are tabulated in

представленный

represented, outlined

• В представленном здесь обсуждении у нас имеется... - In the discussion presented here we have...

• Они представлены в таблице 1. -They are tabulated in Table 1; They are represented in Table 1.

• Очевидно, что эти эффекты не могут быть представлены как... - These effects obviously cannot be represented as...

• Очень хорошо написанное сообщение было представлено Смитом [1]. - A very readable account has been given by Smith [1].

• Представленное здесь рассмотрение было чисто формальным. - The treatment given here has been purely formal.

• Рассуждениями, которые полностью аналогичны представленным в предыдущей главе, мы приходим к заключению, что... - By arguments that are completely analogous to those presented in the previous chapter we conclude that...

• Результат, представленный формулой (9), очень полезен при выводе свойств... - The result (9) is very useful for deducing properties of...

• Эти результаты представлены на рис. 3 и 4. - The results are displayed in Figures 3 and 4.

• Это ясно представлено на данном рисунке. - This is clearly brought out in the figure.

сводить в таблицу

•

The data are accumulated in Table 6-5...

•

The results are summarized in the table.

•

Properties of these alloys are tabulated below.

приводит в таблице

Приводит(ся) в таблице

 Some of the typical small power loss variations at 2.07 MPa are listed in Table.

 Numerical values of the scaling parameters q(0) and f(Ґ) are tabulated in Table.

 The specimen irradiation parameters are detailed in Table.

 The overall performance is also summarized in Table.

приводиться в таблице

•

Included (or Given) in Table I is the calculated product of...

•

In Table I are listed the major calcium minerals and their formulas.

•

Some of the important properties of beryllium are tabulated (or given, or displayed) in Table I.

представлен в таблице

•

The results of exposing silicon, germanium... rectifiers to radiation hazards are tabulated in Table V.

для удобства читателей

Для удобства читателей-- The discharge enthalpies are tabulated for the readers convenience in Table.

нормирующий параметр

Нормирующий параметр-- Numerical values of the scaling parameters q0 and fҐ are tabulated in Table.

длительный допустимый ток

1. Strombelastbarkeit, f
2. Dauerstrombelastbarkeit, f

 

(длительный) допустимый ток
Максимальное значение электрического тока, который может протекать длительно по проводнику, устройству или аппарату при определенных условиях без превышения определенного значения их температуры в установившемся режиме
[ ГОСТ Р МЭК 60050-826-2009]

Этот ток обозначают I_Z
[ ГОСТ Р 50571. 1-2009 ( МЭК 60364-1: 2005)]

EN

(continuous) current-carrying capacity
ampacity (US)
maximum value of electric current which can be carried continuously by a conductor, a device or an apparatus, under specified conditions without its steady-state temperature exceeding a specified value
[IEV number 826-11-13]

ampacity
The current in amperes that a conductor can carry continuously under the conditions of use without exceeding its temperature rating.
[National Electrical Cod]

FR

courant (permanent) admissible, m
valeur maximale du courant électrique qui peut parcourir en permanence, un conducteur, un dispositif ou un appareil, sans que sa température de régime permanent, dans des conditions données, soit supérieure à la valeur spécifiée
[IEV number 826-11-13]

Ampacity, the term is defined as the maximum amount of current a cable can carry before sustaining immediate or progressive deterioration. Also described as current rating or current-carrying capacity, is the RMS electric current which a device can continuously carry while remaining within its temperature rating. The ampacity of a cable depends on:

• its insulation temperature rating;
• conductor electrical properties for current;
• frequency, in the case of alternating currents;
• ability to dissipate heat, which depends on cable geometry and its surroundings;
• ambient temperature.

Electric wires have some resistance, and electric current flowing through them causes voltage drop and power dissipation, which heats the cable. Copper or aluminum can conduct a large amount of current before melting, but long before the conductors melt, their insulation would be damaged by the heat.

The ampacity for a power cable is thus based on physical and electrical properties of the material & construction of the conductor and of its insulation, ambient temperature, and environmental conditions adjacent to the cable. Having a large overall surface area may dissipate heat well if the environment can absorb the heat.

In a long run of cable, different conditions govern, and installation regulations normally specify that the most severe condition along the run governs the cable's rating. Cables run in wet or oily locations may carry a lower temperature rating than in a dry installation. Derating is necessary for multiple circuits in close proximity. When multiple cables are near, each contributes heat to the others and diminishes the amount of cooling air that can flow past the individual cables. The overall ampacity of the insulated conductors in a bundle of more than 3 must be derated, whether in a raceway or cable. Usually the de-rating factor is tabulated in a nation's wiring regulations.

Depending on the type of insulating material, common maximum allowable temperatures at the surface of the conductor are 60, 75 and 90 degrees Celsius, often with an ambient air temperature of 30°C. In the U.S., 105°C is allowed with ambient of 40°C, for larger power cables, especially those operating at more than 2 kV. Likewise, specific insulations are rated 150, 200 or 250°C.

The allowed current in cables generally needs to be decreased (derated) when the cable is covered with fireproofing material.

For example, the United States National Electric Code, Table 310-16, specifies that up to three 8 AWG copper wires having a common insulating material (THWN) in a raceway, cable, or direct burial has an ampacity of 50 A when the ambient air is 30°C, the conductor surface temperature allowed to be 75°C. A single insulated conductor in air has 70 A rating.

Ampacity rating is normally for continuous current, and short periods of overcurrent occur without harm in most cabling systems. The acceptable magnitude and duration of overcurrent is a more complex topic than ampacity.

When designing an electrical system, one will normally need to know the current rating for the following:

• Wires
• Printed Circuit Board traces, where included
• Fuses
• Circuit breakers
• All or nearly all components used

Some devices are limited by power rating, and when this power rating occurs below their current limit, it is not necessary to know the current limit to design a system. A common example of this is lightbulb holders.

[http://en.wikipedia.org/wiki/Ampacity]

Тематики

• электротехника, основные понятия

Синонимы

• длительно допустимый ток
• допустимый ток

EN

• ampacity (US)
• continuous current
• continuous current-carrying capacity
• current-carrying capacity

DE

• Dauerstrombelastbarkeit, f
• Strombelastbarkeit, f

FR

• courant admissible, m
• courant permanent admissible, m

длительный допустимый ток

1. current-carrying capacity
2. continuous current-carrying capacity
3. continuous current
4. ampacity (US)

 

(длительный) допустимый ток
Максимальное значение электрического тока, который может протекать длительно по проводнику, устройству или аппарату при определенных условиях без превышения определенного значения их температуры в установившемся режиме
[ ГОСТ Р МЭК 60050-826-2009]

Этот ток обозначают I_Z
[ ГОСТ Р 50571. 1-2009 ( МЭК 60364-1: 2005)]

EN

(continuous) current-carrying capacity
ampacity (US)
maximum value of electric current which can be carried continuously by a conductor, a device or an apparatus, under specified conditions without its steady-state temperature exceeding a specified value
[IEV number 826-11-13]

ampacity
The current in amperes that a conductor can carry continuously under the conditions of use without exceeding its temperature rating.
[National Electrical Cod]

FR

courant (permanent) admissible, m
valeur maximale du courant électrique qui peut parcourir en permanence, un conducteur, un dispositif ou un appareil, sans que sa température de régime permanent, dans des conditions données, soit supérieure à la valeur spécifiée
[IEV number 826-11-13]

Ampacity, the term is defined as the maximum amount of current a cable can carry before sustaining immediate or progressive deterioration. Also described as current rating or current-carrying capacity, is the RMS electric current which a device can continuously carry while remaining within its temperature rating. The ampacity of a cable depends on:

• its insulation temperature rating;
• conductor electrical properties for current;
• frequency, in the case of alternating currents;
• ability to dissipate heat, which depends on cable geometry and its surroundings;
• ambient temperature.

Electric wires have some resistance, and electric current flowing through them causes voltage drop and power dissipation, which heats the cable. Copper or aluminum can conduct a large amount of current before melting, but long before the conductors melt, their insulation would be damaged by the heat.

The ampacity for a power cable is thus based on physical and electrical properties of the material & construction of the conductor and of its insulation, ambient temperature, and environmental conditions adjacent to the cable. Having a large overall surface area may dissipate heat well if the environment can absorb the heat.

In a long run of cable, different conditions govern, and installation regulations normally specify that the most severe condition along the run governs the cable's rating. Cables run in wet or oily locations may carry a lower temperature rating than in a dry installation. Derating is necessary for multiple circuits in close proximity. When multiple cables are near, each contributes heat to the others and diminishes the amount of cooling air that can flow past the individual cables. The overall ampacity of the insulated conductors in a bundle of more than 3 must be derated, whether in a raceway or cable. Usually the de-rating factor is tabulated in a nation's wiring regulations.

Depending on the type of insulating material, common maximum allowable temperatures at the surface of the conductor are 60, 75 and 90 degrees Celsius, often with an ambient air temperature of 30°C. In the U.S., 105°C is allowed with ambient of 40°C, for larger power cables, especially those operating at more than 2 kV. Likewise, specific insulations are rated 150, 200 or 250°C.

The allowed current in cables generally needs to be decreased (derated) when the cable is covered with fireproofing material.

For example, the United States National Electric Code, Table 310-16, specifies that up to three 8 AWG copper wires having a common insulating material (THWN) in a raceway, cable, or direct burial has an ampacity of 50 A when the ambient air is 30°C, the conductor surface temperature allowed to be 75°C. A single insulated conductor in air has 70 A rating.

Ampacity rating is normally for continuous current, and short periods of overcurrent occur without harm in most cabling systems. The acceptable magnitude and duration of overcurrent is a more complex topic than ampacity.

When designing an electrical system, one will normally need to know the current rating for the following:

• Wires
• Printed Circuit Board traces, where included
• Fuses
• Circuit breakers
• All or nearly all components used

Some devices are limited by power rating, and when this power rating occurs below their current limit, it is not necessary to know the current limit to design a system. A common example of this is lightbulb holders.

[http://en.wikipedia.org/wiki/Ampacity]

Тематики

• электротехника, основные понятия

Синонимы

• длительно допустимый ток
• допустимый ток

EN

• ampacity (US)
• continuous current
• continuous current-carrying capacity
• current-carrying capacity

DE

• Dauerstrombelastbarkeit, f
• Strombelastbarkeit, f

FR

• courant admissible, m
• courant permanent admissible, m

длительный допустимый ток

1. courant permanent admissible, m
2. courant admissible, m

 

(длительный) допустимый ток
Максимальное значение электрического тока, который может протекать длительно по проводнику, устройству или аппарату при определенных условиях без превышения определенного значения их температуры в установившемся режиме
[ ГОСТ Р МЭК 60050-826-2009]

Этот ток обозначают I_Z
[ ГОСТ Р 50571. 1-2009 ( МЭК 60364-1: 2005)]

EN

(continuous) current-carrying capacity
ampacity (US)
maximum value of electric current which can be carried continuously by a conductor, a device or an apparatus, under specified conditions without its steady-state temperature exceeding a specified value
[IEV number 826-11-13]

ampacity
The current in amperes that a conductor can carry continuously under the conditions of use without exceeding its temperature rating.
[National Electrical Cod]

FR

courant (permanent) admissible, m
valeur maximale du courant électrique qui peut parcourir en permanence, un conducteur, un dispositif ou un appareil, sans que sa température de régime permanent, dans des conditions données, soit supérieure à la valeur spécifiée
[IEV number 826-11-13]

Ampacity, the term is defined as the maximum amount of current a cable can carry before sustaining immediate or progressive deterioration. Also described as current rating or current-carrying capacity, is the RMS electric current which a device can continuously carry while remaining within its temperature rating. The ampacity of a cable depends on:

• its insulation temperature rating;
• conductor electrical properties for current;
• frequency, in the case of alternating currents;
• ability to dissipate heat, which depends on cable geometry and its surroundings;
• ambient temperature.

Electric wires have some resistance, and electric current flowing through them causes voltage drop and power dissipation, which heats the cable. Copper or aluminum can conduct a large amount of current before melting, but long before the conductors melt, their insulation would be damaged by the heat.

The ampacity for a power cable is thus based on physical and electrical properties of the material & construction of the conductor and of its insulation, ambient temperature, and environmental conditions adjacent to the cable. Having a large overall surface area may dissipate heat well if the environment can absorb the heat.

In a long run of cable, different conditions govern, and installation regulations normally specify that the most severe condition along the run governs the cable's rating. Cables run in wet or oily locations may carry a lower temperature rating than in a dry installation. Derating is necessary for multiple circuits in close proximity. When multiple cables are near, each contributes heat to the others and diminishes the amount of cooling air that can flow past the individual cables. The overall ampacity of the insulated conductors in a bundle of more than 3 must be derated, whether in a raceway or cable. Usually the de-rating factor is tabulated in a nation's wiring regulations.

Depending on the type of insulating material, common maximum allowable temperatures at the surface of the conductor are 60, 75 and 90 degrees Celsius, often with an ambient air temperature of 30°C. In the U.S., 105°C is allowed with ambient of 40°C, for larger power cables, especially those operating at more than 2 kV. Likewise, specific insulations are rated 150, 200 or 250°C.

The allowed current in cables generally needs to be decreased (derated) when the cable is covered with fireproofing material.

For example, the United States National Electric Code, Table 310-16, specifies that up to three 8 AWG copper wires having a common insulating material (THWN) in a raceway, cable, or direct burial has an ampacity of 50 A when the ambient air is 30°C, the conductor surface temperature allowed to be 75°C. A single insulated conductor in air has 70 A rating.

Ampacity rating is normally for continuous current, and short periods of overcurrent occur without harm in most cabling systems. The acceptable magnitude and duration of overcurrent is a more complex topic than ampacity.

When designing an electrical system, one will normally need to know the current rating for the following:

• Wires
• Printed Circuit Board traces, where included
• Fuses
• Circuit breakers
• All or nearly all components used

Some devices are limited by power rating, and when this power rating occurs below their current limit, it is not necessary to know the current limit to design a system. A common example of this is lightbulb holders.

[http://en.wikipedia.org/wiki/Ampacity]

Тематики

• электротехника, основные понятия

Синонимы

• длительно допустимый ток
• допустимый ток

EN

• ampacity (US)
• continuous current
• continuous current-carrying capacity
• current-carrying capacity

DE

• Dauerstrombelastbarkeit, f
• Strombelastbarkeit, f

FR

• courant admissible, m
• courant permanent admissible, m

обычно

. в каждодневной практике; принято; типичный

•

Such a stringent standard is now routinely met.

•

Liquid diffraction patterns characteristically show one or two maxima that correspond to...

•

The great majority of routinely detected events can be classified as earthquakes.

•

The receptacle is conventionally 2-wire, 120-volt, 15-ampere.

•

That is how the logarithms are conventionally tabulated.

•

This inert phase is normally a gel structure.

•

Engineering practice is to express quantities in lb/h.

•

Group I members tend to have relatively few nucleosides of this sort.

•

Such lasers typically generate pulses of 5—10 ns duration.

•

Traditionally, the residual bottoms have been blended with lighter stocks.

•

It is usual to check the... level whenever there is any doubt.

•

In this application it is common (or usual) to employ...

•

It is common for metabolic pathways to exhibit some form of cyclic pattern.

•

The atomic weight is commonly called the mass number.

•

The commonly used gases are seldom pure enough for use with these sensitive detectors.

•

The head gain is customarily measured in inches of water.

•

It is customary to install a pump having two or three stages.

•

The factor is generally taken to be equal to unity.

•

A field lens is generally placed behind the reticle.

•

Floating roof tanks are normally employed for prevention of loss through evaporation.

•

The temperature at this point is ordinarily the same as that of the forward cylinder section.

•

Where it is suspected that... it is the practice (or custom) to steam out the coils.

•

In large marine installations it is standard (or usual) practice to use...

•

The sensitivity for detection is typically (or usually, or generally, or commonly, or as a rule) five times as great as...

•

In designing such packed columns, it is common (or general) practice to assume "piston", or "plug" flow.

•

The regions of strongest divergence tend to be found over the subtropical regions.

•

Many plant breeders make a practice of having different batches of seed treated with gamma rays, neutrons and one chemical mutagen.

•

For a long time questions related to insulation were apt to be ignored.

•

The usual way to stop the intrusion has been to drill... (геол.).

II

•

In this way dye molecules can enter more freely otherwise inaccessible dye-sites.

в таблице перечислены

•

The table gives. (or lists) the percentage content of...

•

In Table 26 are listed (or tabulated, or given, or enumerated) the various...

•

The etching treatments that were used in the present investigation are listed in the table.

в таблице перечислены

•

The table gives. (or lists) the percentage content of...

•

In Table 26 are listed (or tabulated, or given, or enumerated) the various...

•

The etching treatments that were used in the present investigation are listed in the table.

данные

data, evidence, information, (напр. в таблице) reading

* * *

да́нные мн.
data; information; (заключение, выводы) findings

блоки́ровать да́нные — block data

вводи́ть да́нные — insert [enter, feed, introduce] data in(to)

вводи́ть да́нные в ЭВМ с (напр. носителя) — enter data into a computer from (e. g., a medium)

вводи́ть да́нные в ЭВМ с перфока́рт или перфоле́нты — read punch(ed) cards or tape into a computer

выбира́ть да́нные — retrieve [access] data

выводи́ть да́нные из ЭВМ на (напр. носитель) — output data from a computer to (e. g., a medium)

выдава́ть да́нные — generate data

вызыва́ть да́нные из па́мяти — call up data from memory

загружа́ть да́нные — load data

заноси́ть да́нные — enter data (e. g., in a logbook)

запомина́ть да́нные — store data

извлека́ть да́нные — withdraw data

набира́ть да́нные на клавиату́ре — key data onto a keyboard

нака́пливать да́нные — accumulate data

наноси́ть да́нные на метеорологи́ческую ка́рту — apply information to a weather chart, enter information on a weather chart

да́нные нано́сятся на ка́рту — a card is punched with data, data are punched into a card

нахожде́ние да́нных определя́ется а́дресом — data are located by an address

обме́ниваться да́нными (с кем-л.) — exchange [share] data (with smb.)

обновля́ть да́нные — update data

обобща́ть да́нные из не́скольких исто́чников — pool data

обраба́тывать да́нные — process [reduce] data

отобража́ть да́нные — display data

отраба́тывать да́нные

1. (в сервосистемах; после решения задачи) reproduce data

2. ( в процессе решения задачи) generate [derive] data

оты́скивать [находи́ть] да́нные по табли́це — look up a data item [a quantity] in a table

перемеща́ть да́нные — move data

переноси́ть да́нные с (ле́нты) на (ка́рты) — convert data from (a tape) to (cards) [to a card format]

представля́ть да́нные (о чём-л.) — present [represent] data (on smth.)

разблоки́ровать да́нные — unblock data

разгружа́ть да́нные — unload data

создава́ть да́нные — create data

упоря́дочивать да́нные — rank data

ана́логовые да́нные — analog(ue) data

ба́зисные да́нные — basic data

бу́квенно-цифровы́е да́нные — alpha(nu)meric data

бу́квенные да́нные — alphabetic data

да́нные в двои́чной фо́рме — binary data

входны́е да́нные — input (data)

вы́борочные да́нные — sampled data

выдава́емые да́нные — read-out, output (data)

выходны́е да́нные — output (data)

графи́ческие да́нные — graphic data

двои́чные да́нные — binary data

дискре́тные да́нные — digital data

имити́рованные да́нные — simulated data

да́нные испыта́ний — test findings

исхо́дные да́нные — initial data

ито́говые да́нные — summarized data; total

образо́вывать ито́говые да́нные — develop a total

коди́рованные да́нные — coded data

лаборато́рные да́нные — laboratory findings

лё́тно-техни́ческие да́нные — flight performance

наблюдё́нные да́нные — observed data

нача́льные да́нные — initial data

необрабо́танные да́нные — raw data

непреры́вные да́нные — analog(ue) data

обрабо́танные да́нные — processed information

да́нные ограни́ченного испо́льзования ( секретные данные) — confidential data

о́пытные да́нные — ( найденные практическим путём) empirical data; ( экспериментальные) experimental data

основны́е да́нные — basic data; basic specifications

па́спортные да́нные — rating(s), rated values, nameplate data

да́нные полево́го обсле́дования — field data

да́нные полево́й съё́мки — field survey data

попра́вочные да́нные — correction data

да́нные по себесто́имости — cost data

предвари́тельные да́нные — preliminary [tentative] data

да́нные приё́мо-сда́точных испыта́ний — acceptance-test data

да́нные прогно́за — predicted data

прое́ктные да́нные — design data

протоко́льные да́нные — performance-test data

рабо́чие да́нные — working data

радиотелеметри́ческие да́нные — radio-link telemetry data

радиотехни́ческие да́нные — radio data

расчё́тные да́нные — ( проектные) design data; ( в противоположность экспериментальным) calculated data

систематизи́рованные да́нные — regular [systematical] data

спра́вочные да́нные — reference data

статисти́ческие да́нные — statistical data

сумма́рные да́нные — summarized data

табли́чные да́нные — tabular [tabulated] data

телеметри́ческие да́нные — telemetered data

техни́ческие да́нные — technical data, technical characteristics, technical specifications

упоря́доченные да́нные — ranked [ordered] data

цифровы́е да́нные — ( числовые) numerical data; ( в цифровой форме) digital data

эксперимента́льные да́нные — experimental data

эксплуатацио́нные да́нные — service [operating] data

но даже с учётом этого

Но даже с учётом этого-- Owing to geometric differences, the deviations between the two sets of К values are not unreasonable. Even with this, the present authors are uneasy about the accuracy of the К values tabulated in [...].

табличное значение

Табличное значение

 If, however, more detailed results are needed, tabulated numerical values for all important parameters are contained in reference [...].

 With the measured values of wetbulb temperature and total pressure and with a table look-up for Psat at Twb, equation (...) yields Wwb.

округлять до ближайшего

•

The tabulated values are rounded off to the nearest 10°C.

подтверждать

. в значительной мере подтверждать

•

These observations reinforce the statement that...

•

This fact substantiates our conclusion.

•

These findings are evidence in favour of an assumption that...

•

Our experience has verified several important advantages of the new processor.

•

This result lends credence (or support) to the view that the alga-like organisms probably were photosynthetic.

•

Switches housed in aluminium continued to operate freely, thus attesting to aluminium's superior corrosion resistance.

•

The tabulated values bear out (or confirm, or corroborate) this relationship.

•

The two investigations provide support for this view.

•

The continuous nature of the frequency shifts supports the conclusion that...

беспокоить

Беспокоить-- The present authors are uneasy about the accuracy of the K values tabulated in [...]. (Нас беспокоит точность...)

— вполне естественно, беспокоит

— не может не беспокоить

надо признать, что

Надо признать, что

 Admittedly, these two-dimensional problems do overestimate the scattering efficiency.

 The values tabulated are admittedly somewhat imprecise because of the obvious difficulty involved with determining the slopes and intercepts of the lines plotted in Fig.