replacement modules

replacement modules

взаимозаменяемые модули

replacement modules

взаимозаменяемые модули

replacement modules

1) Техника: взаимозаменяемые модули

2) Макаров: сменный блок, сменный модуль

взаимозаменяемые модули

replacement modules

взаимозаменяемые модули

replacement modules

взаимозаменяемые модули

replacement modules

сменный блок

1) Engineering: plug-in module, plug-in unit, pluggable unit, replaceable block, replaceable module, replacement unit, slide-in chassis

2) Railway term: plug in component

3) Automobile industry: plug-in, plug-in block

4) Telecommunications: replacement assembly

5) Electronics: bench-replacement assembly

6) Mechanics: plug-in package

7) Robots: plug-in package (со штепсельным соединением)

8) Makarov: replacement modules

module

1) модуль; блок; узел

2) разбивать на модули

3) унифицированный элемент

4) космонавт. отсек

•

module of package dimensions — модуль размеров тары

-
access module
-
albedocollecting solar module
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all-space module
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amorphous silicon power module
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analog divider module
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analog timing module
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antilock module
-
applications software module
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applications module
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astronaut free-flying propulsion module
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basic building-block module
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basic module
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bifacial solar module
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biological module
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biomedical module
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buoyancy riser module
-
CAE module
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CAM module
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card module
-
carriage module
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ceiling module
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cell control module
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close-pack module
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computation module
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concentrating photovoltaic module
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control module
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controller module
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co-orbiting module
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coplanar module
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cordwood module
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core module
-
crew module
-
definition module
-
descent module
-
digital module
-
docking module
-
docking payload module
-
dummy module
-
EDP module
-
electronic module
-
engine module
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enlarged module
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final drive exchange module
-
finite state-automata module
-
flat-plate solar module
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flexible assembly module
-
free-flying module
-
fuel module
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full interchangeable modules
-
functional module
-
function module
-
gas-compressor module
-
habitable module
-
hardware interface module
-
hardware module
-
hardware/software module
-
horizontal baseline module
-
hybrid module
-
hydraulic module
-
implementation module
-
inference control module
-
input/output control module
-
instrumentation module
-
instrument module
-
instrument-assembly module
-
instrumentation-propulsion module
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interface module
-
irrigation module
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laboratory space module
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landing module
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laterally docked module
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linear module
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living quarter module
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loading module
-
load module
-
logistics module
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longitudinal docked module
-
machining module
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man-tended module
-
measurement module
-
meteorological module
-
microcircuit module
-
microminiature module
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motorized pump module
-
multistring photovoltaic module
-
nuclear-power module
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number assignment module
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object module
-
oceanographic module
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OMS module
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orbit transfer vehicle module
-
orbital maneuvering system module
-
OTV module
-
payload module
-
pellet module
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personality module
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personal module
-
photovoltaic module
-
pilot cell module
-
plug-in module
-
point-focusing photovoltaic module
-
potted module
-
power module
-
power shift transmission module
-
prefabricated module
-
pressurized module
-
probe module
-
process execution module
-
programmable module
-
propulsion module
-
radially docked module
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RCS module
-
reaction control system module
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redocked modules
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reenterable module
-
regulator module
-
replaceable module
-
replacement modules
-
retro propulsion module
-
robot grip module
-
robot module
-
robotic slip module
-
scientific equipment module
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scientific research module
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self-contained module
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sensor module
-
service module
-
shingle-type photovoltaic module
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signal processing module
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single-ended module
-
software module
-
solar array module
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solar battery module
-
solar module
-
solar-power module
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source module
-
space station module
-
stacked module
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standard module
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subordinate module
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tanker module
-
terrain monitoring module
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three-dimensional module
-
transfer module
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transmit-receive module
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unmanned module
-
up-and-down module
-
utility module
-
working module

взаимозаменяемые модули

Engineering: interchangeable modules, replacement modules

сменный модуль

1) Engineering: card module, plug-in device, plug-in module, plug-in unit, replaceable module

2) Polygraphy: interchangeable module

3) Telecommunications: cassette, plug-in circuit, replacement unit

4) Information technology: plug-in component

5) Makarov: replacement modules

module

1) модуль (структурная единица программы, единица декомпозиции программного обеспечения)

2) модуль, блок (аппаратуры)

•

- add-in module

- add-on module
- alternative module
- application module
- architectural module
- box-like module
- card module
- communication terminal module
- control output module
- debug module
- decoupled modules
- digital input module
- digital module
- digital output module
- dummy module
- executable module
- expansion module
- explanation module
- faulty module
- flat module
- generic module
- good module
- hard module
- hardware module
- higher-level module
- honeycomb module
- input/output control module
- intelligent module
- key transport module
- load module
- logic module
- logic-in-memory module
- memory module
- module with many terminals
- multichip module
- multifunctional module
- nested modules
- network interface module
- not editable module
- N-segment numeric display module
- null module
- object module
- overlapping modules
- overlay module
- package module
- parent module
- pattern module
- peer modules
- personality module
- personal module
- pin module
- power module
- processor module
- programming module
- program module
- quad-width module
- reenterable module
- reentrant module
- refreshable module
- relocatable module
- replacement module
- resident module
- reusable module
- root module
- self-contained module
- silicon module
- single-in-line module
- soft module
- software module
- source module
- standard module
- substitution module
- tamper-resistant module
- task module
- terminal module
- thermal-conduction module
- timing module
- top module
- transport module
- VLSI module
- welded module
- wire-wrap module

параллельная система ИБП

1. parallel UPS system

 

параллельная система ИБП
-
[Интент]

Parallel Operation: The system shall have the option to install up to four (4) UPSs in parallel configuration for redundancy or capacity.
1. The parallel UPS system shall be of the same design, voltage, and frequency. UPS modules of different size ratings shall be permitted to be paralleled together for purposes of increased capacity or UPS module redundancy. The UPSs in the parallel configuration shall not be required to have the same load capacity rating.
2. Parallel Capacity: With N+0 system-level redundancy, up to 2MW of load can be supported by the system.
3. Parallel Redundancy: With N+1 system-level redundancy, up to 1.5MW of load can be supported by the system, and only the UPS being replaced must be isolated from the source (bypass operation is not required for the entire system during the UPS replacement procedure).
4. Output control: A load sharing circuit shall be incorporated into the parallel control circuits to ensure that under no-load conditions, no circulating current exists between modules. This feature also allows each UPS to share equal amounts of the total critical load bus. The output voltage, output frequency, output phase angle, and output impedance of each module shall operate in uniformity to ensure correct load sharing. This control function shall not require any additional footprint and shall be an integral function of each UPS. The static bypass switches shall be connected in parallel.
5. Parallel System Controls: To avoid single points of failure, the UPS system shall have no single dedicated control system designed to control the operation of the parallel UPS system. Control of and direction of parallel UPSs shall take place via a master/slave relationship, where the first UPS to receive logic power asserts itself as a master. In the event of a master failure, a slave UPS shall take the role of master and assume the responsibility of the previous master UPS. Regardless of which UPS is master or slave, user changes to the system status, such as request for bypass, can be done from any UPS connected to the bus and all UPS on the bus shall transfer in simultaneously.
6. Communication: Communication between modules shall be connected so that the removal of any single cable shall not jeopardize the integrity of the parallel communication system. Load sharing communications shall be galvanically isolated for purposes of fault tolerance between UPS modules. A UPS module's influence over load sharing shall be inhibited in any mode where the UPS inverter is not supporting its output bus. Transfers to and from bypass can be initiated from any online UPS in the system.
7. Display: Each UPS multi-color LCD touch screen user interface shall be capable of using an active touch screen mimic bus to show the quantity of UPS(s) connected to the critical bus, as well as the general status of each UPS, such as circuit breaker status information. Any touchscreen display shall support the configuration of the [entire parallel] system and shall provide event and alarm data for all UPSs in the parallel configuration. A Virtual Display Application shall be available for download to the customer’s computer and shalll support remote monitoring of a complete system with up to 4 UPSs in parallel.
8. Battery runtime: Each UPS must have its own battery solution. The battery solution for the entire system can be a combination of standard and third-party batteries, but each UPS must use only one battery solution – either standard or third-party batteries.
9. Switchgear: A custom switchgear option shall be required for parallel operation.

[Schneider Electric]

Тематики

• источники и системы электропитания

EN

• parallel UPS system

parallel UPS system

1. параллельная система ИБП

 

параллельная система ИБП
-
[Интент]

Parallel Operation: The system shall have the option to install up to four (4) UPSs in parallel configuration for redundancy or capacity.
1. The parallel UPS system shall be of the same design, voltage, and frequency. UPS modules of different size ratings shall be permitted to be paralleled together for purposes of increased capacity or UPS module redundancy. The UPSs in the parallel configuration shall not be required to have the same load capacity rating.
2. Parallel Capacity: With N+0 system-level redundancy, up to 2MW of load can be supported by the system.
3. Parallel Redundancy: With N+1 system-level redundancy, up to 1.5MW of load can be supported by the system, and only the UPS being replaced must be isolated from the source (bypass operation is not required for the entire system during the UPS replacement procedure).
4. Output control: A load sharing circuit shall be incorporated into the parallel control circuits to ensure that under no-load conditions, no circulating current exists between modules. This feature also allows each UPS to share equal amounts of the total critical load bus. The output voltage, output frequency, output phase angle, and output impedance of each module shall operate in uniformity to ensure correct load sharing. This control function shall not require any additional footprint and shall be an integral function of each UPS. The static bypass switches shall be connected in parallel.
5. Parallel System Controls: To avoid single points of failure, the UPS system shall have no single dedicated control system designed to control the operation of the parallel UPS system. Control of and direction of parallel UPSs shall take place via a master/slave relationship, where the first UPS to receive logic power asserts itself as a master. In the event of a master failure, a slave UPS shall take the role of master and assume the responsibility of the previous master UPS. Regardless of which UPS is master or slave, user changes to the system status, such as request for bypass, can be done from any UPS connected to the bus and all UPS on the bus shall transfer in simultaneously.
6. Communication: Communication between modules shall be connected so that the removal of any single cable shall not jeopardize the integrity of the parallel communication system. Load sharing communications shall be galvanically isolated for purposes of fault tolerance between UPS modules. A UPS module's influence over load sharing shall be inhibited in any mode where the UPS inverter is not supporting its output bus. Transfers to and from bypass can be initiated from any online UPS in the system.
7. Display: Each UPS multi-color LCD touch screen user interface shall be capable of using an active touch screen mimic bus to show the quantity of UPS(s) connected to the critical bus, as well as the general status of each UPS, such as circuit breaker status information. Any touchscreen display shall support the configuration of the [entire parallel] system and shall provide event and alarm data for all UPSs in the parallel configuration. A Virtual Display Application shall be available for download to the customer’s computer and shalll support remote monitoring of a complete system with up to 4 UPSs in parallel.
8. Battery runtime: Each UPS must have its own battery solution. The battery solution for the entire system can be a combination of standard and third-party batteries, but each UPS must use only one battery solution – either standard or third-party batteries.
9. Switchgear: A custom switchgear option shall be required for parallel operation.

[Schneider Electric]

Тематики

• источники и системы электропитания

EN

• parallel UPS system

Charnley, John

SUBJECT AREA: Medical technology

[br]

b. 29 August 1911 Bury, Lancashire, England

d. 5 August 1982 Lancashire, England

[br]

English orthopedic surgeon, pioneer of ultra-clean-air operating-theatre environments and of total hip-joint replacement.

[br]

During his medical training at Manchester he qualified for the Fellowship of the Royal College of Surgeons and obtained his FRCS in 1936, within a year of becoming medically qualified. Following military service as an orthopaedic specialist, he was appointed a consultant at the Manchester Royal Infirmary in 1947.

Charnley investigated the problems of joint lubrication using polytetrafluoroethylene (PTFE) and a series of 300 initially successful cases laid the foundation for further developments, involving total hip-joint replacement, when in 1962 high-density polythene became available as a suitable inert material. The need for a totally sterile operating environment in which to carry out such procedures led him to develop ultra-clean-air operating-theatre modules which proved to have wide application in relation to other surgical disciplines and to the problems of hospital building. To further these principles he resigned from the Royal Infirmary and was the guiding spirit in the establishment of the centre for hip surgery at Wrightington Hospital in Lancashire, which gained wide international recognition.

[br]

Principal Honours and Distinctions

Knighted 1977. FRS 1964. Fellow of the Royal College of Surgeons. British Medical Association Gold Medal 1978.

Bibliography

1961, "Arthroplasty of the hip", Lancet.

1974, Wound Infection after Hip Replacement Performed in a Clean-Air Operating Room, Wrightington.

1970, Acrylic Cement in Orthopaedic Surgery, Baltimore.

MG