологических) family-of-parts manufacturing cell

обработка семейства деталей

Automation: (технологического) family-of-parts manufacturing

Clark, Edward

SUBJECT AREA: Domestic appliances and interiors

[br]

fl. 1850s New York State, USA

[br]

American co-developer of mass-production techniques at the Singer sewing machine factory.

[br]

Born in upstate New York, where his father was a small manufacturer, Edward Clark attended college at Williams and graduated in 1831. He became a lawyer in New York City and from then on lived either in the city or on his rural estate near Cooperstown in upstate New York. After a series of share manipulations, Clark acquired a one-third interest in Isaac M. Singer's company. They soon bought out one of Singer's earlier partners, G.B.Zeiber, and in 1851, under the name of I.M.Singer \& Co., they set up a permanent sewing machine business with headquarters in New York.

The success of their firm initially rested on marketing. Clark introduced door-to-door sales-people and hire-purchase for their sewing machines in 1856 ($50 cash down, or $100 with a cash payment of $5 and $3 a month thereafter). He also trained women to demonstrate to potential customers the capabilities of the Singer sewing machine. At first their sewing machines continued to be made in the traditional way, with the parts fitted together by skilled workers through hand filing and shaping so that the parts would fit only onto one machine. This resembled European practice rather than the American system of manufacture that had been pioneered in the armouries in that country. In 1856 Singer brought out their first machine intended exclusively for home use, and at the same time manufacturing capacity was improved. Through increased sales, a new factory was built in 1858–9 on Mott Street, New York, but it soon became inadequate to meet demand.

In 1863 the Singer company was incorporated as the Singer Manufacturing Co. and began to modernize its production methods with special jigs and fixtures to help ensure uniformity. More and more specialized machinery was built for making the parts. By 1880 the factory, then at Elizabethport, New Jersey, was jammed with automatic and semi-automatic machine tools. In 1882 the factory was producing sewing machines with fully interchangeable parts that did not require hand fitting in assembly. Production rose from 810 machines in 1853 to half a million in 1880. A new family model was introduced in 1881. Clark had succeeded Singer, who died in 1875, as President of the company, but he retired in 1882 after he had seen through the change to mass production.

[br]

Further Reading

National Cyclopaedia of American Biography.

D.A.Hounshell, 1984, From the American System to Mass Production, 1800–1932. The Development of Manufacturing Technology in the United States, Baltimore (a thorough account of Clark's role in the development of Singer's factories).

F.B.Jewell, 1975, Veteran Sewing Machines. A Collector's Guide, Newton Abbot.

RLH

Gillette, King Camp

SUBJECT AREA: Domestic appliances and interiors, Metallurgy

[br]

b. 5 January 1855 Fond du Lac, Wisconsin, USA

d. 9 July 1932 Los Angeles, California, USA

[br]

American inventor and manufacturer, inventor of the safety razor.

[br]

Gillette's formal education in Chicago was brought to an end when a disastrous fire destroyed all his father's possessions. Forced to fend for himself, he worked first in the hardware trade in Chicago and New York, then as a travelling salesman. Gillette inherited the family talent for invention, but found that his successful inventions barely paid for those that failed. He was advised by a previous employer, William Painter (inventor of the Crown Cork), to look around for something that could be used widely and then thrown away. In 1895 he succeeded in following that advice of inventing something which people could use and then throw away, so that they would keep coming back for more. An idea came to him while he was honing an old-fashioned razor one morning; he was struck by the fact that only a short piece of the whole length of a cutthroat razor is actually used for shaving, as well as by the potentially dangerous nature of the implement. He "rushed out to purchase some pieces of brass, some steel ribbon used for clock springs, a small hand vise and some files". He thought of using a thin steel blade sharpened on each side, placed between two plates and held firmly together by a handle. Though coming from a family of inventors, Gillette had no formal technical education and was entirely ignorant of metallurgy. For six years he sought a way of making a cheap blade from sheet steel that could be hardened, tempered and sharpened to a keen edge.

Gillette eventually found financial supporters: Henry Sachs, a Boston lamp manufacturer; his brother-in-law Jacob Heilbron; and William Nickerson, who had a considerable talent for invention. By skilled trial and error rather than expert metallurgical knowledge, Nickerson devised ways of forming and sharpening the blades, and it was these that brought commercial success. In 1901, the American Safety Razor Company, later to be renamed the Gillette Safety Razor Company, was set up. When it started production in 1903 the company was badly in debt, and managed to sell only fifty-one razors and 168 blades; but by the end of the following year, 90,000 razors and 12.4 million blades had been sold. A sound invention coupled with shrewd promotion ensured further success, and eight plants manufacturing safety razors were established in various parts of the world. Gillette's business experiences led him into the realms of social theory about the way society should be organized. He formulated his views in a series of books published over the years 1894 to 1910. He believed that competition led to a waste of up to 90 per cent of human effort and that want and crime would be eliminated by substituting a giant trust to plan production centrally. Unfortunately, the public in America, or anywhere else for that matter, were not ready for this form of Utopia; no omniscient planners were available, and human wants and needs were too various to be supplied by a single agency. Even so, some of his ideas have found favour: air conditioning and government provision of work for the unemployed. Gillette made a fortune from his invention and retired from active participation in the business in 1913, although he remained President until 1931 and Director until his death.

[br]

Bibliography

"Origin of the Gillette razor", Gillette Blade (February/March).

Further Reading

Obituary, 1932, New York Times (11 July).

J.Jewkes, D.Sawers and R.Stillerman, 1958, The Sources of Invention, London: Macmillan.

LRD / IMcN

Brennan, Louis

SUBJECT AREA: Land transport, Railways and locomotives, Weapons and armour

[br]

b. 28 January 1852 Castlebar, Ireland

d. 17 January 1932 Montreux, Switzerland

[br]

Irish inventor of the Brennan dirigible torpedo, and of a gyroscopically balanced monorail system.

[br]

The Brennan family, including Louis, emigrated to Australia in 1861. He was an inventive genius from childhood, and while at Melbourne invented his torpedo. Within it were two drums, each with several miles of steel wire coiled upon it and mounted on one of two concentric propeller shafts. The propellers revolved in opposite directions. Wires were led out of the torpedo to winding drums on land, driven by high-speed steam engines: the faster the drums on shore were driven, the quicker the wires were withdrawn from the drums within the torpedo and the quicker the propellers turned. A steering device was operated by altering the speeds of the wires relative to one another. As finally developed, Brennan torpedoes were accurate over a range of 1 1/2 miles (2.4 km), in contrast to contemporary self-propelled torpedoes, which were unreliable at ranges over 400 yards (366 in).

Brennan moved to England in 1880 and sold the rights to his torpedo to the British Government for a total of £110,000, probably the highest payment ever made by it to an individual inventor. Brennan torpedoes became part of the defences of many vital naval ports, but never saw active service: improvement of other means of defence meant they were withdrawn in 1906. By then Brennan was deeply involved in the development of his monorail. The need for a simple and cheap form of railway had been apparent to him when in Australia and he considered it could be met by a ground-level monorail upon which vehicles would be balanced by gyroscopes. After overcoming many manufacturing difficulties, he demonstrated first a one-eighth scale version and then a full-size, electrically driven vehicle, which ran on its single rail throughout the summer of 1910 in London, carrying up to fifty passengers at a time. Development had been supported financially by, successively, the War Office, the India Office and the Government of the Indian state of Jammu and Kashmir, which had no rail access; despite all this, however, no further financial support, government or commercial, was forthcoming.

Brennan made many other inventions, worked on the early development of helicopters and in 1929 built a gyroscopically balanced, two-wheeled motor car which, however, never went into production.

[br]

Principal Honours and Distinctions

Companion of the Bath 1892.

Bibliography

1878, British patent no. 3359 (torpedo) 1903, British patent no. 27212 (stability mechanisms).

Further Reading

R.E.Wilkes, 1973, Louis Brennan CB, 2 parts, Gillingham (Kent) Public Library. J.R.Day and B.C.Wilson, 1957, Unusual Railways, London: F.Muller.

See also: Behr, Fritz Bernhard; Lartigue, Charles François Marie-Thérèse; Palmer, Henry Robinson( monorails); Whitehead, Robert( torpedoes).

PJGR

Wheatstone, Sir Charles

SUBJECT AREA: Telecommunications

[br]

b. 1802 near Gloucester, England

d. 19 October 1875 Paris, France

[br]

English physicist, pioneer of electric telegraphy.

[br]

Wheatstone's family moved to London when he was 4 years old. He was educated at various schools in London and excelled in physics and mathematics. He qualified for a French prize but forfeited it because he was too shy to recite a speech in French at the prize-giving.

An uncle, also called Charles Wheatstone, has a musical instrument manufacturing business where young Charles went to work. He was fascinated by the science of music, but did not enjoy business life. After the uncle's death, Charles and his brother William took over the business. Charles developed and patented the concertina, which the firm assembled from parts made by "outworkers". He devoted much of his time to studying the physics of sound and mechanism of sound transmission through solids. He sent speech and music over considerable distances through solid rods and stretched wires, and envisaged communication at a distance. He concluded, however, that electrical methods were more promising.

In 1834 Wheatstone was appointed Professor of Experimental Philosophy—a part-time posi-tion—in the new King's College, London, which gave him some research facilities. He conducted experiments with a telegraph system using several miles of wire in the college corridors. Jointly with William Fothergill Cooke, in 1837 he obtained the first patent for a practical electric telegraph, and much of the remainder of his life was devoted to its improvement. In 1843 he gave a paper to the Royal Society surveying the state of electrical measurements and drew attention to a bridge circuit known ever since as the "Wheatstone bridge", although he clearly attributed it to S.H.Christie. Wheatstone devised the "ABC" telegraph, for use on private lines by anyone who could read, and a high-speed automatic telegraph which was adopted by the Post Office and used for many years. He also worked on the French and Belgian telegraph systems; he died when taken ill on a business visit to Paris.

[br]

Further Reading

B.Bowers, 1975, Sir Charles Wheatstone FRS, London: HMSO.

BB