SU1325367A1 - Optoelectronic device for measuring pulsing current - Google Patents

Abstract

The invention may be used in a high voltage technique for remotely measuring alternating and pulsed voltages or currents. The purpose of the invention is to increase measurement accuracy. The device contains a measuring transducer 1, a calibration generator 2, radiation sources 4 and 6, optical channels 7 and 10, photo detectors 8 and P, photocurrent amplifiers 9 and 12, a recorder (5 and a synchronous detector 17. Introduction of summing amplifiers 3 and 13, differential amplifiers 5 and 14, the selective amplifier 16, the upper target 8, the error signal amplifier 19 and the reference voltage source 20, allows a constant calibration of the measuring device. 1 or 10 i CLC to have a

Description

The invention relates to a measurement technique and can be used in a high voltage technique for remotely measuring alternating and pulsed voltages or currents in electrical circuits that are under high potential with respect to earth.

The purpose of the invention is to improve the accuracy of the device.

The drawing shows a block diagram of the measuring device.

The outputs of the measuring transducer 1 and the calibration generator

2 through the first summing amplifier

3 are connected to the first radiation source 4 and through the first differential amplifier 5 with the second radiation source 6. First source

4 radiation through the optical channel 7 is connected with the first photodetector 8 connected to the first amplifier 9 of the photocurrent. A second radiation source 6 through optical channel 10 is connected to a second photodetector II connected to a second photocurrent amplifier 12. Photocurrent Amplifier Outputs 9

and 12 are connected to the inputs of the second summing dummy amplifier 13 and the inputs of the second differential amplifier 14. The output of the second summit amplifier 13 is connected to the recorder 15 and through a selective amplifier 16 and the synchronous detector 17 to the control input of the first amplifier 9 of the photocurrent. The output of the second differential amplifier 1A is connected to the reference input of the synchronous detector 17 and through the connector 18 and the error signal amplifier 19, the second input of which is connected to the source 20 of the reference voltage, is connected to the control input of the second photocurrent amplifier.

The measuring device works in the following way.

The output voltages of the measuring transducer 1 and the calibration generator 2 through the first RUYu11R1Y amplifier 3 control the first radiation source 4, generating a stream, the variable component of the intensity of which varies in proportion to the sum of the measured and calibration voltages. The same voltages, through the first differential amplifier 5, control the second radiation source 6, the variable component of which intensity is variable.

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It is proportional to the difference between the measured and calibration voltages. Difference and total radiation fluxes through the first 7 and second 10 optical channels arrive at the first 8 and second 11 photodetectors, which convert them into electrical signals amplified by the first 9 and second 12 photocurrent amplifiers. The output voltages of the photocurrent amplifiers 9 and 12 are fed to the inputs of the second summing amplifier 13. If the conversion factors of emission sources 4 and 6, the attenuation coefficients of optical channels 7 and 10, the conversion coefficients of photoreceivers 8 and 11 and the coefficients of photocurrent amplifiers 9 and 12 then the output of the second summing amplifier 13 produces a voltage proportional to the measured one. If the equality is not observed, then in the output voltage of the second sum of the amplifier 13, the harmonic appears at the frequency of the calibration voltage, which is amplified by the selective amplifier 16, detected by the synchronous detector 17 and changes the gain of the first amplifier of the photocurrent 9 so that the amplitude of the harmonic strives to 1st. Thus, the transfer coefficients of the total and differential channels are aligned.

In addition, the output voltages of the photocurrent amplifiers 9 and 12 are fed to the inputs of the second differential amplifier 14, which absorbs a voltage proportional to the calibration voltage. This voltage is rectified by rectifier 18 and is compared by amplifying 19 the error signal with a reference produced by the source 20 of the reference voltage. The transient voltage of the error signal amplifier 19 controls the second photocurrent amplifier 12 so that the amplitude of the voltage proportional to the calibration voltage at the output of the second differential amplifier 14 is equal to the reference voltage. In this way, the transfer coefficient of the total and differential channels is stabilized. The output voltage of the second differential amplifier 14 is also used as a reference for the synchronous detector 17, and the output voltage of the second summing amplifier 13 is proportional to (with a known coefficient of

proportionality factor) being measured, arrives at the recorder.

Thus, in contrast to the known device in the present invention, its calibration is carried out continuously without the need to interrupt the measurement process, as a result of which the accuracy and productivity of measurements is increased.

Claims (1)

Invention Formula An optoelectronic pulse current measuring device comprising a measuring transducer, a calibration generator, two radiation sources connected via two optical channels to two photoreceivers, two photocurrent amplifiers connected to photoreceivers, and a recorder, characterized in that it is equipped with two summing amplifiers, two differential amplifiers, a selective amplifier, syn. Composer A. Tszllkov Editor A. Kozoriz Tehred V. Kadar Order 3102/39 Circulation 730 Subscription  VNIIPI USSR State Committee on affairs of invention and discovery 113035, Moscow, Zh-35, Raushsk nab., d. A / 5 Production and printing department, Uzhgorod, st. Project, 4 a chronical detector, a rectifier, an error signal amplifier and a reference voltage source, while the outputs of the measuring converter and the calibration generator are connected through the first summing amplifier to the first radiation source and through the first differential amplifier to the second radiation source, the outputs of the photocurrent amplifiers are connected to the inputs of the second summing amplifier and the inputs of the second differential amplifier, the output of the second summing amplifier is connected to the recorder and through selective amplification The tele and synchronous detector with the control input of the first photocurrent amplifier, and the output of the second differential amplifier are connected to the reference input of the synchronous detector and through the coupler and error signal amplifier, the second input of which is connected to the reference voltage source, is connected to the control input of the second photocurrent amplifier . Proofreader A.Ilyin