weighed design

weighed design

мат. взвешенный план

weighed design

Математика: взвешенный план

weighed design

эксп.

взвешенный план

design

1) дизайн; конструкция

2) замысел, план; проект, проектное решение

3) конструирование; проектирование || конструировать; проектировать

4) конструкция

5) рисунок, эскиз, набросок || делать рисунок, эскиз, набросок

6) составлять план

7) чертёж

8) расчёт || рассчитывать

•

design with confounding — план со смешиванием эффектов

design with eight points — план с восемью точками

design with replications — план с репликами

design without confounding — план без смешивания эффектов

design without replications — план без реплик

for reasons of design — из конструктивных соображений

- absolutely minimal design

- accurate design

- admissible design

- affine design

- affine resovable design

- alternate design

- asymmetric design

- asymptotic sequential design

- asymptotically locally optimal design

- balanced incomplete block design

- balanced orthogonal design

- biased design

- binary design

- breadboard design

- central composite design

- changeover design

- civil-engineering design

- combinatorial design

- complementary design

- complete design

- complete factorial design

- completely confounded design

- completely crossed design

- completely hierarchical design

- completely randomized design

- confounded design

- connected designs

- crossed design

- cube-plus-octahedron rotatable design

- cubic lattice design

- cuboidal design

- cut-and-try design

- cyclic design

- cylindrically rotatable design

- design of statistical inquiry

- design of type face

- disconnected design

- discriminating design

- double-buttion design

- doubly balanced design

- doubly overlap design

- elementary design

- equilateral triangle design

- equireplicated designs

- first-order design

- fractional factorial design

- fractional nested design

- fractional weighing design

- fractionally replicated design

- generalized chain block design

- generally balanced design

- geometrical design

- group divisible design

- half-factorial design

- half-replicated design

- hexagonal design

- hierarchical design

- hypercubic design

- ice-gouging design

- icosahedral design

- incomplete split plot design

- intragroup balanced design

- isomorphic block designs

- landscape design

- lattice design

- linked-block design

- magic design

- minimal design

- minimax design

- mixed design

- multiply balanced design

- multiresponse design

- multivariate design

- noncentral composite design

- nonfactorial design

- nonorthogonal design

- nonrotatable design

- nonsaturated design

- nonsymmetrical design

- one-factor-at-a-time design

- one-stage design

- orthogonal composite design

- paired-comparison design

- pairwise-balanced designs

- partially balanced design

- partially confounded design

- partially duplicated design

- pentagonal design

- permutable design

- pseudotriangular design

- purely hierarchical design

- quasifactorial design

- quasioptimal design

- quasiorthogonal designs

- quasiresidual design

- quasisymmetrical design

- radial centroid design

- radial lattice design

- randomized design

- regular design

- replicated nested design

- response surface design

- right-angular design

- roll pass design

- row-and-column design

- screening design

- second-order design

- self-corrective design

- semibalanced design

- semiregular design

- sequential design

- simplex design

- simplex-centroid design

- simplex-lattice design

- simplex-symmetric design

- simplified design

- singly-linked block design

- singular design

- six-point design

- smooth design

- spherical design

- split-plot design

- split-split-plot design

- square design

- staircase design

- standard design

- steepest ascent design

- strongly regular incomplete multiresponse design

- supersaturated design

- survey design

- switch-back design

- system design

- tetrahedral design

- three-factor design

- totally confounded design

- tournamental design

- transversal design

- tri-factorial design

- truncated design

- two-associate design

- two-stage design

- typographic design

- ultimate load design

- unbalanced design

- unbiased design

- unconventional design

- unit-type design

- unreduced design

- unsymmetrical design

- variance-balanced design

- wallpaper design

- weighed design

- weighing design

weighed

взвешенный - weighed design Взвешенный

взвешенный план

мат. weighed design

Armstrong, Sir William George, Baron Armstrong of Cragside

SUBJECT AREA: Ports and shipping, Public utilities, Weapons and armour

[br]

b. 26 November 1810 Shieldfield, Newcastle upon Tyne, England

d. 27 December 1900 Cragside, Northumbria, England

[br]

English inventor, engineer and entrepreneur in hydraulic engineering, shipbuilding and the production of artillery.

[br]

The only son of a corn merchant, Alderman William Armstrong, he was educated at private schools in Newcastle and at Bishop Auckland Grammar School. He then became an articled clerk in the office of Armorer Donkin, a solicitor and a friend of his father. During a fishing trip he saw a water-wheel driven by an open stream to work a marble-cutting machine. He felt that its efficiency would be improved by introducing the water to the wheel in a pipe. He developed an interest in hydraulics and in electricity, and became a popular lecturer on these subjects. From 1838 he became friendly with Henry Watson of the High Bridge Works, Newcastle, and for six years he visited the Works almost daily, studying turret clocks, telescopes, papermaking machinery, surveying instruments and other equipment being produced. There he had built his first hydraulic machine, which generated 5 hp when run off the Newcastle town water-mains. He then designed and made a working model of a hydraulic crane, but it created little interest. In 1845, after he had served this rather unconventional apprenticeship at High Bridge Works, he was appointed Secretary of the newly formed Whittle Dene Water Company. The same year he proposed to the town council of Newcastle the conversion of one of the quayside cranes to his hydraulic operation which, if successful, should also be applied to a further four cranes. This was done by the Newcastle Cranage Company at High Bridge Works. In 1847 he gave up law and formed W.G.Armstrong \& Co. to manufacture hydraulic machinery in a works at Elswick. Orders for cranes, hoists, dock gates and bridges were obtained from mines; docks and railways.

Early in the Crimean War, the War Office asked him to design and make submarine mines to blow up ships that were sunk by the Russians to block the entrance to Sevastopol harbour. The mines were never used, but this set him thinking about military affairs and brought him many useful contacts at the War Office. Learning that two eighteen-pounder British guns had silenced a whole Russian battery but were too heavy to move over rough ground, he carried out a thorough investigation and proposed light field guns with rifled barrels to fire elongated lead projectiles rather than cast-iron balls. He delivered his first gun in 1855; it was built of a steel core and wound-iron wire jacket. The barrel was multi-grooved and the gun weighed a quarter of a ton and could fire a 3 lb (1.4 kg) projectile. This was considered too light and was sent back to the factory to be rebored to take a 5 lb (2.3 kg) shot. The gun was a complete success and Armstrong was then asked to design and produce an equally successful eighteen-pounder. In 1859 he was appointed Engineer of Rifled Ordnance and was knighted. However, there was considerable opposition from the notably conservative officers of the Army who resented the intrusion of this civilian engineer in their affairs. In 1862, contracts with the Elswick Ordnance Company were terminated, and the Government rejected breech-loading and went back to muzzle-loading. Armstrong resigned and concentrated on foreign sales, which were successful worldwide.

The search for a suitable proving ground for a 12-ton gun led to an interest in shipbuilding at Elswick from 1868. This necessitated the replacement of an earlier stone bridge with the hydraulically operated Tyne Swing Bridge, which weighed some 1450 tons and allowed a clear passage for shipping. Hydraulic equipment on warships became more complex and increasing quantities of it were made at the Elswick works, which also flourished with the reintroduction of the breech-loader in 1878. In 1884 an open-hearth acid steelworks was added to the Elswick facilities. In 1897 the firm merged with Sir Joseph Whitworth \& Co. to become Sir W.G.Armstrong Whitworth \& Co. After Armstrong's death a further merger with Vickers Ltd formed Vickers Armstrong Ltd.

In 1879 Armstrong took a great interest in Joseph Swan's invention of the incandescent electric light-bulb. He was one of those who formed the Swan Electric Light Company, opening a factory at South Benwell to make the bulbs. At Cragside, his mansion at Roth bury, he installed a water turbine and generator, making it one of the first houses in England to be lit by electricity.

Armstrong was a noted philanthropist, building houses for his workforce, and endowing schools, hospitals and parks. His last act of charity was to purchase Bamburgh Castle, Northumbria, in 1894, intending to turn it into a hospital or a convalescent home, but he did not live long enough to complete the work.

[br]

Principal Honours and Distinctions

Knighted 1859. FRS 1846. President, Institution of Mechanical Engineers; Institution of Civil Engineers; British Association for the Advancement of Science 1863. Baron Armstrong of Cragside 1887.

Further Reading

E.R.Jones, 1886, Heroes of Industry', London: Low.

D.J.Scott, 1962, A History of Vickers, London: Weidenfeld \& Nicolson.

IMcN

Ferguson, Harry

SUBJECT AREA: Agricultural and food technology

[br]

b. 4 November 1884 County Down, Ireland

d. 25 October 1960 England

[br]

Irish engineer who developed a tractor hydraulic system for cultivation equipment, and thereby revolutionized tractor design.

[br]

Ferguson's father was a small farmer who expected his son to help on the farm from an early age. As a result he received little formal education, and on leaving school joined his brother in a backstreet workshop in Belfast repairing motor bikes. By the age of 19 he had built his own bike and began hill-climbing competitions and racing. His successes in these ventures gained useful publicity for the workshop. In 1907 he built his own car and entered it into competitions, and in 1909 became the first person in Britain to build and fly a machine that was heavier than air.

On the outbreak of the First World War he was appointed by the Irish Department of Agriculture to supervise the operation and maintenance of all farm tractors. His experiences convinced him that even the Ford tractor and the implements available for it were inadequate for the task, and he began to experiment with his own plough designs. The formation of the Ferguson-Sherman Corporation resulted in the production of thousands of the ploughs he had designed for the Ford tractor, but in 1928 Ford discontinued production of tractors, and Ferguson returned to Ireland. He immediately began to design his own tractor. Six years of development led to the building of a prototype that weighed only 16 cwt (813kg). In 1936 David Brown of Huddersfield, Yorkshire, began production of these tractors for Ferguson, but the partnership was not wholly successful and was dissolved after three years. In 1939 Ferguson and Ford reached their famous "Handshake agreement", in which no formal contract was signed, and the mass production of the Ford Ferguson system tractors began that year. During the next nine years 300,000 tractors and a million implements were produced under this agreement. However, on the death of Henry Ford the company began production, under his son, of their own tractor. Ferguson returned to the UK and negotiated a deal with the Standard Motor Company of Coventry for the production of his tractor. At the same time he took legal action against Ford, which resulted in that company being forced to stop production and to pay damages amounting to US$9.5 million.

Aware that his equipment would only operate when set up properly, Ferguson established a training school at Stoneleigh in Warwickshire which was to be a model for other manufacturers. In 1953, by amicable agreement, Ferguson amalgamated with the Massey Harris Company to form Massey Ferguson, and in so doing added harvesting machinery to the range of equipment produced. A year later he disposed of his shares in the new company and turned his attention again to the motor car. Although a number of experimental cars were produced, there were no long-lasting developments from this venture other than a four-wheel-drive system based on hydraulics; this was used by a number of manufacturers on occasional models. Ferguson's death heralded the end of these developments.

[br]

Principal Honours and Distinctions

Honorary DSc Queen's University, Belfast, 1948.

Further Reading

C.Murray, 1972, Harry Ferguson, Inventor and Pioneer. John Murray.

AP

MacCready, Paul

SUBJECT AREA: Aerospace

[br]

b. 29 September 1925 New Haven, Connecticut, USA

[br]

American designer of man-powered aeroplanes, one of which flew across the English Channel in 1979.

[br]

As a boy, Paul MacCready was an enthusiastic builder of flying model aeroplanes; he became US National Junior Champion in 1941. He learned to fly and became a pilot with the US Navy in 1943. he developed an interest in gliding in 1945 and became National Soaring Champion in 1948 and 1949. After graduating from the California Institute of Technology (Cal Tech) as a meteorologist, he set up Meteorological Research Inc. In 1953 MacCready became the first American to win the World Gliding Championship. When hang-gliders became popular in the early 1970s MacCready studied their performance and compared them with soaring birds: he came to the conclusion that man-powered flight was a possibility. In an effort to generate an interest in man-powered flight, a cash prize had been offered in Britain by Henry Kremer, a wealthy industrialist and fitness enthusiast. A man-powered aircraft had to complete a one-mile (1.6km) figure-of-eight course in order to win. However, the figure-of-eight proved to be a major obstacle and the prize money was increased over the years to £50,000. In 1976 MacCready and his friend Dr Peter Lissaman set to work on their computer and came up with their optimum design for a man-powered aircraft. The Gossamer Condor had a wing span of 96 ft (27.4 m), about the same as a Douglas DC-9 airliner, yet it weighed just 70 lb (32 kg). It was a tail-first design with a pedaldriven pusher propeller just behind the pilot. Bryan Allen, a biologist, pilot and racing cyclist, joined the team to provide the muscle-power. After over two hundred flights they were ready to make an attempt on the prize, and on 23 August 1977 they succeeded where many had failed, in 7 minutes. Kremer then offered £100,000 for the first manpowered flight across the English Channel. Many thought this would be impossible, but MacCready and his team set about the task of designing a new machine based on their Condor, which they called the Gossamer Albatross. Bryan Allen also had a major task: getting fit for a flight which might take three hours of pedalling. The weather was more of a problem than in California, and after a long delay the Gossamer Albatross took off, on 12 June 1979. After pedalling for 2 hours 49 minutes, Bryan Allen landed in France: it was seventy years since Blériot's flight, although Blériot was much quicker.

[br]

Principal Honours and Distinctions

World Gliding Champion 1953.

Bibliography

1979, "The Channel crossing and the future", Man Powered Aircraft Symposium, London: Royal Aeronautical Society.

Further Reading

M.Grosser, 1981, Gossamer Odyssey, London (provides a brief biography and detailed accounts of the two aircraft).

M.F.Jerram, 1980, Incredible Flying Machines, London (a short survey of pedal planes).

Articles by Ron Moulton on the Gossamer Albatross appeared in Aerospace (Royal Aeronautical Society) London, August/September 1979, and the Aeromodeller, London, September 1979.

JDS

batch

1) партия (продукта, изделий)

2) порция; одноразовая загрузка; дозировка || загружать; дозировать

3) садка; изделия из материала одной плавки

4) шихта

5) производственная серия || пускать в серийное производство

6) замес (бетона, раствора) || производить замес (бетона, раствора)

7) пищ. масса теста для одной выпечки

8) парфюм. навеска

9) полигр. привёртка

10) вчт. пакет, группа; серия

•

to batch by volume — дозировать по объёму;

to batch by weight — дозировать по массе;

to design batch — проектировать (составлять) замес;

to batch off — 1. снимать (срезать) резиновую смесь с вальцев 2. принимать заправку резиновой смеси;

to proportion batch — проектировать (составлять) замес;

to batch up — 1. производить замес 2. закатывать в рулон

batch of bricks — штабель кирпича

batch of ore — порция( железной) руды

-
agglomerated batch
-
aircrafts batch
-
bad batch
-
briquetted batch
-
card batch
-
charge batch
-
colored batch
-
developed batch
-
dry batch
-
dry-weighed batch
-
flint batch
-
float batch
-
glass batch
-
granulated batch
-
job batch
-
loose batch
-
master batch
-
pelletized batch
-
pilot batch
-
preproduction batch
-
production batch
-
remote batch
-
spilled batch
-
trial batch
-
wagon batch
-
wetted batch

Booth, Hubert Cecil

SUBJECT AREA: Civil engineering, Domestic appliances and interiors, Mechanical, pneumatic and hydraulic engineering, Ports and shipping

[br]

b. 1871 Gloucester, England d. 1955

[br]

English mechanical, civil and construction engineer best remembered as the inventor of the vacuum cleaner.

[br]

As an engineer Booth contributed to the design of engines for Royal Navy battleships, designed and supervised the erection of a number of great wheels (in Blackpool, Vienna and Paris) and later designed factories and bridges.

In 1900 he attended a demonstration, at St Paneras Station in London, of a new form of railway carriage cleaner that was supposed to blow the dirt into a container. It was not a very successful experiment and Booth, having considered the problem carefully, decided that sucking might be better than blowing. He tried out his idea by placing a piece of damp cloth over an upholstered armchair. When he sucked air by mouth through his cloth the dirt upon it was tangible proof of his theory.

Various attempts were being made at this time, especially in America, to find a successful cleaner of carpets and upholstery. Booth produced the first truly satisfactory machine, which he patented in 1901, and coined the term "vacuum cleaner". He formed the Vacuum Cleaner Co. (later to become Goblin BVC Ltd) and began to manufacture his machines. For some years the company provided a cleaning service to town houses, using a large and costly vacuum cleaner (the first model cost £350). Painted scarlet, it measured 54×10×42 in. (137×25×110 cm) and was powered by a petrol-driven 5 hp piston engine. It was transported through the streets on a horse-driven van and was handled by a team of operators who parked outside the house to be cleaned. With the aid of several hundred feet of flexible hose extending from the cleaner through the windows into all the rooms, the machine sucked the dirt of decades from the carpets; at the first cleaning the weight of many such carpets was reduced by 50 per cent as the dirt was sucked away.

Many attempts were made in Europe and America to produce a smaller and less expensive machine. Booth himself designed the chief British model in 1906, the Trolley- Vac, which was wheeled around the house on a trolley. Still elaborate, expensive and heavy, this machine could, however, be operated inside a room and was powered from an electric light fitting. It consisted of a sophisticated electric motor and a belt-driven rotary vacuum pump. Various hoses and fitments made possible the cleaning of many different surfaces and the dust was trapped in a cloth filter within a small metal canister. It was a superb vacuum cleaner but cost 35 guineas and weighed a hundredweight (50 kg), so it was difficult to take upstairs.

Various alternative machines that were cheaper and lighter were devised, but none was truly efficient until a prototype that married a small electric motor to the machine was produced in 1907 in America.

[br]

Further Reading

The Story of the World's First Vacuum Cleaner, Leatherhead: BSR (Housewares) Ltd. See also Hoover, William Henry.

DY