processing number

Flax Scutching

FLAX SCUTCHING

Bale

Two cwt. of scutched flax enclosed in a bessian bag. The unit of flax for despatch to the spinner.

Blades, Tapered - A turbine scutching machine in which the scutching blades are tapered in width in the first third of each compartment in contradistinction to the usual parallel sided blades. Blades, Tapered and Coned - A turbine scutching machine in which the blades are tapered and at the same time the first third of each scutching rotor is coned. Bunch - The aggregate of pieces which is tied up with two or more ties preparatory to baling. Conditioning - The operation of adding moisture to or abstracting moisture from straw to put it in the optimum condition for scutching. Decortication - The term sometimes applied to the scutching of unretted straw in contradistinction to retted straw. Handles - See Scutching Wheel or Handles. Piece - The small handful which is the unit of scutched flax. Scutching - The mechanical operation of separating the fibre from the woody part of the de-seeded or retted flax straw. Scutching, Automatic - See Scutching, machine or turbine or automatic. Scutching, Hand - The operation of scutching as carried out on a Belgian or Irish scutching wheel. Scutching, Machine, or Turbine, or Automatic - The operation of scutching flax entirely mechanically. Scutching Machine, Monoblade - Similar in principle to a turbine machine, but each compartment has a single steel blade on one shaft in place of multiple blades on two shafts. Scutching Machine, Turbine - A scutching outfit consisting generally of (a) prebreaking rollers to crimp the centre of the straw (b) a set of fluted breaking rollers to crimp the ends of the straw (c) a conveyor to hold the straw during processing; (d) a root end compartment where intersecting steel blades scutch the root end and middle of the flax; (e) a top end compartment where similar blades scutch the middle and top end of the flax; (f) a delivery bar where the scutched flax is piled up for removal. Scutching Wheel, or Handles - The machine on which hand scutching is done. It consists of an upright wooden or metal stock in a notch of which the broken flax straw is held and is there operated on by a number of wooden blades mounted equidistantly on a central shaft. Scutching Wheel, Belgian - A scutch wheel which usually has 12 light blades of walnut. Scutching Wheel Irish - A scutch wheel which usually has 6 blades, much heavier than those in the Belgian wheel. Strick (v.) - To divide straw from the breakers into suitable pieces and to level the ends before hand scutching.

Toyota production system

Ops

a manufacturing system, developed by Toyota in Japan after World War II, which aims to increase production efficiency by the elimination of waste in all its forms. The Toyota production system was invented, and made to work, by Taiichi Ohno. Japan’s fledgling car-making industry was suffering from poor productivity, and Ohno was brought into Toyota with an initial assignment of catching up with the productivity levels of Ford’s car plants. In analyzing the problem, he decided that although Japanese workers must be working at the same rate as their American counterparts, waste and inefficiency were the main causes of their different productivity levels. Ohno identified waste in a number of forms, including overproduction, waiting time, transportation problems, inefficient processing, inventory, and defective products. The philosophy of TPS is to remove or minimize the influence of all these elements. In order to achieve this, TPS evolved to operate under lean production conditions. It is made up of soft, or cultural aspects, such as automation with the human touch— autonomation—and hard, or technical, aspects, which include just-in-time, kanban, and production smoothing. Each aspect is equally important and complementary. TPS has proven itself to be one of the most efficient manufacturing systems in the world but although leading companies have adopted it in one form or another, few have been able to replicate the success of Toyota.

Abbr. TPS

Kilby, Jack St Clair

SUBJECT AREA: Electronics and information technology

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b. 8 November 1923 Jefferson City, Missouri, USA

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American engineer who filed the first patents for micro-electronic (integrated) circuits.

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Kilby spent most of his childhood in Great Bend, Kansas, where he often accompanied his father, an electrical power engineer, on his maintenance rounds. Working in the blizzard of 1937, his father borrowed a "ham" radio, and this fired Jack to study for his amateur licence (W9GTY) and to construct his own equipment while still a student at Great Bend High School. In 1941 he entered the University of Illinois, but four months later, after the attack on Pearl Harbor, he was enlisted in the US Army and found himself working in a radio repair workshop in India. When the war ended he returned to his studies, obtaining his BSEE from Illinois in 1947 and his MSEE from the University of Wisconsin. He then joined Centralab, a small electronics firm in Milwaukee owned by Globe-Union. There he filed twelve patents, including some for reduced titanate capacitors and for Steatite-packing of transistors, and developed a transistorized hearing-aid. During this period he also attended a course on transistors at Bell Laboratories. In May 1958, concerned to gain experience in the field of number processing, he joined Texas Instruments in Dallas. Shortly afterwards, while working alone during the factory vacation, he conceived the idea of making monolithic, or integrated, circuits by diffusing impurities into a silicon substrate to create P-N junctions. Within less than a month he had produced a complete oscillator on a chip to prove that the technology was feasible, and the following year at the 1ERE Show he demonstrated a germanium integrated-circuit flip-flop. Initially he was granted a patent for the idea, but eventually, after protracted litigation, priority was awarded to Robert Noyce of Fairchild. In 1965 he was commissioned by Patrick Haggerty, the Chief Executive of Texas Instruments, to make a pocket calculator based on integrated circuits, and on 14 April 1971 the world's first such device, the Pocketronic, was launched onto the market. Costing $150 (and weighing some 2½ lb or 1.1 kg), it was an instant success and in 1972 some 5 million calculators were sold worldwide. He left Texas Instruments in November 1970 to become an independent consultant and inventor, working on, amongst other things, methods of deriving electricity from sunlight.

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Principal Honours and Distinctions

Franklin Institute Stuart Ballantine Medal 1966. Institute of Electrical and Electronics Engineers David Sarnoff Award 1966; Cledo Brunetti Award (jointly with Noyce) 1978; Medal of Honour 1986. National Academy of Engineering 1967. National Science Medal 1969. National Inventors Hall of Fame 1982. Honorary DEng Miami 1982, Rochester 1986. Honorary DSc Wisconsin 1988. Distinguished Professor, Texas A \& M University.

Bibliography

6 February 1959, US patent no. 3,138,743 (the first integrated circuit (IC); initially granted June 1964).

US patent no. 3,819,921 (the Pocketronic calculator).

Further Reading

T.R.Reid, 1984, Microchip. The Story of a Revolution and the Men Who Made It, London: Pan Books (for the background to the development of the integrated circuit). H.Queisser, 1988, Conquest of the Microchip, Cambridge, Mass.: Harvard University Press.

KF

Noyce, Robert

SUBJECT AREA: Electronics and information technology

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b. 12 December 1927 Burlington, Iowa, USA

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American engineer responsible for the development of integrated circuits and the microprocessor chip.

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Noyce was the son of a Congregational minister whose family, after a number of moves, finally settled in Grinnell, some 50 miles (80 km) east of Des Moines, Iowa. Encouraged to follow his interest in science, in his teens he worked as a baby-sitter and mower of lawns to earn money for his hobby. One of his clients was Professor of Physics at Grinnell College, where Noyce enrolled to study mathematics and physics and eventually gained a top-grade BA. It was while there that he learned of the invention of the transistor by the team at Bell Laboratories, which included John Bardeen, a former fellow student of his professor. After taking a PhD in physical electronics at the Massachusetts Institute of Technology in 1953, he joined the Philco Corporation in Philadelphia to work on the development of transistors. Then in January 1956 he accepted an invitation from William Shockley, another of the Bell transistor team, to join the newly formed Shockley Transistor Company, the first electronic firm to set up shop in Palo Alto, California, in what later became known as "Silicon Valley".

From the start things at the company did not go well and eventually Noyce and Gordon Moore and six colleagues decided to offer themselves as a complete development team; with the aid of the Fairchild Camera and Instrument Company, the Fairchild Semiconductor Corporation was born. It was there that in 1958, contemporaneously with Jack K. Wilby at Texas Instruments, Noyce had the idea for monolithic integration of transistor circuits. Eventually, after extended patent litigation involving study of laboratory notebooks and careful examination of the original claims, priority was assigned to Noyce. The invention was most timely. The Apollo Moon-landing programme announced by President Kennedy in May 1961 called for lightweight sophisticated navigation and control computer systems, which could only be met by the rapid development of the new technology, and Fairchild was well placed to deliver the micrologic chips required by NASA.

In 1968 the founders sold Fairchild Semicon-ductors to the parent company. Noyce and Moore promptly found new backers and set up the Intel Corporation, primarily to make high-density memory chips. The first product was a 1,024-bit random access memory (1 K RAM) and by 1973 sales had reached $60 million. However, Noyce and Moore had already realized that it was possible to make a complete microcomputer by putting all the logic needed to go with the memory chip(s) on a single integrated circuit (1C) chip in the form of a general purpose central processing unit (CPU). By 1971 they had produced the Intel 4004 microprocessor, which sold for US$200, and within a year the 8008 followed. The personal computer (PC) revolution had begun! Noyce eventually left Intel, but he remained active in microchip technology and subsequently founded Sematech Inc.

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Principal Honours and Distinctions

Franklin Institute Stuart Ballantine Medal 1966. National Academy of Engineering 1969. National Academy of Science. Institute of Electrical and Electronics Engineers Medal of Honour 1978; Cledo Brunetti Award (jointly with Kilby) 1978. Institution of Electrical Engineers Faraday Medal 1979. National Medal of Science 1979. National Medal of Engineering 1987.

Bibliography

1955, "Base-widening punch-through", Proceedings of the American Physical Society.

30 July 1959, US patent no. 2,981,877.

Further Reading

T.R.Reid, 1985, Microchip: The Story of a Revolution and the Men Who Made It, London: Pan Books.

KF

Osborne, Adam

SUBJECT AREA: Electronics and information technology

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b. 6 February 1939 Bangkok, Thailand

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British computer pioneer, producer of the first practical portable microcomputer.

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Born of British parents, Osborne spent some time in India before moving to the UK. He obtained a BSc in chemical engineering at Birmingham University in 1961, then worked for a number of companies in the USA before obtaining a PhD at the University of Delaware. He was then employed by the Shell Oil Company, near San Francisco, California, but he resigned in 1971 to write and to study computing. In 1975 he published a book on microcomputers that sold 20,000 copies in less than a year. He then set up a publishing firm, Osborne and Associates, which he sold to McGraw-Hill in 1979. Subsequently, he formed the Osborne Computer Company and in March 1981 he introduced the Osborne I, the first portable microcomputer. Features of this innovative machine, which sold for under US$2,000, were a full-size keyboard, a CRT (cathode ray tube) display, dual floppy-disk drives, a CP/M operating system, Wordstar word-processing, SuperCalc (a financial-analysis package) and interpretive and compiled BASIC. By late 1982 the company had over 1,000 employees and sales had reached US$70 million, but within a year the company was bankrupt, a débâcle that Osborne later described in a book. Following this he returned to publishing with the formation of Paperback Software International.

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Bibliography

1975, An Introduction to Microcomputers: Adam Osborne \& Associates. 1984, Hypergrowth: The Rise and Fall of the Osborne Computer Co.

KF

сообщение с высоким приоритетом

high priority message

преимущественное право, право приоритета — right of priority

оперативное управление по приоритетам — priority scheduling

приоритетный номер; указатель приоритета — priority number

приоритет обработки кассеты — priority cassette processing

таблица приоритетов прерываний — priority interrupt table

система с приоритетом

priority system

преимущественное право, право приоритета — right of priority

оперативное управление по приоритетам — priority scheduling

приоритетный номер; указатель приоритета — priority number

приоритет обработки кассеты — priority cassette processing

таблица приоритетов прерываний — priority interrupt table

тип приоритета

priority class

преимущественное право, право приоритета — right of priority

оперативное управление по приоритетам — priority scheduling

приоритетный номер; указатель приоритета — priority number

приоритет обработки кассеты — priority cassette processing

таблица приоритетов прерываний — priority interrupt table