designed depth

designed depth

1. расчётная глубина

 

расчётная глубина
—
[ http://slovarionline.ru/anglo_russkiy_slovar_neftegazovoy_promyishlennosti/]

Тематики

• нефтегазовая промышленность

EN

• designed depth
• rated depth

designed depth

расчетная глубина

designed depth

расчётная глубина

* * *

расчетная глубина

designed depth

Нефть: расчётная глубина

depth

1. глубина

2. геол. мощность ( пласта)

3. густота ( цвета)

maximum depth of seismic rays — максимальная глубина проникновения сейсмических лучей

plugged back total depth — глубина скважины после установки моста

— budgeted depth

— casing cemented depth

— casing depth

— casing setting depth

— contract depth

— depth of case

— depth of freezing

— depth of penetration

— depth of plunger

— depth of setting

— depth of thread

— design water depth

— diver depth

— drilled out depth

— drilling total depth

— geothermic depth

— hole depth

— landing depth

— log total depth

— measured total depth

— new total depth

— old plug-back depth

— old total depth

— operating water depth

— platform depth

— plugged back depth

— producing depth

— proposed depth

— selected depth

— true depth

— true vertical depth

— tubing depth

— weathering depths

— well depth

— whipstock depth

— wireline total depth

* * *

глубина

operating w.'ter depth — рабочая глубина воды (для морского бурения)

well total vertical depth — конечная глубина скважины по вертикали

— drilling depth

— hole depth

— producing depth

— reservoir depth

— setting depth

— target well depth

— well contract depth

— well total depth

* * *

глубина; мощность, толщина ( пласта); густота ( цвета)

* * *

1) глубина

2) высота борта ( судна)

3) геол. мощность, толщина ( пласта)

•

from spud-in to total depth — от устья до конечной глубины;

depth in — глубина, на которую было опущено новое долото;

depth out — глубина ствола скважины, до которой проработало долото ( до извлечения);

to determine depth — измерять глубину;

to measure depth — измерять глубину

- depth of burial

- depth of case
- depth of cement case
- depth of cover
- depth of diamond-bearing layer
- depth of invasion
- depth of investigation
- depth of penetration
- depth of pile setting
- depth of pipeline
- depth of plunger
- actual drilling depth
- actual filling depth
- authorized depth
- average depth
- average well depth
- basement depth
- bottomhole depth
- budgeted depth
- cable depth
- case depth
- casing depth
- casing cemented depth
- casing liner hanger setting depth
- casing setting depth
- contract depth
- corrected depth
- crack depth
- design water depth
- designed depth
- drawworks brake drum flange depth
- drilled-out depth
- drillhole depth
- drilling depth
- drilling total depth
- estimated depth
- filling depth
- filtrate ingress depth
- fishing depth
- foundation depth
- geophone depth
- hole depth
- immersion depth
- insert depth
- invasion depth
- kerf depth
- landing depth
- log total depth
- logging depth
- maximum depth of seismic rays
- maximum drilling depth
- measured depth
- measured drilling depth
- measured total depth
- migrated depth
- new total depth
- occurrence depth
- oil plug-back depth
- old total depth
- operating water depth
- overall depth
- overburden depth
- packer setting depth
- penetration depth
- pipeline laying depth
- pipeline trench depth
- pit depth
- planned drilling depth
- platform depth
- plugged back depth
- plugged back total depth
- pool depth
- predetermined well depth
- predicted depth
- preestablished depth
- producing depth
- project drilling depth
- proposed depth
- pulling depth of drill pipe
- pump running depth
- pump setting depth
- rated depth
- reflection depth
- reflector depth
- refraction depth
- refractor depth
- reservoir depth
- running depth
- sampling depth
- seismic-deducted depth
- seismometer depth
- selected depth
- setting depth
- shot depth
- shothole depth
- shot-point depth
- sidetracked total depth
- source depth
- stratigraphic depth
- streamer depth
- tanker depth
- target well depth
- test depth
- time depth
- tooth depth
- total depth
- true depth
- true vertical well depth
- tubing depth
- tubing running depth
- tubing setting depth
- ultimate pump running depth
- ultimate pump setting depth
- unmigrated depth
- weathering depth
- well depth
- well contract depth
- well total depth
- well total vertical depth
- whipstock depth
- wireline total depth
- working depth

* * *

• высота

• высота борта

rated depth

1. расчётная глубина

 

расчётная глубина
—
[ http://slovarionline.ru/anglo_russkiy_slovar_neftegazovoy_promyishlennosti/]

Тематики

• нефтегазовая промышленность

EN

• designed depth
• rated depth

расчётная глубина

designed depth, rated depth

charted

a отмеченный на карте, нанесённый на карту

charted position — место, нанесённое на карту

charted post — место корабля по карте

charted depth — глубина моря от нуля карты

charted a course — проложил на карте маршрут

Синонимический ряд:

1. summarized (adj.) diagramed; epitomized; generalized; graphed; mapped; outlined; summarized

2. mapped (verb) lay out; mapped; plotted

3. planned (verb) arranged; blueprinted; cast; contrived; designed; devised; draw up; framed; planned; projected

executive coaching

HR

regular one-to-one coaching for leaders, designed as part of a management development program to provide knowledge and skills in a particular area. Executive coaching involves giving feedback to a leader and assisting in the creation of a development plan, often using 360 degree appraisal. It can include in-depth development coaching conducted by colleagues, superiors, or specialist trainers, lasting perhaps six to twelve months.

Davis, Robert Henry

SUBJECT AREA: Ports and shipping

[br]

b. 6 June 1870 London, England

d. 29 March 1965 Epsom, Surrey, England

[br]

English inventor of breathing, diving and escape apparatus.

[br]

Davis was the son of a detective with the City of London police. At the age of 11 he entered the employment of Siebe, Gorman \& Co., manufacturers of diving and other safety equipment since 1819, at their Lambeth works. By good fortune, his neat handwriting attracted the notice of Mr Gorman and he was transferred to work in the office. He studied hard after working hours and rose steadily in the firm. In his twenties he was promoted to Assistant Manager, then General Manager, Managing Director and finally Governing Director. He retired in 1960, having been made Life President the previous year, and continued to attend the office regularly until May 1964.

Davis's entire career was devoted to research and development in the firm's special field. In 1906 he perfected the first practicable oxygen-breathing apparatus for use in mine rescue; it was widely adopted and with modifications was still in use in the 1990s. With Professor Leonard Hill he designed a deep-sea diving-bell incorporating a decompression chamber. He also invented an oxygen-breathing apparatus and heated apparel for airmen flying at high altitudes.

Immediately after the first German gas attacks on the Western Front in April 1915, Davis devised a respirator, known as the stocking skene or veil mask. He quickly organized the mass manufacture of this device, roping in members of his family and placing the work in the homes of Lambeth: within 48 hours the first consignment was being sent off to France.

He was a member of the Admiralty Deep Sea Diving Committee, which in 1933 completed tables for the safe ascent of divers with oxygen from a depth of 300 ft (91 m). They were compiled by Davis in conjunction with Professors J.B.S.Haldane and Leonard Hill and Captain G.C.Damant, the Royal Navy's leading diving expert. With revisions these tables have been used by the Navy ever since. Davis's best-known invention was first used in 1929: the Davis Submarine Escape Apparatus. It became standard equipment on submarines until it was replaced by the Built-in Breathing System, which the firm began manufacturing in 1951.

The firm's works were bombed during the Second World War and were re-established at Chessington, Surrey. The extensive research facilities there were placed at the disposal of the Royal Navy and the Admiralty Experimental Diving Unit. Davis worked with Haldane and Hill on problems of the underwater physiology of working divers. A number of inventions issued from Chessington, such as the human torpedo, midget submarine and human minesweeper. In the early 1950s the firm helped to pioneer the use of underwater television to investigate the sinking of the submarine Affray and the crashed Comet jet airliners.

[br]

Principal Honours and Distinctions

Knighted 1932.

Bibliography

Davis was the author of several manuals on diving including Deep Sea Diving and Submarine Operations and Breathing in Irrespirable Atmospheres. He also wrote Resuscitation: A Brief Personal History of Siebe, Gorman \& Co. 1819–1957.

Further Reading

Obituary, 1965, The Times, 31 March, p. 16.

LRD

Fowler, John

SUBJECT AREA: Civil engineering

[br]

b. 11 July 1826 Melksham, Wiltshire, England

d. 4 December 1864 Ackworth, Yorkshire, England

[br]

English engineer and inventor who developed a steam-powered system of mole land drainage, and a two-engined system of land cultivation, founding the Steam Plough Works in Leeds.

[br]

The son of a Quaker merchant, John Fowler entered the business of a county corn merchant on leaving school, but he found this dull and left as soon as he came of age, joining the Middlesbrough company of Gilkes, Wilson \& Hopkins, railway locomotive manufacturers. In 1849, at the age of 23, Fowler visited Ireland and was so distressed by the state of Irish agriculture that he determined to develop a system to deal with the drainage of land. He designed an implement which he patented in 1850 after a period of experimentation. It was able to lay wooden pipes to a depth of two feet, and was awarded the Silver Medal at the 1850 Royal Agriculture Show. By 1854, using a steam engine made by Clayton \& Shuttleworth, he had applied steam power to his invention and gained another award that year at the Royal Show. The following year he turned his attention to steam ploughing. He first developed a single-engined system that used a double windlass with which to haul a plough backwards and forwards across fields. In 1856 he patented his balance plough, and the following year he read a paper to the Institution of Mechanical Engineers at their Birmingham premises, describing the system. In 1858 he won the Royal Agricultural Society award with a plough built for him by Ransomes. Fowler founded the Steam Plough Works in Leeds and in 1862 production began in partnership with William Watson Hewitson. Within two years they were producing the first of a series of engines which were to make the name Fowler known worldwide. John Fowler saw little of his success because he died in 1864 at his Yorkshire home as a result of tetanus contracted after a riding accident.

[br]

Further Reading

M.Lane, 1980, The Story of the Steam Plough Works, Northgate Publishing (provides biographical details of John Fowler, but is mostly concerned with the company that he founded).

AP

Whitehead, Robert

SUBJECT AREA: Weapons and armour

[br]

b. 3 January 1823 Bolton-le-Moors, Lancashire, England

d. 19 November 1903 Shrivenham, Wiltshire, England

[br]

English inventor of the torpedo.

[br]

At the age of 14 Whitehead was apprenticed by his father, who ran a cotton-bleaching business, to an engineering firm in Manchester. He moved in 1847 to join his uncle, who was the Manager of another engineering firm, and three years later Whitehead set up on his own in Milan, where he made mechanical improvements to the silk-weaving industry and designed drainage machines for the Lombardy marshes.

In 1848 he was forced to move from Italy because of the revolution and settled in Fiume, which was then part of Austria. There he concen-. trated on designing and building engines for warships, and in 1864 the Austrians invited him to participate in a project to develop a "floating torpedo". In those days the torpedo was synonymous with the underwater mine, and Whitehead believed that he could do better than this proposal and produce an explosive weapon that could propel itself through the water. He set to work with his son John and a mechanic, producing the first version of his torpedo in 1866. It had a range of only 700 yd (640 m) and a speed of just 7 knots (13 km/h), as well as depth-keeping problems, but even so, especially after he had reduced the last problem by the use of a "balance chamber", the Austrian authorities were sufficiently impressed to buy construction rights and to decorate him. Other navies quickly followed suit and within twenty years almost every navy in the world was equipped with the Whitehead torpedo, its main attraction being that no warship, however large, was safe from it. During this time Whitehead continued to improve on his design, introducing a servo-motor and gyroscope, thereby radically improving range, speed and accuracy.

[br]

Principal Honours and Distinctions

Order of Max Joseph (Austria) 1868. Légion d'honneur 1884. Whitehead also received decorations from Prussia, Denmark, Portugal, Italy and Greece.

Further Reading

Dictionary of National Biography, 1912, Vol. 3, Suppl. 2, London: Smith, Elder.

CM

electrical characteristics of assemblies

1. электрические характеристики НКУ

 

электрические характеристики НКУ
-
[Интент]

Параллельные тексты EN-RU

The Standard IEC 60439-1 identifies the nominal characteristics to be assigned to each assembly, defines the environmental service conditions, establishes the mechanical requirements and gives prescriptions about:
• insulation
• thermal behaviour
• short-circuit withstand strength
• protection against electrical shock
• degree of protection of the enclosure
• installed components, internal separation and connections inside the assembly
• electronic equipment supply circuits.

Information specified under items a) and b) shall be given on the nameplate according to the Standard.
Information from items c) to t), where applicable, shall be given either on the nameplates or in the technical documentation of the manufacturer:
a) manufacturer ’s name or trade mark;
b) type designation or identification number, or any other means of identification making it possible to obtain relevant information from the manufacturer;
c) IEC 60439-1;
d) type of current (and frequency, in the case of a.c.);
e) rated operational voltages;
f) rated insulation voltages (rated impulse withstand voltage, when declared by the manufacturer);
g) rated voltages of auxiliary circuits, if applicable;
h) limits of operation;
j) rated current of each circuit, if applicable;
k) short-circuit withstand strength;
l) degree of protection;
m) measures for protection of persons;
n) service conditions for indoor use, outdoor use or special use, if different from the usual service conditions.
Pollution degree when declared by the manufacturer;
o) types of system earthing (neutral conductor) for which the ASSEMBLY is designed;
p) dimensions given preferably in the order of height, width (or length), depth;
q) weight;
r) form of internal separation;
s) types of electrical connections of functional units;
t) environment 1 or 2.

[ABB]

Стандарт МЭК 60439-1 определяет номинальные характеристики НКУ, условия эксплуатации, требования к механической части конструкции, а также следующие параметры:
• изоляция;
• превышение температуры;
• прочность к воздействию тока короткого замыкания;
• защита от поражения электрическим током;
• степень защиты, обеспечиваемая оболочкой;
• комплектующие элементы, внутреннее разделение НКУ ограждениями и перегородками, электрические соединения внутри НКУ;
• требования к цепям питания электронного оборудования.

Информация, относящаяся к пунктам а) и b), должна быть указана на паспортной табличке, соответствующей данному стандарту.
Информация, приведенная в пунктах с) … d), должна быть указана либо на паспортной табличке, либо в технической документации изготовителя:
a) наименование изготовителя или товарный знак;
b) обозначение типа, условного номера или другого знака, позволяющих получить необходимую информацию от изготовителя;
c) МЭК 60439-1;
d) род тока (а для переменно тока и частота.);
e) номинальные рабочие напряжения;
f) номинальное напряжение изоляции (или указываемое изготовителем номинальное импульсное выдерживаемое напряжение);
g) номинальное напряжение вспомогательных цепей, если таковые имеются;
h) предельные отклонения параметров;
j) номинальный ток каждой цепи, если таковые приводят;
k) прочность к воздействию короткого замыкания;
l) степень защиты;
m) меры защиты персонала;
n) нормальные условия эксплуатации при внутренней или наружной установке, а также специальные условия эксплуатации, если они отличаются от нормальных.
Степень загрязнения, если она указывается изготовителем;
o) вид системы заземления (режим нейтрали), который был принят при проектировании НКУ;
p) размеры, приводимые в следующей последовательности: высота, ширина (или длина), глубина;
q) масса;
r) вид внутреннего разделения;
s) типы электрических соединений функциональных блоков;
t) окружающая среда 1 или 2.

[Перевод Интент]

Тематики

• НКУ (шкафы, пульты,...)

EN

• electrical characteristics of assemblies