main pressure controller - перевод на русский
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main pressure controller - перевод на русский

CONTAINER DESIGNED TO HOLD GASES OR LIQUIDS AT A PRESSURE SUBSTANTIALLY DIFFERENT FROM THE AMBIENT PRESSURE
Chemical vessel; Pressure chamber; Pressure chambers; Main reservoir (locomotive); Bullet (pressure vessel); Air receiver; Pneumatic chamber; Pneumatic vessel; Airtight chamber; Overpressure (engineering); Boiler overpressure; Pressure vessels; Pressure equipment
  • Preserved [[H.K. Porter, Inc.]] No. 3290 of 1923 powered by [[compressed air]] stored in a horizontal [[rivet]]ed pressure vessel
  • Composite overwrapped pressure vessel with titanium liner.
  • date=June 2020}}
  • A welded steel pressure vessel constructed as a horizontal cylinder with domed ends. An access cover can be seen at one end, and a drain valve at the bottom centre.
  • abbr=on}} pressure vessel from 1919, wrapped with high tensile steel banding and steel rods to secure the end caps.
  • Animation showing two stages of deep drawing of a steel plate to a cup, and a similar cup to a diving cylinder blank with domed bottom
  • Stress in the cylinder body of a pressure vessel.
Найдено результатов: 1479
main pressure controller      

нефтегазовая промышленность

регулятор давления в газосборнике

disk controller         
CONTROLLER FOR DISK STORAGE, USUALLY INTEGRATED INTO THE DRIVE
Hard disk controller; Hard drive controller; HD controller; Drive controller

общая лексика

дисковый контроллер, контроллер диска

плата расширения и/или микросхема, обеспечивающая взаимодействие процессора с дисковым накопителем

PID controller         
  • Showing the evolution of analog control loop signaling from the pneumatic to the electronic eras
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>d</sub> (''K''<sub>p</sub> and ''K''<sub>i</sub> held constant)
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>i</sub> (''K''<sub>p</sub> and ''K''<sub>d</sub> held constant)
  • Proportional control using nozzle and flapper high gain amplifier and negative feedback
  • Effects of varying PID parameters (K<sub>p</sub>,K<sub>i</sub>,K<sub>d</sub>) on the step response of a system
  • A [[block diagram]] of a PID controller in a feedback loop. ''r''(''t'') is the desired process value or setpoint (SP), and ''y''(''t'') is the measured process value (PV).
  • PID with derivative filtering
  • PID without derivative filtering
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>p</sub> (''K''<sub>i</sub> and ''K''<sub>d</sub> held constant)
  • Basic block of a PI controller
  • alt=
  • Early PID theory was developed by observing the actions of [[helmsmen]] in keeping a vessel on course in the face of varying influences such as wind and sea state.
  • Current loops used for sensing and control signals. A modern electronic "smart" valve positioner is shown, which will incorporate its own PID controller.
CONTROL LOOP MECHANISM USED IN CONTROL ENGINEERING
PID loop; Proportional-Integral-Derivative controller; PID tuning; PID algorithm; Proportional integral derivative; PI controller; PD controller; PID control; PI Controller; Pi controller; Pidc; PID Controller; Proportional–integral–derivative controller; P.I.D. control; Droop (control); Proportional-integral-derivative controller; PID feed back controller; PID feedback controller; Three term controller; Steady-state error
ПИД-регулятор, пропорционально-интегральный (изодромный) регулятор с предварением
three term controller         
  • Showing the evolution of analog control loop signaling from the pneumatic to the electronic eras
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>d</sub> (''K''<sub>p</sub> and ''K''<sub>i</sub> held constant)
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>i</sub> (''K''<sub>p</sub> and ''K''<sub>d</sub> held constant)
  • Proportional control using nozzle and flapper high gain amplifier and negative feedback
  • Effects of varying PID parameters (K<sub>p</sub>,K<sub>i</sub>,K<sub>d</sub>) on the step response of a system
  • A [[block diagram]] of a PID controller in a feedback loop. ''r''(''t'') is the desired process value or setpoint (SP), and ''y''(''t'') is the measured process value (PV).
  • PID with derivative filtering
  • PID without derivative filtering
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>p</sub> (''K''<sub>i</sub> and ''K''<sub>d</sub> held constant)
  • Basic block of a PI controller
  • alt=
  • Early PID theory was developed by observing the actions of [[helmsmen]] in keeping a vessel on course in the face of varying influences such as wind and sea state.
  • Current loops used for sensing and control signals. A modern electronic "smart" valve positioner is shown, which will incorporate its own PID controller.
CONTROL LOOP MECHANISM USED IN CONTROL ENGINEERING
PID loop; Proportional-Integral-Derivative controller; PID tuning; PID algorithm; Proportional integral derivative; PI controller; PD controller; PID control; PI Controller; Pi controller; Pidc; PID Controller; Proportional–integral–derivative controller; P.I.D. control; Droop (control); Proportional-integral-derivative controller; PID feed back controller; PID feedback controller; Three term controller; Steady-state error

строительное дело

ПИД-регулятор, пропорционально-интегральный (изодромный) регулятор с предварением

three term controller         
  • Showing the evolution of analog control loop signaling from the pneumatic to the electronic eras
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>d</sub> (''K''<sub>p</sub> and ''K''<sub>i</sub> held constant)
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>i</sub> (''K''<sub>p</sub> and ''K''<sub>d</sub> held constant)
  • Proportional control using nozzle and flapper high gain amplifier and negative feedback
  • Effects of varying PID parameters (K<sub>p</sub>,K<sub>i</sub>,K<sub>d</sub>) on the step response of a system
  • A [[block diagram]] of a PID controller in a feedback loop. ''r''(''t'') is the desired process value or setpoint (SP), and ''y''(''t'') is the measured process value (PV).
  • PID with derivative filtering
  • PID without derivative filtering
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>p</sub> (''K''<sub>i</sub> and ''K''<sub>d</sub> held constant)
  • Basic block of a PI controller
  • alt=
  • Early PID theory was developed by observing the actions of [[helmsmen]] in keeping a vessel on course in the face of varying influences such as wind and sea state.
  • Current loops used for sensing and control signals. A modern electronic "smart" valve positioner is shown, which will incorporate its own PID controller.
CONTROL LOOP MECHANISM USED IN CONTROL ENGINEERING
PID loop; Proportional-Integral-Derivative controller; PID tuning; PID algorithm; Proportional integral derivative; PI controller; PD controller; PID control; PI Controller; Pi controller; Pidc; PID Controller; Proportional–integral–derivative controller; P.I.D. control; Droop (control); Proportional-integral-derivative controller; PID feed back controller; PID feedback controller; Three term controller; Steady-state error
ПИД-регулятор, пропорционально-интегральный (изодромный) регулятор с предварением
PID controller         
  • Showing the evolution of analog control loop signaling from the pneumatic to the electronic eras
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>d</sub> (''K''<sub>p</sub> and ''K''<sub>i</sub> held constant)
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>i</sub> (''K''<sub>p</sub> and ''K''<sub>d</sub> held constant)
  • Proportional control using nozzle and flapper high gain amplifier and negative feedback
  • Effects of varying PID parameters (K<sub>p</sub>,K<sub>i</sub>,K<sub>d</sub>) on the step response of a system
  • A [[block diagram]] of a PID controller in a feedback loop. ''r''(''t'') is the desired process value or setpoint (SP), and ''y''(''t'') is the measured process value (PV).
  • PID with derivative filtering
  • PID without derivative filtering
  • Response of PV to step change of SP vs time, for three values of ''K''<sub>p</sub> (''K''<sub>i</sub> and ''K''<sub>d</sub> held constant)
  • Basic block of a PI controller
  • alt=
  • Early PID theory was developed by observing the actions of [[helmsmen]] in keeping a vessel on course in the face of varying influences such as wind and sea state.
  • Current loops used for sensing and control signals. A modern electronic "smart" valve positioner is shown, which will incorporate its own PID controller.
CONTROL LOOP MECHANISM USED IN CONTROL ENGINEERING
PID loop; Proportional-Integral-Derivative controller; PID tuning; PID algorithm; Proportional integral derivative; PI controller; PD controller; PID control; PI Controller; Pi controller; Pidc; PID Controller; Proportional–integral–derivative controller; P.I.D. control; Droop (control); Proportional-integral-derivative controller; PID feed back controller; PID feedback controller; Three term controller; Steady-state error

строительное дело

ПИД-регулятор, пропорционально-интегральный (изодромный) регулятор с предварением

floppy-disk controller         
  • A setup disk of Japanese [[Microsoft Office]] 4.3, provided with 3.5" 1.2&nbsp;MB and 1440&nbsp;KB formats.
CIRCUITRY THAT CONTROLS READING FROM AND WRITING TO A COMPUTER'S FLOPPY DISK DRIVE
Floppy Disk Controller; Intel 82072A; Intel 82072; NEC µPD765; NEC uPD765; Floppy controllers; 3 mode; 3-mode; 3mode; Floppy disk controller; NEC D765; NEC 765; NEC 765A; NEC D765A; NEC µPD765A; ΜPD765; ΜPD765A; NEC uPD765A; UPD765; UPD765A; D765A; Intel 8072A; NEC μPD765; NEC μPD765A; Floppy controller; FDC controller; Philips interface bus; Floppy diskette controller; Diskette controller; Floppy disk drive controller; 2HC

общая лексика

контроллер НГМД

air receiver         

строительное дело

ресивер сжатого воздуха, воздухосборник

нефтегазовая промышленность

воздушный ресивер

воздушный резервуар

воздухоприёмник

воздухосборник

pressure vessel         
сосуд, работающий под давлением
pressure vessel         
сосуд высокого давления

Определение

ЗВУКОВОЕ ДАВЛЕНИЕ
переменное избыточное давление, возникающее в среде при прохождении звуковой волны. Обычно звуковое давление мало по сравнению с постоянным давлением в среде. Звуковое давление следует отличать от давления звука.

Википедия

Pressure vessel

A pressure vessel is a container designed to hold gases or liquids at a pressure substantially different from the ambient pressure.

Construction methods and materials may be chosen to suit the pressure application, and will depend on the size of the vessel, the contents, working pressure, mass constraints, and the number of items required.

Pressure vessels can be dangerous, and fatal accidents have occurred in the history of their development and operation. Consequently, pressure vessel design, manufacture, and operation are regulated by engineering authorities backed by legislation. For these reasons, the definition of a pressure vessel varies from country to country.

Design involves parameters such as maximum safe operating pressure and temperature, safety factor, corrosion allowance and minimum design temperature (for brittle fracture). Construction is tested using nondestructive testing, such as ultrasonic testing, radiography, and pressure tests. Hydrostatic pressure tests usually use water, but pneumatic tests use air or another gas. Hydrostatic testing is preferred, because it is a safer method, as much less energy is released if a fracture occurs during the test (water does not greatly increase its volume when rapid depressurization occurs, unlike gases, which expand explosively). Mass or batch production products will often have a representative sample tested to destruction in controlled conditions for quality assurance. Pressure relief devices may be fitted if the overall safety of the system is sufficiently enhanced.

In most countries, vessels over a certain size and pressure must be built to a formal code. In the United States that code is the ASME Boiler and Pressure Vessel Code (BPVC). In Europe the code is the Pressure Equipment Directive. Information on this page is mostly valid in ASME only. These vessels also require an authorized inspector to sign off on every new vessel constructed and each vessel has a nameplate with pertinent information about the vessel, such as maximum allowable working pressure, maximum temperature, minimum design metal temperature, what company manufactured it, the date, its registration number (through the National Board), and American Society of Mechanical Engineers's official stamp for pressure vessels (U-stamp). The nameplate makes the vessel traceable and officially an ASME Code vessel.

A special application is pressure vessels for human occupancy, for which more stringent safety rules apply.

Как переводится main pressure controller на Русский язык