machine+development

constante

adj.

1 persistent (person) (en una empresa).

2 constant.

3 unchanging, uniform, consistent, constant.

4 dedicated, hardworking.

f.

1 constant.

constantes vitales (medicine) vital signs

mantener las constantes vitales de alguien (medicine) to keep somebody alive

2 Constante.

* * *

constante

► adjetivo

1 (invariable) constant

2 (persona) steadfast

► nombre femenino

1 MATEMÁTICAS constant

\

FRASEOLOGÍA

constantes vitales vital signs

* * *

adj.

constant

* * *

1. ADJ

1) (=continuado) constant

la búsqueda constante de la verdad — the constant search for truth

un día de lluvia constante — a day of constant o persistent rain

2) (=frecuente) constant

recibía constantes advertencias de su jefe — she was getting constant warnings from her boss

3) (=perseverante) [persona] persevering

4) (Fís) [velocidad, temperatura, presión] constant

2. SF

1) (=factor predominante)

el mar es una constante en su obra — the sea is a constant theme o an ever-present theme in his work

el paro es una constante en la economía española — unemployment is a permanent feature of the Spanish economy

constante histórica — historical constant

2) (Mat) constant

3) (Med)

constantes vitales — vital signs

* * *

I

adjetivo

1) ( continuo) constant

2) ( perseverante) < persona> persevering

II

femenino

a) (Mat) constant

b) ( característica) constant feature

una constante en su obra — a constant theme in his work

el malhumor es una constante en él — he's always in a bad mood

c) constantes femenino plural (Med) tb

constantes vitales — vital signs (pl)

* * *

= constant, continual, continued, continuing, continuous, even, ongoing [on-going], persistent, regular, unvarying, steadfast, perpetual, steady [steadier -comp., steadiest -sup.], abiding, unfailing, unabated, constant, standing, unflagging, assiduous, on-the-go, unceasing, incessant, ceaseless, persevering.

Ex. Film and videotape are stored on the premises in vaults situated at the back of the library and are air conditioned to ensure a constant temperature.

Ex. The second point concerns the continual reference to Haykin's book, a sort of code of subject authority practice and its drawbacks.

Ex. Instructional development is a goal-oriented, problem-solving process involving techniques such as development of specific objectives, analysis of learners and tasks, preliminary trials, formative and summative evaluation, and continued revision.

Ex. They are likely to influence the future function of DC, and the way in which the scheme will evolve, but since there will be a continuing need for shelf arrangement, DC will remain necessary.

Ex. However, in 1983, Forest Press decided to opt for the concept of continuous revision.

Ex. An unvarying level of illumination, heating, cooling, ventilation and acoustics will give the even type of environment needed in an academic library.

Ex. This study has many implications for an ongoing COMARC effort beyond the present pilot project because it is evident that a very small number of libraries can furnish machine-readable records with full LC/MARC encoding.

Ex. Cases keep discussion grounded on certain persistent facts that must be faced, and keep a realistic rein on airy flights of academic speculation.

Ex. Book form was generally regarded as too inflexible for library catalogues, especially where the catalogue required regular updating to cater for continuing and gradual expansion of the collection.

Ex. An unvarying level of illumination, heating, cooling, ventilation and acoustics will give the even type of environment needed in an academic library.

Ex. He does admit, however, that 'this power is unusual, it is a gift which must be cultivated, an accomplishment which can only be acquired by vigorous and steadfast concentration'.

Ex. Possessed of a phenomenal memory and a perpetual smile, this paragon always is ready to meet the public without losing balance or a sense of humor.

Ex. Susan Blanch is a fairly steady customer, taking only fiction books.

Ex. The revision and correction of reference works is an abiding concern to the librarian and the user.

Ex. Public libraries can be characterized by an unfailing flexibility and sincere intent to help people solve problems.

Ex. The demand for English as the world's lingua franca continues unabated.

Ex. In this formula, curly brackets {} indicate activities, and alpha, beta and gamma are constants = En esta fórmula, las llaves {} indican actividades y alfa, beta y gamma son las constantes.

Ex. A standing reproach to all librarians is the non-user.

Ex. Colleagues from all the regions of the world harnessed their combined intellectual capital, tenacity, good will and unflagging spirit of volunteerism for the good of our profession = Colegas de todas las regiones del mundo utilizaron su capital intelectual, su tenacidad, su buena voluntad y su inagotable espíritu de voluntarismo para el bien de nuestra profesión.

Ex. The management of a large number of digital images requires assiduous attention to all stages of production.

Ex. With technologies such as SMS, Podcasting, voice over IP (VoIP), and more becoming increasingly mainstream, the potential to provide instant, on-the-go reference is limitless.

Ex. But just as she pulled over the road in the pitch blackness of night she heard the unceasing sound of the night like she had never heard it.

Ex. The great practical education of the Englishman is derived from incessant intercourse between man and man, in trade.

Ex. Children in modern society are faced with a ceaseless stream of new ideas, and responsibility for their upbringing has generally moved from parents to childminders and teachers.

Ex. Napoleon Bonaparte said: 'Victory belongs to the most persevering' and 'Ability is of little account without opportunity'.

----

* constante de bajada = slope constant.

* constante flujo de = steady stream of.

* constante vital = vital sign.

* crítica constante = nagging.

* de un modo constante = on an ongoing basis.

* en constante expansión = ever-expanding, ever-growing.

* en constante movimiento = on the go.

* los constantes cambios de = the changing face of, the changing nature of.

* mantenimiento de las constantes vitales = life support.

* máquina que mantiene las constantes vitales = life-support system.

* permanecer constante = remain + constant.

* que está en constante evolución = ever-evolving.

* serie constante de = steady stream of.

* ser una constante = be a constant.

* * *

I

adjetivo

1) ( continuo) constant

2) ( perseverante) < persona> persevering

II

femenino

a) (Mat) constant

b) ( característica) constant feature

una constante en su obra — a constant theme in his work

el malhumor es una constante en él — he's always in a bad mood

c) constantes femenino plural (Med) tb

constantes vitales — vital signs (pl)

* * *

= constant, continual, continued, continuing, continuous, even, ongoing [on-going], persistent, regular, unvarying, steadfast, perpetual, steady [steadier -comp., steadiest -sup.], abiding, unfailing, unabated, constant, standing, unflagging, assiduous, on-the-go, unceasing, incessant, ceaseless, persevering.

Ex: Film and videotape are stored on the premises in vaults situated at the back of the library and are air conditioned to ensure a constant temperature.

Ex: The second point concerns the continual reference to Haykin's book, a sort of code of subject authority practice and its drawbacks.

Ex: Instructional development is a goal-oriented, problem-solving process involving techniques such as development of specific objectives, analysis of learners and tasks, preliminary trials, formative and summative evaluation, and continued revision.

Ex: They are likely to influence the future function of DC, and the way in which the scheme will evolve, but since there will be a continuing need for shelf arrangement, DC will remain necessary.

Ex: However, in 1983, Forest Press decided to opt for the concept of continuous revision.

Ex: An unvarying level of illumination, heating, cooling, ventilation and acoustics will give the even type of environment needed in an academic library.

Ex: This study has many implications for an ongoing COMARC effort beyond the present pilot project because it is evident that a very small number of libraries can furnish machine-readable records with full LC/MARC encoding.

Ex: Cases keep discussion grounded on certain persistent facts that must be faced, and keep a realistic rein on airy flights of academic speculation.

Ex: Book form was generally regarded as too inflexible for library catalogues, especially where the catalogue required regular updating to cater for continuing and gradual expansion of the collection.

Ex: An unvarying level of illumination, heating, cooling, ventilation and acoustics will give the even type of environment needed in an academic library.

Ex: He does admit, however, that 'this power is unusual, it is a gift which must be cultivated, an accomplishment which can only be acquired by vigorous and steadfast concentration'.

Ex: Possessed of a phenomenal memory and a perpetual smile, this paragon always is ready to meet the public without losing balance or a sense of humor.

Ex: Susan Blanch is a fairly steady customer, taking only fiction books.

Ex: The revision and correction of reference works is an abiding concern to the librarian and the user.

Ex: Public libraries can be characterized by an unfailing flexibility and sincere intent to help people solve problems.

Ex: The demand for English as the world's lingua franca continues unabated.

Ex: In this formula, curly brackets {} indicate activities, and alpha, beta and gamma are constants = En esta fórmula, las llaves {} indican actividades y alfa, beta y gamma son las constantes.

Ex: A standing reproach to all librarians is the non-user.

Ex: Colleagues from all the regions of the world harnessed their combined intellectual capital, tenacity, good will and unflagging spirit of volunteerism for the good of our profession = Colegas de todas las regiones del mundo utilizaron su capital intelectual, su tenacidad, su buena voluntad y su inagotable espíritu de voluntarismo para el bien de nuestra profesión.

Ex: The management of a large number of digital images requires assiduous attention to all stages of production.

Ex: With technologies such as SMS, Podcasting, voice over IP (VoIP), and more becoming increasingly mainstream, the potential to provide instant, on-the-go reference is limitless.

Ex: But just as she pulled over the road in the pitch blackness of night she heard the unceasing sound of the night like she had never heard it.

Ex: The great practical education of the Englishman is derived from incessant intercourse between man and man, in trade.

Ex: Children in modern society are faced with a ceaseless stream of new ideas, and responsibility for their upbringing has generally moved from parents to childminders and teachers.

Ex: Napoleon Bonaparte said: 'Victory belongs to the most persevering' and 'Ability is of little account without opportunity'.

* constante de bajada = slope constant.

* constante flujo de = steady stream of.

* constante vital = vital sign.

* crítica constante = nagging.

* de un modo constante = on an ongoing basis.

* en constante expansión = ever-expanding, ever-growing.

* en constante movimiento = on the go.

* los constantes cambios de = the changing face of, the changing nature of.

* mantenimiento de las constantes vitales = life support.

* máquina que mantiene las constantes vitales = life-support system.

* permanecer constante = remain + constant.

* que está en constante evolución = ever-evolving.

* serie constante de = steady stream of.

* ser una constante = be a constant.

* * *

constante¹

adjective

A

1 (continuo) constant

estaba sometido a una constante vigilancia he was kept under constant surveillance

2 ‹tema/motivo› constant

B (perseverante) persevering

constante²

feminine

1 ( Mat) constant

2 (característica) constant feature

las escaseces han sido una constante durante los últimos siete años shortages have been a constant feature of the last seven years

durante estas fechas las colas son una constante en las tiendas at this time of year queues are a regular feature in the shops

una constante en su obra a constant theme in his work

el malhumor es una constante en él he's always in a bad mood

3 constantes fpl ( Med) tb

constantes vitales vital signs (pl)

* * *

 

constante adjetivo

a) ( continuo) constant

b) ( perseverante) ‹ persona› persevering

■ sustantivo femenino

a) (Mat) constant

b) ( característica) constant feature

c)

◊ constantes sustantivo femenino plural (Med) tb constantes vitales vital signs (pl)

constante
I adjetivo
1 (tenaz) steadfast: es una persona constante en sus ambiciones, he is steadfast in his ambitions
2 (incesante, sin variaciones) constant, incessant, unchanging: me mareaba el constante barullo que había allí, the constant racket there made me dizzy
II sustantivo femenino
1 constant feature: los desengaños fueron una constante a lo largo de su vida, disappointments were a constant during his lifetime
2 Mat constant
' constante' also found in these entries:
Spanish:
fiel
- salario
- sangría
English:
constant
- continual
- cruise
- equable
- even
- incessant
- recurrent
- steadily
- steady
- unfailing
- uniform
- unremitting
- break
- consistent
- drive
- eternal
- niggling
- persistent
- wear

* * *

constante

♦ adj

1. [persona] [en una empresa] persistent;

[en ideas, opiniones] steadfast;

se mantuvo constante en su esfuerzo he persevered in his efforts

2. [lluvia, atención] constant, persistent;

[temperatura] constant

3. [que se repite] constant

♦ nf

1. [rasgo] constant;

las desilusiones han sido una constante en su vida disappointments have been a constant feature in her life;

las tormentas son una constante en sus cuadros storms are an ever-present feature in his paintings;

la violencia es una constante histórica en la región the region has known violence throughout its history

2. Mat constant

3. constantes vitales vital signs;

mantener las constantes vitales de alguien to keep sb alive

* * *

constante

I adj constant

II f MAT constant

* * *

constante adj

: constant

♦ constantemente adv

constante nf

: constant

* * *

constante adj (continuo) constant

ininterrumpido

adj.

uninterrupted, continuous, breakless, sustained.

* * *

ininterrumpido

► adjetivo

1 uninterrupted

* * *

ADJ (=sin interrupción) [gen] uninterrupted; [proceso] continuous; [progreso] steady, sustained

20 horas de música ininterrumpida — 20 hours of non-stop o uninterrupted music

llovió de forma ininterrumpida — it rained continuously o non-stop

la película se proyecta de manera ininterrumpida — the film is shown uninterrupted o without a break

* * *

- da adjetivo <lluvias/trabajo> continuous, uninterrupted; < sueño> uninterrupted; < línea> continuous

seis horas de música ininterrumpida — six hours of nonstop music

* * *

= continued, continuous, ongoing [on-going], running, sustained, unbroken, steady [steadier -comp., steadiest -sup.], uninterrupted, unobstructed, in a row, back-to-back, on-the-go.

Ex. Instructional development is a goal-oriented, problem-solving process involving techniques such as development of specific objectives, analysis of learners and tasks, preliminary trials, formative and summative evaluation, and continued revision.

Ex. However, in 1983, Forest Press decided to opt for the concept of continuous revision.

Ex. This study has many implications for an ongoing COMARC effort beyond the present pilot project because it is evident that a very small number of libraries can furnish machine-readable records with full LC/MARC encoding.

Ex. Tom Hernandez knew that there had been a ' running feud' between Lespran and Balzac during the last year or so.

Ex. Research has shown that strong centralized control of employees is not the best way to achieve operational efficiency or sustained productivity.

Ex. Ideally it would be preferable to keep the main monograph collection in one unbroken sequence.

Ex. Susan Blanch is a fairly steady customer, taking only fiction books.

Ex. For this purpose it is assumed that the usual 23-letter latin alphabet, or an uninterrupted series of numerals, is used for signing the gatherings.

Ex. From the library she could see miles and miles of unobstructed vistas of rich, coffee-brown, almost black soil, broken only by occasional small towns, farms, and grain elevators.

Ex. The integrated library systems installed in Canandian libraries are surveyed for the 3rd year in a row.

Ex. The conference program includes back-to-back papers on techniques for sorting Unicode data.

Ex. With technologies such as SMS, Podcasting, voice over IP (VoIP), and more becoming increasingly mainstream, the potential to provide instant, on-the-go reference is limitless.

----

* de modo ininterrumpido = in an unbroken line.

* * *

- da adjetivo <lluvias/trabajo> continuous, uninterrupted; < sueño> uninterrupted; < línea> continuous

seis horas de música ininterrumpida — six hours of nonstop music

* * *

= continued, continuous, ongoing [on-going], running, sustained, unbroken, steady [steadier -comp., steadiest -sup.], uninterrupted, unobstructed, in a row, back-to-back, on-the-go.

Ex: Instructional development is a goal-oriented, problem-solving process involving techniques such as development of specific objectives, analysis of learners and tasks, preliminary trials, formative and summative evaluation, and continued revision.

Ex: However, in 1983, Forest Press decided to opt for the concept of continuous revision.

Ex: This study has many implications for an ongoing COMARC effort beyond the present pilot project because it is evident that a very small number of libraries can furnish machine-readable records with full LC/MARC encoding.

Ex: Tom Hernandez knew that there had been a ' running feud' between Lespran and Balzac during the last year or so.

Ex: Research has shown that strong centralized control of employees is not the best way to achieve operational efficiency or sustained productivity.

Ex: Ideally it would be preferable to keep the main monograph collection in one unbroken sequence.

Ex: Susan Blanch is a fairly steady customer, taking only fiction books.

Ex: For this purpose it is assumed that the usual 23-letter latin alphabet, or an uninterrupted series of numerals, is used for signing the gatherings.

Ex: From the library she could see miles and miles of unobstructed vistas of rich, coffee-brown, almost black soil, broken only by occasional small towns, farms, and grain elevators.

Ex: The integrated library systems installed in Canandian libraries are surveyed for the 3rd year in a row.

Ex: The conference program includes back-to-back papers on techniques for sorting Unicode data.

Ex: With technologies such as SMS, Podcasting, voice over IP (VoIP), and more becoming increasingly mainstream, the potential to provide instant, on-the-go reference is limitless.

* de modo ininterrumpido = in an unbroken line.

* * *

ininterrumpido -da

adjective

‹lluvias› continuous, uninterrupted; ‹sueño› uninterrupted; ‹línea› continuous

seis horas de música ininterrumpida six hours of nonstop music

20 horas de funcionamiento ininterrumpido 20 hours of continuous use

* * *

ininterrumpido

◊ -da adjetivo ‹lluvias/trabajo› continuous, uninterrupted;

‹ sueño› uninterrupted;
‹ línea› continuous
ininterrumpido,-a adjetivo uninterrupted, continuous
' ininterrumpido' also found in these entries:
Spanish:
ininterrumpida
English:
undisturbed
- uninterrupted
- solid
- unbroken

* * *

ininterrumpido, -a adj

uninterrupted, continuous;

bailaron durante cinco horas ininterrumpidas they danced for five hours non-stop;

lleva tres años ininterrumpidos viviendo en el país she's been living in the country continuously for three years

* * *

ininterrumpido

adj uninterrupted

* * *

ininterrumpido, -da adj

: uninterrupted, continuous

♦ ininterrumpidamente adv

проходческий комбайн

1) Geology: continuous heading machine

2) Engineering: borer, development machine, entry-driving machine, heading machine, road heading machine, roadheader, tunneler, tunneling machine

3) Mining: combination cutting and loading machine, continuous heading machine (штрековый), entry driver, helldiver, mechanical mole, tunnel borer (для проходки горизонтальных выработок), tunnel boring machine (для проходки горизонтальных выработок), tunnelling machine

4) Makarov: mining machine

5) Gold mining: road header

Fourdrinier, Henry

SUBJECT AREA: Paper and printing

[br]

b. 11 February 1766 London, England

d. 3 September 1854 Mavesyn Ridware, near Rugeley, Staffordshire, England

[br]

English pioneer of the papermaking machine.

[br]

Fourdrinier's father was a paper manufacturer and stationer of London, from a family of French Protestant origin. Henry took up the same trade and, with his brother Sealy (d. 1847), devoted many years to developing the papermaking machine. Their first patent was taken out in 1801, but success was still far off. A machine for making paper had been invented a few years previously by Nicolas Robert at the Didot's mill at Essonnes, south of Paris. Robert quarrelled with the Didots, who then contacted their brother-in-law in England, John Gamble, in an attempt to raise capital for a larger machine. Gamble and the Fourdriniers called in the engineer Bryan Donkin, and between them they patented a much improved machine in 1807. In the new machine, the paper pulp flowed on to a moving continuous woven wire screen and was then squeezed between rollers to remove much of the water. The paper thus formed was transferred to a felt blanket and passed through a second press to remove more water, before being wound while still wet on to a drum. For the first time, a continuous sheet of paper could be made. Other inventors soon made further improvements: in 1817 John Dickinson obtained a patent for sizing baths to improve the surface of the paper; while in 1820 Thomas Crompton patented a steam-heated drum round which the paper was passed to speed up the drying process. The development cost of £60,000 bankrupted the brothers. Although Parliament extended the patent for fourteen years, and the machine was widely adopted, they never reaped much profit from it. Tsar Alexander of Russia became interested in the papermaking machine while on a visit to England in 1814 and promised Henry Fourdrinier £700 per year for ten years for super-intending the erection of two machines in Russia; Henry carried out the work, but he received no payment. At the age of 72 he travelled to St Petersburg to seek recompense from the Tsar's successor Nicholas I, but to no avail. Eventually, on a motion in the House of Commons, the British Government awarded Fourdrinier a payment of £7,000. The paper trade, sensing the inadequacy of this sum, augmented it with a further sum which they subscribed so that an annuity could be purchased for Henry, then the only surviving brother, and his two daughters, to enable them to live in modest comfort. From its invention in ancient China (see Cai Lun), its appearance in the Middle Ages in Europe and through the first three and a half centuries of printing, every sheet of paper had to made by hand. The daily output of a hand-made paper mill was only 60–100 lb (27–45 kg), whereas the new machine increased that tenfold. Even higher speeds were achieved, with corresponding reductions in cost; the old mills could not possibly have kept pace with the new mechanical printing presses. The Fourdrinier machine was thus an essential element in the technological developments that brought about the revolution in the production of reading matter of all kinds during the nineteenth century. The high-speed, giant paper-making machines of the late twentieth century work on the same principle as the Fourdrinier of 1807.

[br]

Further Reading

R.H.Clapperton, 1967, The Paper-making Machine, Oxford: Pergamon Press. D.Hunter, 1947, Papermaking. The History and Technique of an Ancient Craft, London.

LRD

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]

Bibliography

1738, British patent no. 562 (spinning machine). 1748, British patent no. 636 (carding machine).

1758, British patent no. 724 (circular spinning machine).

Further Reading

G.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

проходческая машина

1) Geology: sinking machine

2) Engineering: development machine, head-road machine, head-roader, heading machine, tunneling machine

3) Mining: sinking machine (для вертикальных и наклонных выработок)

4) Makarov: bead-road machine, bead-road tunneling machine, beading machine

organización

f.

1 organization, hierarchy, array, structure.

2 institution, entity, organism, foundation.

3 organizing.

* * *

organización

► nombre femenino

1 organization

* * *

noun f.

organization

* * *

SF organization

Organización de Estados Americanos — Organization of American States

Organización de las Naciones Unidas — United Nations Organization

organización no gubernamental — non-governmental organization

OPEP

* * *

femenino organization

una organización sindical — a labor (AmE) o (BrE) trade union

* * *

femenino organization

una organización sindical — a labor (AmE) o (BrE) trade union

* * *

organización¹

¹ = establishment, organisation [organization, -USA], institution.

Ex: Since BC adheres closely to the educational and scientific consensus, BC found most favour with libraries in educational establishments.

Ex: The author of a document is the person or organisation responsible for its creation.

Ex: The distinction between 'societies' and 'institutions' lies at the heart of the code.

* Comité de las Organizaciones = Committee of Agricultural Producer Organizations (COPA).

* comportamiento de las organizaciones = organisational behaviour.

* comunicación dentro de una organización = organisational communication.

* conducta de las organizaciones = organisational behaviour.

* OPEC, la [Organización de Países Exportadores de Petróleo] = OPEC [Organization of Petroleum Exporting Countries].

* organigrama de una organización = organisation chart.

* organización afiliada = sister organisation.

* organización agraria = agricultural organisation.

* organización a la que pertenece = parent organisation.

* organización benéfica = aid agency, aid organisation.

* organización cívica = community organisation.

* Organización Cultural, Científica y Educativa de las Naciones Unidas (UNESCO = UNESCO (United Nations Educational, Scientific, and Cultural Organization).

* organización de voluntariado = voluntary body, voluntary agency, voluntary organisation.

* organización empresarial = business organisation.

* organización intergubernamental (OIG) = intergovernmental organisation (IGO).

* organización internacional = international organisation.

* Organización Internacional del Trabajo (OIT) = International Labour Organisation (ILO).

* Organización Internacional de Normalización = ISO.

* organización mafiosa = crime syndicate.

* organización miembro de una asociación = partner organisation.

* Organización Mundial de la Salud (OMS) = World Health Organisation (WHO).

* Organización Mundial para el Comercio = World Trade Organization (WTO).

* Organización para la Alimentación y la Agricultura (FAO) = FAO (Food and Agriculture Organisation).

* Organización para la Cooperación y el Desarrollo Económico (OCDE) = Organization for Economic Cooperation and Development (OECD).

* organización que actúa en representación de otras = umbrella organisation.

* OTAN (Organización del Tratado del Atlántico Norte) = NATO (North Atlantic Treaty Organisation).

* una pieza más en la organización = a cog in the wheel, a cog in the machine.

* uno más de tantos en la organización = a cog in the wheel, a cog in the machine.

organización²

² = logistics, map, mapping, organisational setting, organising [organizing, -USA], setup [set-up], organisation [organization, -USA], work organisation, staging, set-up, structuring, implementation.

Ex: Donald P Hammer, Executive Secretary of LITA, and Dorothy Butler, the Division's Administrative Secretary, handled all of the administrative details, arrangements, and logistics.

Ex: A detailed study of a co-citation map, its core documents' citation patterns and the related journal structures, is presented.

Ex: Recently, proponents of co-citation cluster analysis have claimed that in principle their methodology makes possible the mapping of science using the data in the Science Citation Index.

Ex: Many students, after working with cases, have testified to the help they received in developing a clearer concept of the dynamics of human relationships in organizational settings.

Ex: No course on management would be complete without articulating the principles of management (i.e., planning, organizing, staffing, directing, controlling).

Ex: 'You know,' she had said amiably, 'there might be a better job for you here once things get rolling with this new regional setup'.

Ex: This article discusses the history of the organisation of readers' camps for students of secondary schools in Slovakia which dates back to 1979.

Ex: Quality of Work Life (QWL) can be defined as 'the degree to which members of a work organisation are able to satisfy important personal needs through their experiences in the organisation'.

Ex: The author describes the success of a library in staging a series of music concerts as a public relations exercise.

Ex: Areas of particular concern are: equipment set-up and use; helping develop search strategies, logon/logoff procedures; and emergency assistance when things go wrong.

Ex: There are also suggestions for rules for structuring corporate body names.

Ex: This software is important to the further implementation of the record format, especially in developing countries.

* conocimientos básicos de búsqueda, recuperación y organización de la informa = information literacy.

* desorganización = disorganisation [disorganization, -USA].

* metaorganización = meta-organisation.

* modelo de organización = organisational scheme.

* organización bibliográfica = bibliographic organisation.

* organización bibliotecaria = library organisation.

* organización del trabajo = workflow [work flow], working arrangement.

* organización de materias = subject organisation.

* organización horizontal = flat organisation, horizontal organisation.

* organización interna = organisational structure.

* organización laboral = job structuring.

* reorganización = respacing.

* una organización de = a pattern of.

* * *

organización

feminine

1 (acción) organization

2 (agrupación, institución) organization

una organización ecologista an ecological organization

una organización sindical a labor ( AmE) o ( BrE) trade union

organización de bienestar social welfare organization

Compuestos:

● Organización de Cooperación y Desarrollo Económico

Organization for Economic Cooperation and Development

● Organización Mundial de la Propiedad Intelectual

World Intellectual Property Organization

● Organización Mundial del Comercio

World Trade Organization

* * *

 

organización sustantivo femenino
organization
organización sustantivo femenino
1 organization: la organización del concierto fue un desastre, the concert was disastrously organized
2 (asociación) organization
Organización No Gubernamental (ONG), Non-Governmental Organization (NGO)
' organización' also found in these entries:
Spanish:
adherirse
- aparato
- desactivar
- endosar
- entrar
- escala
- F.A.O.
- INTERPOL
- lucro
- mafiosa
- mafioso
- ONG
- OTAN
- OUA
- sede
- seno
- terrorista
- adhesión
- articulación
- barón
- boda
- caritativo
- correr
- cuadro
- cúspide
- depurar
- disolución
- disolver
- emplear
- entidad
- funcionario
- infiltrar
- ingresar
- ingreso
- integrar
- jerarquía
- marina
- miembro
- obra
- ONCE
- ONU
- permanencia
- pertenencia
- programación
- radio
- remodelación
- remodelar
- renovación
- renovar
- representar
English:
base
- charitable
- charity
- disband
- entrance
- Interpol
- join
- lead
- motto
- NATO
- NGO
- nonprofit
- organization
- outfit
- patron
- picketing
- PLO
- policy
- reshape
- service
- set-up
- shake up
- show
- start
- superintendent
- system
- top-heavy
- trust
- umbrella organisation
- voluntary organization
- watchdog
- credit
- in-house
- insider
- second
- syndicate
- united

* * *

organización nf

1. [orden] organization

2. [organismo] organization;

las organizaciones sindicales the trade o US labor unions

Comp

organización de ayuda humanitaria humanitarian aid organization;

organización benéfica charity, charitable organization;

organización de consumidores consumer organization;

Organización para la Cooperación y el Desarrollo Económico Organization for Economic Cooperation and Development;

Organización de Estados Americanos Organization of American States;

Organización Internacional de Normalización International Standards Organization;

Organización Internacional del Trabajo International Labour Organization;

Organización para la Liberación de Palestina Palestine Liberation Organization;

Organización Mundial del Comercio World Trade Organization;

Organización Mundial de la Salud World Health Organization;

Organización de las Naciones Unidas United Nations Organization;

organización no gubernamental non-governmental organization;

Organización de Países Exportadores de Petróleo Organization of Petroleum Exporting Countries;

Organización para la Seguridad y Cooperación en Europa Organization for Security and Cooperation in Europe;

Organización para la Unidad Africana Organization of African Unity;

Organización del Tratado del Atlántico Norte North Atlantic Treaty Organization

* * *

organización

f organization

* * *

organización nf, pl - ciones : organization

* * *

organización n organization

Corliss, George Henry

SUBJECT AREA: Steam and internal combustion engines

[br]

b. 2 June 1817 Easton, Washington City, New York, USA

d. 21 February 1888 USA

[br]

American inventor of a cut-off mechanism linked to the governor which revolutionized the operation of steam engines.

[br]

Corliss's father was a physician and surgeon. The son was educated at Greenwich, New York, but while he showed an aptitude for mathematics and mechanics he first of all became a storekeeper and then clerk, bookkeeper, salesperson and official measurer and inspector of the cloth produced at W.Mowbray \& Son. He went to the Castleton Academy, Vermont, for three years and at the age of 21 returned to a store of his own in Greenwich. Complaints about stitching in the boots he sold led him to patent a sewing machine. He approached Fairbanks, Bancroft \& Co., Providence, Rhode Island, machine and steam engine builders, about producing his machine, but they agreed to take him on as a draughtsman providing he abandoned it. Corliss moved to Providence with his family and soon revolutionized the design and construction of steam engines. Although he started working out ideas for his engine in 1846 and completed one in 1848 for the Providence Dyeing, Bleaching and Calendering Company, it was not until March 1849 that he obtained a patent. By that time he had joined John Barstow and E.J.Nightingale to form a new company, Corliss Nightingale \& Co., to build his design of steam-engines. He used paired valves, two inlet and two exhaust, placed on opposite sides of the cylinder, which gave good thermal properties in the flow of steam. His wrist-plate operating mechanism gave quick opening and his trip mechanism allowed the governor to regulate the closure of the inlet valve, giving maximum expansion for any load. It has been claimed that Corliss should rank equally with James Watt in the development of the steam-engine. The new company bought land in Providence for a factory which was completed in 1856 when the Corliss Engine Company was incorporated. Corliss directed the business activities as well as technical improvements. He took out further patents modifying his valve gear in 1851, 1852, 1859, 1867, 1875, 1880. The business grew until well over 1,000 workers were employed. The cylindrical oscillating valve normally associated with the Corliss engine did not make its appearance until 1850 and was included in the 1859 patent. The impressive beam engine designed for the 1876 Centennial Exhibition by E. Reynolds was the product of Corliss's works. Corliss also patented gear-cutting machines, boilers, condensing apparatus and a pumping engine for waterworks. While having little interest in politics, he represented North Providence in the General Assembly of Rhode Island between 1868 and 1870.

[br]

Further Reading

Many obituaries appeared in engineering journals at the time of his death. Dictionary of American Biography, 1930, Vol. IV, New York: C.Scribner's Sons. R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press (explains Corliss's development of his valve gear).

J.L.Wood, 1980–1, "The introduction of the Corliss engine to Britain", Transactions of the Newcomen Society 52 (provides an account of the introduction of his valve gear to Britain).

W.H.Uhland, 1879, Corliss Engines and Allied Steam-motors, London: E. \& F.N.Spon.

RLH

Language

   1) The Book of Nature Is Written in the Language of Mathematics

   Philosophy is written in that great book, the universe, which is always open, right before our eyes. But one cannot understand this book without first learning to understand the language and to know the characters in which it is written. It is written in the language of mathematics, and the characters are triangles, circles, and other figures. Without these, one cannot understand a single word of it, and just wanders in a dark labyrinth. (Galileo, 1990, p. 232)

   2) Arranging Speech so as to Reply Appropriately

   It never happens that it [a nonhuman animal] arranges its speech in various ways in order to reply appropriately to everything that may be said in its presence, as even the lowest type of man can do. (Descartes, 1970a, p. 116)

   3) No Other Animal Has the Language Capacity of the Human

   It is a very remarkable fact that there are none so depraved and stupid, without even excepting idiots, that they cannot arrange different words together, forming of them a statement by which they make known their thoughts; while, on the other hand, there is no other animal, however perfect and fortunately circumstanced it may be, which can do the same. (Descartes, 1967, p. 116)

   4) Human Beings Do Not Live Only in the World of Objects

   Human beings do not live in the object world alone, nor alone in the world of social activity as ordinarily understood, but are very much at the mercy of the particular language which has become the medium of expression for their society. It is quite an illusion to imagine that one adjusts to reality essentially without the use of language and that language is merely an incidental means of solving specific problems of communication or reflection. The fact of the matter is that the "real world" is to a large extent unconsciously built on the language habits of the group.... We see and hear and otherwise experience very largely as we do because the language habits of our community predispose certain choices of interpretation. (Sapir, 1921, p. 75)

   5) Language Powerfully Conditions All Our Thinking

   It powerfully conditions all our thinking about social problems and processes.... No two languages are ever sufficiently similar to be considered as representing the same social reality. The worlds in which different societies live are distinct worlds, not merely the same worlds with different labels attached. (Sapir, 1985, p. 162)

   6) A List of Language Games

   [A list of language games, not meant to be exhaustive:]

   Giving orders, and obeying them- Describing the appearance of an object, or giving its measurements- Constructing an object from a description (a drawing)Reporting an eventSpeculating about an eventForming and testing a hypothesisPresenting the results of an experiment in tables and diagramsMaking up a story; and reading itPlay actingSinging catchesGuessing riddlesMaking a joke; and telling it

   Solving a problem in practical arithmeticTranslating from one language into another

   LANGUAGE Asking, thanking, cursing, greeting, and praying-. (Wittgenstein, 1953, Pt. I, No. 23, pp. 11 e-12 e)

   7) Language Constrains Certain Modes of Interpretation

   We dissect nature along lines laid down by our native languages.... The world is presented in a kaleidoscopic flux of impressions which has to be organized by our minds-and this means largely by the linguistic systems in our minds.... No individual is free to describe nature with absolute impartiality but is constrained to certain modes of interpretation even while he thinks himself most free. (Whorf, 1956, pp. 153, 213-214)

   8) We Dissect Nature in Accordance with Our Native Languages

   We dissect nature along the lines laid down by our native languages.

   The categories and types that we isolate from the world of phenomena we do not find there because they stare every observer in the face; on the contrary, the world is presented in a kaleidoscopic flux of impressions which has to be organized by our minds-and this means largely by the linguistic systems in our minds.... We are thus introduced to a new principle of relativity, which holds that all observers are not led by the same physical evidence to the same picture of the universe, unless their linguistic backgrounds are similar or can in some way be calibrated. (Whorf, 1956, pp. 213-214)

   9) The Forms of a Person's Thoughts Are Controlled by Unperceived Patterns of His Own Language

   The forms of a person's thoughts are controlled by inexorable laws of pattern of which he is unconscious. These patterns are the unperceived intricate systematizations of his own language-shown readily enough by a candid comparison and contrast with other languages, especially those of a different linguistic family. (Whorf, 1956, p. 252)

    10) The Analysis of Certain Types of Utterances

   It has come to be commonly held that many utterances which look like statements are either not intended at all, or only intended in part, to record or impart straightforward information about the facts.... Many traditional philosophical perplexities have arisen through a mistake-the mistake of taking as straightforward statements of fact utterances which are either (in interesting non-grammatical ways) nonsensical or else intended as something quite different. (Austin, 1962, pp. 2-3)

    11) The Dictionary of a Language Is a System of Concepts

   In general, one might define a complex of semantic components connected by logical constants as a concept. The dictionary of a language is then a system of concepts in which a phonological form and certain syntactic and morphological characteristics are assigned to each concept. This system of concepts is structured by several types of relations. It is supplemented, furthermore, by redundancy or implicational rules..., representing general properties of the whole system of concepts.... At least a relevant part of these general rules is not bound to particular languages, but represents presumably universal structures of natural languages. They are not learned, but are rather a part of the human ability to acquire an arbitrary natural language. (Bierwisch, 1970, pp. 171-172)

    12) Talk about the Evolution of the Language Capacity is Beside the Point

   In studying the evolution of mind, we cannot guess to what extent there are physically possible alternatives to, say, transformational generative grammar, for an organism meeting certain other physical conditions characteristic of humans. Conceivably, there are none-or very few-in which case talk about evolution of the language capacity is beside the point. (Chomsky, 1972, p. 98)

    13) The Development of Language

   [It is] truth value rather than syntactic well-formedness that chiefly governs explicit verbal reinforcement by parents-which renders mildly paradoxical the fact that the usual product of such a training schedule is an adult whose speech is highly grammatical but not notably truthful. (R. O. Brown, 1973, p. 330)

    14) Sentential and Conceptual Levels in Language

   he conceptual base is responsible for formally representing the concepts underlying an utterance.... A given word in a language may or may not have one or more concepts underlying it.... On the sentential level, the utterances of a given language are encoded within a syntactic structure of that language. The basic construction of the sentential level is the sentence.

   The next highest level... is the conceptual level. We call the basic construction of this level the conceptualization. A conceptualization consists of concepts and certain relations among those concepts. We can consider that both levels exist at the same point in time and that for any unit on one level, some corresponding realizate exists on the other level. This realizate may be null or extremely complex.... Conceptualizations may relate to other conceptualizations by nesting or other specified relationships. (Schank, 1973, pp. 191-192)

    15) Linguistic Realities Have Not Yet Been Captured by Theoretical Models

   The mathematics of multi-dimensional interactive spaces and lattices, the projection of "computer behavior" on to possible models of cerebral functions, the theoretical and mechanical investigation of artificial intelligence, are producing a stream of sophisticated, often suggestive ideas.

   But it is, I believe, fair to say that nothing put forward until now in either theoretic design or mechanical mimicry comes even remotely in reach of the most rudimentary linguistic realities. (Steiner, 1975, p. 284)

    16) The Final Steps to Human Language

   The step from the simple tool to the master tool, a tool to make tools (what we would now call a machine tool), seems to me indeed to parallel the final step to human language, which I call reconstitution. It expresses in a practical and social context the same understanding of hierarchy, and shows the same analysis by function as a basis for synthesis. (Bronowski, 1977, pp. 127-128)

    17) The Inadequacy of Formal Linguistic Models for Ordinary Language Usage

    t is the language donn eґ in which we conduct our lives.... We have no other. And the danger is that formal linguistic models, in their loosely argued analogy with the axiomatic structure of the mathematical sciences, may block perception.... It is quite conceivable that, in language, continuous induction from simple, elemental units to more complex, realistic forms is not justified. The extent and formal "undecidability" of context-and every linguistic particle above the level of the phoneme is context-bound-may make it impossible, except in the most abstract, meta-linguistic sense, to pass from "pro-verbs," "kernals," or "deep deep structures" to actual speech. (Steiner, 1975, pp. 111-113)

    18) When a Language Is an Abstract Machine

   A higher-level formal language is an abstract machine. (Weizenbaum, 1976, p. 113)

    19) Metaphor and Metonymy Underpin the Formation of Linguistic Signs

   Jakobson sees metaphor and metonymy as the characteristic modes of binarily opposed polarities which between them underpin the two-fold process of selection and combination by which linguistic signs are formed.... Thus messages are constructed, as Saussure said, by a combination of a "horizontal" movement, which combines words together, and a "vertical" movement, which selects the particular words from the available inventory or "inner storehouse" of the language. The combinative (or syntagmatic) process manifests itself in contiguity (one word being placed next to another) and its mode is metonymic. The selective (or associative) process manifests itself in similarity (one word or concept being "like" another) and its mode is metaphoric. The "opposition" of metaphor and metonymy therefore may be said to represent in effect the essence of the total opposition between the synchronic mode of language (its immediate, coexistent, "vertical" relationships) and its diachronic mode (its sequential, successive, lineal progressive relationships). (Hawkes, 1977, pp. 77-78)

    20) Language and the Analysis of Nature

   It is striking that the layered structure that man has given to language constantly reappears in his analyses of nature. (Bronowski, 1977, p. 121)

    21) Correspondence Rules for Mapping Old Theory into Subsets of New Theory

   First, [an ideal intertheoretic reduction] provides us with a set of rules"correspondence rules" or "bridge laws," as the standard vernacular has it-which effect a mapping of the terms of the old theory (T o) onto a subset of the expressions of the new or reducing theory (T n). These rules guide the application of those selected expressions of T n in the following way: we are free to make singular applications of their correspondencerule doppelgangers in T o....

   Second, and equally important, a successful reduction ideally has the outcome that, under the term mapping effected by the correspondence rules, the central principles of T o (those of semantic and systematic importance) are mapped onto general sentences of T n that are theorems of Tn. (P. Churchland, 1979, p. 81)

    22) The Inclusion of Non- linguistic Factors in a Theory of Grammar

   If non-linguistic factors must be included in grammar: beliefs, attitudes, etc. [this would] amount to a rejection of the initial idealization of language as an object of study. A priori such a move cannot be ruled out, but it must be empirically motivated. If it proves to be correct, I would conclude that language is a chaos that is not worth studying.... Note that the question is not whether beliefs or attitudes, and so on, play a role in linguistic behavior and linguistic judgments... [but rather] whether distinct cognitive structures can be identified, which interact in the real use of language and linguistic judgments, the grammatical system being one of these. (Chomsky, 1979, pp. 140, 152-153)

    23) Language Is Inevitably Influenced by Specific Contexts of Human Interaction

   Language cannot be studied in isolation from the investigation of "rationality." It cannot afford to neglect our everyday assumptions concerning the total behavior of a reasonable person.... An integrational linguistics must recognize that human beings inhabit a communicational space which is not neatly compartmentalized into language and nonlanguage.... It renounces in advance the possibility of setting up systems of forms and meanings which will "account for" a central core of linguistic behavior irrespective of the situation and communicational purposes involved. (Harris, 1981, p. 165)

    24) The Genetic Blueprints of Language

   By innate [linguistic knowledge], Chomsky simply means "genetically programmed." He does not literally think that children are born with language in their heads ready to be spoken. He merely claims that a "blueprint is there, which is brought into use when the child reaches a certain point in her general development. With the help of this blueprint, she analyzes the language she hears around her more readily than she would if she were totally unprepared for the strange gabbling sounds which emerge from human mouths. (Aitchison, 1987, p. 31)

    25) Languages Are Machines

   Looking at ourselves from the computer viewpoint, we cannot avoid seeing that natural language is our most important "programming language." This means that a vast portion of our knowledge and activity is, for us, best communicated and understood in our natural language.... One could say that natural language was our first great original artifact and, since, as we increasingly realize, languages are machines, so natural language, with our brains to run it, was our primal invention of the universal computer. One could say this except for the sneaking suspicion that language isn't something we invented but something we became, not something we constructed but something in which we created, and recreated, ourselves. (Leiber, 1991, p. 8)

Bell, Thomas

SUBJECT AREA: Paper and printing

[br]

fl. 1770–1785 Scotland

[br]

Scottish inventor of a calico printing machine with the design engraved on rollers.

[br]

In November 1770, John Mackenzie, owner of a bleaching mill, took his millwright Thomas Bell to Glasgow to consult with James Watt about problems they were having with the calico printing machine invented by Bell some years previously. Bell rolled sheets of copper one eighth of an inch (3 mm) thick into cyliders, and filled them with cement which was held in place by cast iron ends. After being turned true and polished, the cylinders were engraved; they cost about £10 each. The printing machines were driven by a water-wheel, but Bell and Mackenzie appeared to have had problems with the doctor blades which scraped off excess colour, and this may have been why they visited Watt.

They had, presumably, solved the technical problems when Bell took out a patent in 1783 which describes him as "the Elder", but there are no further details about the man himself. The machine is described as having six printing rollers arranged around the top of the circumference of a large central bowl. In later machines, the printing rollers were placed all round a smaller cylinder. All of the printing rollers, each printing a different colour, were driven by gearing to keep them in register. The patent includes steel doctor blades which would have scraped excess colour off the printing rollers. Another patent, taken out in 1784, shows a smaller three-colour machine. The printing rollers had an iron core covered with copper, which could be taken off at pleasure so that fresh patterns could be cut as desired. Bell's machine was used at Masney, near Preston, England, by Messrs Livesey, Hargreaves, Hall \& Co in 1786. Although copper cylinders were difficult to make and engrave, and the soldered seams often burst, these machines were able to increase the output of the cheaper types of printed cloth.

[br]

Bibliography

1783, patent no. 1,378 (calico printing machine with engraved copper rollers). 1784, patent no. 1,443 (three-colour calico printing machine).

Further Reading

W.E.A.Axon, 1886, Annals of Manchester, Manchester (provides an account of the invention).

R.L.Hills, 1970, Power in the Industrial Revolution, Manchester (provides a brief description of the development of calico printing).

RLH

Maxim, Sir Hiram Stevens

SUBJECT AREA: Aerospace, Weapons and armour

[br]

b. 5 February 1840 Brockway's Mills, Maine, USA

d. 24 November 1916 Streatham, London, England

[br]

American (naturalized British) inventor; designer of the first fully automatic machine gun and of an experimental steam-powered aircraft.

[br]

Maxim was born the son of a pioneer farmer who later became a wood turner. Young Maxim was first apprenticed to a carriage maker and then embarked on a succession of jobs before joining his uncle in his engineering firm in Massachusetts in 1864. As a young man he gained a reputation as a boxer, but it was his uncle who first identified and encouraged Hiram's latent talent for invention.

It was not, however, until 1878, when Maxim joined the first electric-light company to be established in the USA, as its Chief Engineer, that he began to make a name for himself. He developed an improved light filament and his electric pressure regulator not only won a prize at the first International Electrical Exhibition, held in Paris in 1881, but also resulted in his being made a Chevalier de la Légion d'honneur. While in Europe he was advised that weapons development was a more lucrative field than electricity; consequently, he moved to England and established a small laboratory at Hatton Garden, London. He began by investigating improvements to the Gatling gun in order to produce a weapon with a faster rate of fire and which was more accurate. In 1883, by adapting a Winchester carbine, he successfully produced a semi-automatic weapon, which used the recoil to cock the gun automatically after firing. The following year he took this concept a stage further and produced a fully automatic belt-fed weapon. The recoil drove barrel and breechblock to the vent. The barrel then halted, while the breechblock, now unlocked from the former, continued rearwards, extracting the spent case and recocking the firing mechanism. The return spring, which it had been compressing, then drove the breechblock forward again, chambering the next round, which had been fed from the belt, as it did so. Keeping the trigger pressed enabled the gun to continue firing until the belt was expended. The Maxim gun, as it became known, was adopted by almost every army within the decade, and was to remain in service for nearly fifty years. Maxim himself joined forces with the large British armaments firm of Vickers, and the Vickers machine gun, which served the British Army during two world wars, was merely a refined version of the Maxim gun.

Maxim's interests continued to occupy several fields of technology, including flight. In 1891 he took out a patent for a steam-powered aeroplane fitted with a pendulous gyroscopic stabilizer which would maintain the pitch of the aeroplane at any desired inclination (basically, a simple autopilot). Maxim decided to test the relationship between power, thrust and lift before moving on to stability and control. He designed a lightweight steam-engine which developed 180 hp (135 kW) and drove a propeller measuring 17 ft 10 in. (5.44 m) in diameter. He fitted two of these engines into his huge flying machine testrig, which needed a wing span of 104 ft (31.7 m) to generate enough lift to overcome a total weight of 4 tons. The machine was not designed for free flight, but ran on one set of rails with a second set to prevent it rising more than about 2 ft (61 cm). At Baldwyn's Park in Kent on 31 July 1894 the huge machine, carrying Maxim and his crew, reached a speed of 42 mph (67.6 km/h) and lifted off its rails. Unfortunately, one of the restraining axles broke and the machine was extensively damaged. Although it was subsequently repaired and further trials carried out, these experiments were very expensive. Maxim eventually abandoned the flying machine and did not develop his idea for a stabilizer, turning instead to other projects. At the age of almost 70 he returned to the problems of flight and designed a biplane with a petrol engine: it was built in 1910 but never left the ground.

In all, Maxim registered 122 US and 149 British patents on objects ranging from mousetraps to automatic spindles. Included among them was a 1901 patent for a foot-operated suction cleaner. In 1900 he became a British subject and he was knighted the following year. He remained a larger-than-life figure, both physically and in character, until the end of his life.

[br]

Principal Honours and Distinctions

Chevalier de la Légion d'Honneur 1881. Knighted 1901.

Bibliography

1908, Natural and Artificial Flight, London. 1915, My Life, London: Methuen (autobiography).

Further Reading

Obituary, 1916, Engineer (1 December).

Obituary, 1916, Engineering (1 December).

P.F.Mottelay, 1920, The Life and Work of Sir Hiram Maxim, London and New York: John Lane.

Dictionary of National Biography, 1912–1921, 1927, Oxford: Oxford University Press.

See also: Pilcher, Percy Sinclair

CM / JDS

Dawson, William

SUBJECT AREA: Textiles

[br]

b. mid-eighteenth century

d. c.1805 London, England

[br]

English inventor of the notched wheel for making patterns on early warp knitting machines.

[br]

William Dawson, a Leicester framework knitter, made an important addition to William Lee's knitting machine with his invention of the notched wheel in 1791. Lee's machine could make only plain knitting; to be able to knit patterns, there had to be some means of mechanically selecting and operating, independently of all the others, any individual thread, needle, lever or bar at work in the machine. This was partly achieved when Dawson devised a wheel that was irregularly notched on its edge and which, when rotated, pushed sprung bars, which in turn operated on the needles or other parts of the recently invented warp knitting machines. He seems to have first applied the idea for the knitting of military sashes, but then found it could be adapted to plait stay laces with great rapidity. With the financial assistance of two Leicester manufacturers and with his own good mechanical ability, Dawson found a way of cutting his wheels. However, the two financiers withdrew their support because he did not finish the design on time, although he was able to find a friend in a Nottingham architect, Mr Gregory, who helped him to obtain the patent. A number of his machines were set up in Nottingham but, like many other geniuses, he squandered his money away. When the patent expired, he asked Lord Chancellor Eldon to have it renewed: he moved his workshop to London, where Eldon inspected his machine, but the patent was not extended and in consequence Dawson committed suicide.

[br]

Bibliography

1791, British patent no. 1,820 (notched wheel for knitting machine).

Further Reading

W.Felkin, 1867, History of Machine-Wrought Hosiery and Lace Manufacture (covers Dawson's invention).

W.English, 1969, The Textile Industry, London (provides an outline history of the development of knitting machines).

RLH

Deverill, Hooton

SUBJECT AREA: Textiles

[br]

fl. c.1835 England

[br]

English patentee of the first successful adaptation of the Jacquard machine for patterned lacemaking.

[br]

After John Levers had brought out his lacemaking machine in 1813, other lacemakers proceeded to elaborate their machinery so as to imitate the more complicated forms of handwork. One of these was Samuel Draper of Nottingham, who took out one patent in 1835 for the use of a Jacquard mechanism on a lace making machine, followed by another in 1837. However, material made on his machine cost more than the handmade article, so the experiment was abandoned after three years. Then, in Nottingham in 1841, Hooton Deverill patented the first truly successful application of the Jacquard to lacemaking. The Jacquard needles caused the warp threads to be pushed sideways to form the holes in the lace while the bobbins were moved around them to bind them together. This made it possible to reproduce most of the traditional patterns of handmade lace in both narrow and wide pieces. Lace made on these machines became cheap enough for most people to be able to hang it in their windows as curtains, or to use it for trimming clothing. However, it raised in a most serious form the problem of patent rights between the two patentees, Deverill and Draper, threatening much litigation. Deverill's patent was bought by Richard Birkin, who with his partner Biddle relinquished the patent rights. The lacemaking trade on these machines was thus thrown open to the public and a new development of the trade took place. Levers lace is still made in the way described here.

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Bibliography

1841, British patent no. 8,955 (adaptation of Jacquard machine for patterned lacemaking).

Further Reading

W.Felkin, 1867, History of Machine-Wrought Hosiery and Lace Manufacture (provides an account of Deverill's patent).

C.Singer (ed.), 1958, A History of'Technology, Vol. V, Oxford: Clarendon Press (a modern account).

T.K.Derry and T.I.Williams, 1960, A Short History of Technology from the Earliest

Times to AD 1900, Oxford.

RLH

проходческий комбайн

borer, development machine, heading machine, tunneler, tunneling machine, road heading machine, roadheader

* * *

entry-driving machine

Bramah, Joseph

SUBJECT AREA: Civil engineering, Domestic appliances and interiors, Land transport, Mechanical, pneumatic and hydraulic engineering, Public utilities

[br]

b. 2 April 1749 Stainborough, Yorkshire, England

d. 9 December 1814 Pimlico, London, England

[br]

English inventor of the second patented water-closet, the beer-engine, the Bramah lock and, most important, the hydraulic press.

[br]

Bramah was the son of a tenant farmer and was educated at the village school before being apprenticed to a local carpenter, Thomas Allot. He walked to London c.1773 and found work with a Mr Allen that included the repair of some of the comparatively rare water-closets of the period. He invented and patented one of his own, which was followed by a water cock in 1783. His next invention, a greatly improved lock, involved the devising of a number of special machine tools, for it was one of the first devices involving interchangeable components in its manufacture. In this he had the help of Henry Maudslay, then a young and unknown engineer, who became Bramah's foreman before setting up business on his own. In 1784 he moved his premises from Denmark Street, St Giles, to 124 Piccadilly, which was later used as a showroom when he set up a factory in Pimlico. He invented an engine for putting out fires in 1785 and 1793, in effect a reciprocating rotary-vane pump. He undertook the refurbishment and modernization of Norwich waterworks c.1793, but fell out with Robert Mylne, who was acting as Consultant to the Norwich Corporation and had produced a remarkably vague specification. This was Bramah's only venture into the field of civil engineering.

In 1797 he acted as an expert witness for Hornblower \& Maberley in the patent infringement case brought against them by Boulton and Watt. Having been cut short by the judge, he published his proposed evidence in "Letter to the Rt Hon. Sir James Eyre, Lord Chief Justice of the Common Pleas…etc". In 1795 he was granted his most important patent, based on Pascal's Hydrostatic Paradox, for the hydraulic press which also incorporated the concept of hydraulics for the transmission of both power and motion and was the foundation of the whole subsequent hydraulic industry. There is no truth in the oft-repeated assertion originating from Samuel Smiles's Industrial Biography (1863) that the hydraulic press could not be made to work until Henry Maudslay invented the self-sealing neck leather. Bramah used a single-acting upstroking ram, sealed only at its base with a U-leather. There was no need for a neck leather.

He also used the concept of the weight-loaded, in this case as a public-house beer-engine. He devised machinery for carbonating soda water. The first banknote-numbering machine was of his design and was bought by the Bank of England. His development of a machine to cut twelve nibs from one goose quill started a patent specification which ended with the invention of the fountain pen, patented in 1809. His coach brakes were an innovation that was followed bv a form of hydropneumatic carriage suspension that was somewhat in advance of its time, as was his patent of 1812. This foresaw the introduction of hydraulic power mains in major cities and included the telescopic ram and the air-loaded accumulator.

In all Joseph Bramah was granted eighteen patents. On 22 March 1813 he demonstrated a hydraulic machine for pulling up trees by the roots in Hyde Park before a large crowd headed by the Duke of York. Using the same machine in Alice Holt Forest in Hampshire to fell timber for ships for the Navy, he caught a chill and died soon after at his home in Pimlico.

[br]

Bibliography

1778, British patent no. 1177 (water-closet). 1784, British patent no. 1430 (Bramah Lock). 1795, British patent no. 2045 (hydraulic press). 1809, British patent no. 3260 (fountain pen). 1812, British patent no. 3611.

Further Reading

I.McNeil, 1968, Joseph Bramah, a Century of Invention.

S.Smiles, 1863, Industrial Biography.

H.W.Dickinson, 1942, "Joseph Bramah and his inventions", Transactions of the Newcomen Society 22:169–86.

IMcN

Heald, James Nichols

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

[br]

b. 21 September 1864 Barre, Massachusetts, USA

d. 7 May 1931 Worcester, Massachusetts, USA

[br]

American mechanical engineer and machine-tool manufacturer who concentrated on grinding machines.

[br]

James N.Heald was the son of Leander S.Heald and was educated at the Worcester Polytechnic Institute, graduating with the degree of Bachelor of Science in 1884. He then joined the firm that had been established by his grandfather, Stephen Heald, in 1826; this was a machine shop and foundry then known as S.Heald \& Son. When his grandfather died in 1888, James Heald took over the management of the business, which then became known as L.S.Heald \& Son. He concentrated on the manufacture of grinding machines and in 1903 bought out his father's interest and organized the Heald Machine Company. James Heald then began the development of a series of grinding machines designed to meet the needs of the expanding automobile industry. Special machines were produced for grinding piston rings making use of the recently invented magnetic chuck, and for cylinder bores he introduced the planetary grinder. Heald was a member of the National Machine Tool Builders' Association and served as its Treasurer and on its Board of Directors. He was elected a member of the American Society of Mechanical Engineers in 1917 and was also a member of the Society of Automotive Engineers.

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Further Reading

Robert S.Woodbury, 1959, History of the Grinding Machine, Cambridge, Mass (describes his grinding machines).

L.T.C.Rolt, 1965, Tools for the Job, London; repub. 1986 (describes his grinding machines).

RTS

Maudslay, Henry

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

[br]

b. 22 August 1771 Woolwich, Kent, England

d. 15 February 1831 Lambeth, London, England

[br]

English precision toolmaker and engineer.

[br]

Henry Maudslay was the third son of an ex-soldier and storekeeper at Woolwich Arsenal. At the age of 12 he was employed at the Arsenal filling cartridges; two years later he was transferred to the woodworking department, adjacent to the smithy, to which he moved when 15 years old. He was a rapid learner, and three years later Joseph Bramah took him on for the construction of special tools required for the mass-production of his locks. Maudslay was thus employed for the next eight years. He became Bramah's foreman, married his housekeeper, Sarah Tindale, and, unable to better himself, decided to leave and set up on his own. He soon outgrew his first premises in Wells Street and moved to Margaret Street, off Oxford Street, where some examples of his workmanship were displayed in the window. These caught the attention of a visiting Frenchman, de Bacquancourt; he was a friend of Marc Isambard Brunel, who was then in the early stages of designing the block-making machinery later installed at Portsmouth dockyard.

Brunel wanted first a set of working models, as he did not think that the Lords of the Admiralty would be capable of understanding engineering drawings; Maudslay made these for him within the next two years. Sir Samuel Bentham, Inspector-General of Naval Works, agreed that Brunel's system was superior to the one that he had gone some way in developing; the Admiralty approved, and an order was placed for the complete plant. The manufacture of the machinery occupied Maudslay for the next six years; he was assisted by a draughtsman whom he took on from Portsmouth dockyard, Joshua Field (1786–1863), who became his partner in Maudslay, Son and Field. There were as many as eighty employees at Margaret Street until, in 1810, larger premises became necessary and a new works was built at Lambeth Marsh where, eventually, there were up to two hundred workers. The new factory was flanked by two houses, one of which was occupied by Maudslay, the other by Field. The firm became noted for its production of marine steam-engines, notably Maudslay's table engine which was first introduced in 1807.

Maudslay was a consummate craftsman who was never happier than when working at his bench or at a machine tool; he was also one of the first engineers to appreciate the virtues of standardization. Evidence of this appreciation is to be found in his work in the development of the Bramah lock and then on the machine tools for the manufacture of ship's blocks to Marc Brunel's designs; possibly his most important contribution was the invention in 1797 of the metal lathe. He made a number of surface plates of the finest quality. The most celebrated of his numerous measuring devices was a micrometer-based machine which he termed his "Lord Chancellor" because, in the machine shop, it represented the "final court of appeal", measuring to one-thousandth of an inch.

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Further Reading

1934–5, "Maudslay, Sons \& Field as general engineers", Transactions of the Newcomen Society 15, London.

1963, Engineering Heritage, Vol. 1, London: Institution of Mechanical Engineers. L.T.C.Rolt, 1965, Tools for the Job, London: Batsford.

W.Steeds, 1969, A History of Machine Tools 1700–1910, Oxford: Oxford University Press.

IMcN

Moore, Hiram

SUBJECT AREA: Agricultural and food technology

[br]

b. 19 July 1801 New England, USA

d. c. 1874 Wisconsin, USA

[br]

American farmer and inventor who developed the first combine harvester.

[br]

Hiram Moore was the son of a New England stonemason. In 1831 he moved to West Michigan to farm, and he and his two brothers settled in Climax in Kalamazoo County.

Stimulated by a conversation with his neighbour, John Hascall, Moore made a model harvesting machine, which he patented in 1834. By the following year he had built a full-scale machine, but it broke down very quickly. In 1835 he successfully harvested 3 acres left standing for the purpose. Each year alterations and additions were made to the machine, and by 1839 over 50 acres were successfully harvested and threshed in the one operation by the Moore-Hascall machine.

During further developments which took place in the 1840s, Moore sold much of his interest to Senator Lucius Lyon. By the late 1840s this source of funding was no longer available, and attempts to extend the patent became embroiled in similar attempts by McCormick and Hussey and were blocked by rural pressures stemming from the fear that high machinery prices would ensue if the patents continued.

Discouraged, Moore moved to Brandon, Wisconsin, where he farmed 600 acres. He was still developing various machines, but was no longer actively involved in the development of the combine harvester. He continued to work his own machine, with which he would cut just a few acres each year.

[br]

Further Reading

Graeme Quick and Wesley Buchele, 1978, The Grain Harvesters, American Society of Agricultural Engineers (describes Hiram Moore's achievements in detail).

AP

Sauerbrun, Charles de, Baron von Drais

SUBJECT AREA: Land transport

[br]

b. 1785

d. 1851

[br]

German popularizer of the first form of manumotive vehicle, the hobby-horse.

[br]

An engineer and agriculturalist who had to travel long distances over rough country, he evolved an improved design of velocipede. The original device appears to have been first shown in the gardens of the Palais Royal by the comte de Sivrac in 1791, a small wooden "horse" fitted with two wheels and propelled by the rider's legs thrusting alternately against the ground. It was not possible to turn the front wheel to steer the machine, a small variation from the straight being obtained by the rider leaning sideways. It is not known if de Sivrac was the inventor of the machine: it is likely that it had been in existence, probably as a child's toy, for a number of years. Its original name was the celerifière, but it was renamed the velocifère in 1793. The Baron's Draisienne was an improvement on this primitive machine; it had a triangulated wooden frame, an upholstered seat, a rear luggage seat and an armrest which took the thrust of the rider as he or she pushed against the ground. Furthermore, it was steerable. In some models there was a cordoperated brake and a prop stand, and the seat height could be adjusted. At least one machine was fitted with a milometer. Drais began limited manufacture and launched a long marketing and patenting campaign, part of which involved sending advertising letters to leading figures, including a number of kings.

The Draisienne was first shown in public in April 1817: a ladies' version became available in 1819. Von Drais took out a patent in Baden on 12 January 1818 and followed with a French patent on 17 February. Three-and four-wheeled versions became available so the two men could take the ladies for a jaunt.

Drais left his agricultural and forestry work and devoted his full time to the "Running Machine" business. Soon copies were being made and sold in Italy, Germany and Austria. In London, a Denis Johnson took out a patent in December 1818 for a "pedestrian curricle" which was soon nicknamed the dandy horse.

[br]

Further Reading

C.A.Caunter, 1955, Cycles: History and Development, London: Science Museum and HMSO.

IMcN

опытный образец

1) General subject: development type, developmental prototype

2) Naval: experimental prototype

3) Military: Y (ЛА), development prototype, pilot item, testbed (англ. термин взят из репортажа агентства Thomson Reuters; контекстуальный перевод)

4) Engineering: engineering sample, experimental model, pilot model, preproduction model, prototype, prototype machine, prototype model, prototype preproduction model, prototype unit, test sample

5) Agriculture: check sample, control sample, proof sample

6) Economy: first article, pilot sample, test pattern

7) Accounting: prototype model (напр. машины)

8) Automobile industry: trial model

9) Electronics: test model

10) Information technology: trial design

11) Oil: test piece, test specimen

12) Astronautics: functional equipment, predictable pattern

13) Advertising: pilot sample (изделия)

14) Business: certificate model

15) EBRD: industrial prototype

16) Automation: R and D model, engineering prototype, preproduction prototype, production prototype, prototype sample

17) Quality control: pilot( run) item

18) Chemical weapons: test prototype

19) Makarov: machine (первое спроектированное изделие в металле), part (первое спроектированное изделие в металле), prototype (первое спроектированное изделие в металле)