SU1137403A1 - Device for touch-free measuring of current - Google Patents

Abstract

DEVICE FOR CONTACTLESS MEASUREMENT OF CURRENT POWER, containing on the high potential side, a polarizer installed in series along the light rays, a current converter into the angle of rotation of the polarization plane and a two-beam analyzer, and on the low potential side - the first and second radiation sources coupled with two individual bell-shaped fibers, the first of which is connected to the first input of the polarizer by the other end, a modulation frequency generator, the first output of which is connected to one of the controls The secondary inputs of the second radiation source, two photodetectors optically coupled through the third and quarter optical fibers with the outputs, a three-beam analyzer, two photocurrent amplifiers with adjustable transmission coefficients, the signal inputs of which are connected to the outputs of the corresponding photoreceivers, the summation unit and the subtraction unit, whose inputs are connected to the outputs of the photocurrent amplifiers, the first differential amplifier, one of the inputs of which is connected to the zero potential bus, and the output to the control input of one of photocurrent amplifiers, the second differential: the other amplifier, one of the inputs of which is connected to the output of the reference voltage source, and the output to the control input of another photo current amplifier, the first selective amplifier, the input of which is connected to the output of the subtractor, the first synchronous a detector, one of the inputs of which is (the Logo is connected to the output of the first selective amplifier, and the other input to the second output of the modulation frequency generator, a low-pass filter and a recording device, characterized in that, in order to improve the accuracy and measuring, a third differential amplifier, a second selective amplifier and a second synchronous detector are entered into it, and the polarizer is designed as a two-beam prism, one of the inputs of the third differential amplifier SAD is connected to the zero potential bus, the other input is connected to the output the second synchronous detector, and the output with a different control input of the second radiation source, the output of the summation unit is connected to the input of the second selective amplifier and another input of the second: differential amplifier, output block After subtracting through a low-pass filter, it is connected to another input of the first differential amplifier, one of the inputs of the second blue

Description

the chronically detector is connected to the output of the second selective amplifier, and the other input is connected to the second output of the modulation frequency generator, which is connected to the control input of the first

the radiation source, the other end of the second optical fiber is connected to the second input of the polarizer, and the input of the recording device is connected to the output of the first synchronous detector.

one

The invention relates to electrical measuring equipment and is intended for use in measuring the current of high voltage power lines of constant and alternating voltages.

YcTpoUQTBO is known for contactless measurement of the current strength, containing a source of polarized light, optically coupled to a current transducer into the angle of rotation of the polarization plane, a two-beam prism installed along the path of the light flux between said converter and two photodetectors,

about

whose outputs are connected to the signal inputs of the corresponding photocurrent amplifiers, the summation unit and the subtraction unit, whose inputs are connected to the outputs of the photocurrent amplifiers, and the outputs to the first inputs of synchronous detectors, a signal generator whose output is connected to the second inputs of synchronous detectors, a differential amplifier, is one of the inputs of which are connected to the output of the voltage source, the other input is connected to the output circuit of the summation unit, and the output is connected to the control inputs of both photocurrent amplifiers registered th device whose input through one of the synchronous detectors connected to the output of subtracting unit A.

A disadvantage of the known device is that in its practical use there are significant additive and multiplicative measurement errors due to the unequal sensitivity of photodetectors.

The closest to the invention is a device for contactless measurement of current, containing on the high potential side a polarizer, a current converter to the angle of rotation of the polarization polarization (a Farade cell), a mixer and a two-beam analyzer, and a low-potential analyzer; the first and second radiation sources optically coupled through the first and second optical fibers with the inputs of a polarizer and a mixer, respectively, a modulation frequency generator, an output which is connected to the control input of the second radiation source, two photodetectors optically coupled through the third and fourth fiber lights to the outputs of the dual-beam analyzer, two amplifiers

photocurrent with adjustable transmission coefficients, the signal inputs of which are connected to the outputs of the corresponding photodetectors, the summation unit and the first subtraction unit, whose inputs are connected to the outputs of the photocurrent amplifiers, the first differential amplifier, one of the inputs of which is connected to the zero potential bus, and the output is controlled the input of one of the photocurrent amplifiers, the second differential amplifier, one of the inputs of which is connected to the output of the reference voltage source, and the output to the control input of the other preamplifier photocurrent selective amplifier, whose input is connected to the output of the first subtracting unit, a synchronous detector, one input of which is connected to the output of the selective amplifier, the other input - to the output of the generator

modulation frequency, and the output to another input of the first differential amplifier, the second subtraction unit, one of the inputs of which through the first low-pass filter, the other input through a series-connected high-pass filter, the rectifier and the second low-pass filter are connected to the output of the summation unit, and the output is connected to another input of the second differential amplifier, the registering device, the input of which is connected to the output of the first subtraction unit 2. The disadvantage of this device is the low accuracy of measurement due to the presence of a special mixer of two beams in its composition. A real mixer, made in the form of a translucent mirror or a beam-splitting cube, changes the polarization and the light passing through it. The unpolarized light, the passage of the mixer, becomes partially polarized and because of this, when an inaccurate mutual installation of the analyzer and the mixer occurs, multiplicative error arises because the contribution from the second radiation source - the polarization of the light passing through the Farad cell , additionally changes with the passage of the mixer, which leads to significant additive and multiplicative measurement errors. The purpose of the invention is to improve the measurement accuracy of the measuring device. . This goal is achieved by the fact that in a device for contactless measurement of current, containing on the high potential side the polarizers are successively installed along the light beams, a polarizer, an inverter for converting the plane of polarization polarization and a two-beam analyzer, and on the low potential side - the first and second radiation sources, coupled with two individual optical fibers, the first of which is connected to the first input of the polarizer by a different end, the modulation frequency generator, the first output D which is connected to one of the control inputs of the second radiation source, two photoreceivers, optically coupled through the third and fourth optical fibers with the outputs of the two-beam analyzer, two. a photocurrent amplifier with adjustable transmission coefficients, the signal inputs of which are connected to the outputs of the corresponding photodetectors, a summation unit and a subtraction unit, the inputs of which are connected to the outputs of the photocurrent amplifiers, the first differential amplifier, one of the inputs of which is connected to the zero potential bus, and the output is controlled The input is one of the photocurrent amplifiers, the second differential amplifier, one of the inputs of which is connected to the output of the reference voltage source, and the output to the control input of the other photocurrent amplifier, the first selective amplifier, whose input is connected to the output of the subtraction unit, the first synchronous detector, one of the inputs of which is connected to the output of the first selective amplifier, and the other input to the second output of the modulation frequency generator, low pass filter and recording device, A differential differential amplifier, a second selective amplifier and a second synchronous detector, and a polarizer are made in the form of a double-prism, with one of the inputs of the third differential amplifier connected to w another zero potential, another input with the output of the second synchronous detector, and the output with another control input of the second radiation source, the output of the summation unit is connected to the input of the second selective amplifier and another input of the second differential amplifier, the output of the subtraction unit is connected to another through a low-pass filter the input of the first differential amplifier, one of the inputs of the second synchronous detector is connected to the output of the second selective amplifier, and the other input is connected to the second output of the frequency generator; This is connected to the control input of the first radiation source, the other end of the second optical fiber is connected to the second input of the polarizer, and the input of the recording device is connected to the output of the first synchronous detector. The drawing shows a functional diagram of the proposed device for contactless measurement of current. The device contains, on the high potential side, a polarizer 1 arranged in series along the light rays, made in the form of a two-beam prism, a current transducer 2 into the angle of rotation of the plane S. 1 polarization (Faradet cell) and dual beam / 1izator 3 (Wollaston prism). On the low potential side, there are first and second sources 4 and 5 connected by optical fibers 6 and 7 to the inputs of polarizer 1, a generator 8 of modulation frequency, photodetectors 9 and lOj optically connected via optical fibers 11 and 12 to the outputs of the Zdusili analyzer The photocurrents are 13 and 14 with adjustable. transfer coefficients; block 15; summation; block 16; plugs;, differential amplifiers 17-195; source 20, reference voltage 5. 21 low-pass filter, selective Amplifiers 22 and 23, synchronous detectors 24 and 2.5 and a recording device 26. Paraphase outputs of the modulation frequency generator 8 are connected to the control input of source 4 and one of the control inputs of the radiation source 5. The signal inputs of the photocurrent amplifiers 13 and 14 are connected to the outputs of photodetectors 9 and 10, the control inputs to the outputs of differential amplifiers 17 and 18, and the outputs to the inputs of the summation unit 15 and the subtraction unit 16 One of the inputs of the differential amplifier 17 is connected to the zero potential bus, and The other input is through a low-pass filter 21 - with the output of the 16-gang unit connected to the input of the selective amplifier 22. One of the inputs of the differential amplifier 18 is connected to the output of the source 20 of the reference voltage e and the other input to the output of the block 15 s connected to the input of the selective amplifier 23. One of the inputs of the synchronous detector 24 is connected to the output of the selective amplifier 22, the other input to the output of the generator 8 of the modulation frequency, and the output to the input of the recording instrument 26. One of the inputs of the synchronous The detector 23 is connected to the output of the selective amplifier 23, the other input to the outputs of the generator 8 of the modulation frequency. One of the inputs of the differential amplifier 19 is connected to the zero potential bus, the other input is connected to the output of the synchronous detector 25, and the output is connected to the other control input of the source 5 from the beam. 3 The operation of the device is as follows. Light from sources 4 and 5 of radiation alternately through optical fibers 6 and 7 is fed to two inputs of a double-beam polarizer 1. Power sources 4 and 5 of radiation are emitted from a modulation frequency generator 8, which is connected to them alternately for half a frequency module. of Semiconductor lasers or LEDs can be used as radiation sources 4 and 5, and direct optical contact, focons, lenses or micro-lenses can be used to inject radiation into the fiber. From polarizer 1, linearly polarized light emerges with modulation along the polarization plane, and the modulation depth is 90 Light passes the converter 2 of the measured current strength into the angle of rotation of the polarization plane — the Farade cell. In the simplest case, as is conventionally shown in the diagram, the cell is a rod of diamagnetic glass, the magnetic field of the measured current I along the lines of force I. After the converter, the light enters the two-beam analyzer 3, which divides the incident flux into two streams, having orthogonal polarization. The azimuth of the analyzer 3. is chosen so that the azimuths of the polarization provided by it are different from the azimuth of the polarization of the light coming out of the polarizer 1. After analyzer 3, two output beams go through optical fibers 9 and 10, which convert radiation fluxes incident on them into electrical signals. The latter are amplified by photocurrent amplifiers 13 and 14. The sum and difference signals are formed at the outputs of the summation unit 15 and the subtraction unit 16, respectively. The simultaneous elimination of the constant component of the difference signal and the variable component of the modulation frequency in the total signal allows us to exclude additive and multiplicative errors from the unequal sensitivities of the photodetectors 9 and 10, skip coefficients71

Neither the optical fibers 6, 7, 11 and 12, the radiation fluxes of the sources 4 and 5. To this end, the constant component of the difference signal through the low-pass filter 21 comes after amplification in the differential amplifier 17 to the control input of the photocurrent amplifier 13 and changes the transmission coefficient the amplifier 13 until the disappearance of the constant component of the differential signal. This forms the first loop of the feedback. The variable component of the sum signal is amplified by a selective amplifier 23, outputted by a synchronous detector 25 and, after amplification of the output voltage in the differential amplifier 19, acts on the corresponding control input of the radiation source 5 until the variable component of the sum signal disappears. This is how a second feedback loop is formed. To stabilize the sensitivity (conversion factor) of the entire device, it is necessary to stabilize the constant component of the signal. For this on

038

The inputs of the differential amplifier 18 are supplied with a CONSTANT component of the total signal and a reference voltage from source 20. The difference between these voltages, after amplification, goes to the control input of the photocurrent amplifier 14 and changes its transmission coefficient until the condition of equality of the reference voltage and constant component is met. total signal. This forms a third feedback loop. The simultaneous operation of three feedback loops eliminates current measurement errors, which

They are characteristic of the well-known appliance 21 and are due to the fact that the mixer does not have two radiation fluxes.

The proposed device is universal, allowing it to be used at various operating voltages without changing the design of the main components. With an increase in operating voltage, it is only necessary to increase the length of the optical fibers 6.7,

11 and 12, therefore, the cost, size, and reliability of the device are practically independent of the operating voltage.

Claims (1)

DEVICE FOR NON-CONTACT MEASUREMENT OF THE CURRENT POWER, containing on the high potential side a polarizer installed in series along the light rays, a current transducer in the angle of rotation of the plane of polarization and a two-beam analyzer, and on the low potential side the first and second radiation sources coupled to two individual fiber optical fibers, the first of which is connected to the first input of the polarizer with the other end, a modulation frequency generator, whose first output is soy? dinene with one of the control inputs of the second radiation source, two photodetectors optically coupled through the third and fourth fiber optic fibers with the outputs of the two-beam analyzer, two photocurrent amplifiers with adjustable transmission coefficients, the signal inputs of which are connected to the outputs of the respective photodetectors, a summing unit and a subtraction unit, inputs which are connected to the outputs of the photocurrent amplifiers, the first differential amplifier, one of the inputs of which is connected to the zero potential bus, and the output is with a control m input of one of the amplifiers of the photocurrent, the second differential? an amplifier, one of whose inputs is connected to the output of the reference voltage source, and the output to the control, the input of another photocurrent amplifier, the first selective amplifier, the input of which is connected to the output of the subtraction unit, the first synchronous detector, one of the inputs of which is connected SS to the output of the first selective amplifier, and another input to the second output of the modulation frequency generator, a low-pass filter and a recording device, characterized in that, in order to improve the measurement accuracy, a third differential the first amplifier, the second selective amplifier and the second synchronous detector, and the polarizer is made in the form of a two-beam prism, moreover, one of the inputs of the third differential amplifier is connected to the zero potential bus, the other input to the output of the second synchronous detector, and the output to the other control input of the second source radiation, the output of the summing unit is connected to the input of the second selective amplifier and another input of the second differential amplifier, the output of the subtraction unit through a low-pass filter is connected to another input of the first differential amplifier, one of the inputs of the second synchronous detector is connected to the output of the second selective amplifier, and the other input is to the second output of the modulation frequency generator connected to the control input of the first radiation source, the other end of the second fiber waveguide is connected to the second input of the polarizer, and the input the recording device is connected to the output of the first synchronous detector.