SU1566313A1 - Device for checking condition of insulation of electric equipment - Google Patents

Abstract

The invention relates to electrical measuring equipment and is intended to ensure the safety of operation of electrical installations of consumers due to continuous indirect contactless control of leakage current as the difference between the input and output currents of electrical equipment. The purpose of the invention is to expand the scope of use and improve the accuracy of control. This is achieved by eliminating the multiplicative component of the error in monitoring the leakage current as the difference between the input and output currents of electrical equipment. The exception of the multiplicative component of the error is achieved by the differential inclusion of two differential magnetic modulators. The device contains a power source 1, an external tubular current conductor 2, an internal tubular current conductor 3, first 4 and second 5 differential magnetic modulators, field windings 6, 7 of the first differential magnetic modulator, field windings 8, 9 of the second differential magnetic modulator, output winding 10 of the first differential magnetic modulator, the output winding 11 of the second differential magnetic modulator, electrical equipment 12, excitation generator 13, selective amplifier 14, detector 15, unit 1 6, the information comparator 17, the driver 18 of the control signal of the protective tripping unit. The device is characterized by an increased accuracy of control at high load carrying currents. 2 Il.

Description

one

(21) 4475411 / 24-21

(22) 08/18/88

(46) 05.23.90. Bul No. 19

(71) All-Union Scientific Research Institute of Electrical Instruments

(72) E.A. Bel ev

(53) 621.317.799 (088.8)

(56) Semenov N.M., Yakovlev N.I. Digital fluxgate magnetometers. L .: Energie, 1978, p. 131

Patent of Germany No. 2124178, cl. H 01 H 3/16, 1971.

(54) DEVICE OF INSULATION CONTROL CONTROL ELECTRIC EQUIPMENT

(57) The invention relates to electrical measuring equipment and is intended to ensure the safety of operation of electrical installations of consumers due to continuous indirect contactless control of leakage current as the difference between the input and output currents of electrical equipment. The purpose of the invention is to expand the field of use and improve the accuracy of control. This is achieved by eliminating the multiplicative component of the error in monitoring the leakage current as the difference between the input and output currents of electrical equipment. The exception of the multiplicative component of the error is achieved by the differential inclusion of two differential magnetic modulators. The device contains a power source 1, an external tubular current conductor 2, an internal tubular current conductor 3, the first 4 and second 5 differential magnetic modulators, windings 6, 7 of the excitation of the first differentiation of the external magnetic modulator, the winding I, and the excitation of the second differential magnetic modulus Torah. winding 10 of the first differential magnetic modulator, output winding 11 of the second differential magnetic modulator, electrical equipment 12, generator 13 energized HP, selective amplifier 14, detector 15, information providing unit 16, comparator 17, protective tripping unit control signal generator 13. The device is characterized by an increased accuracy of control at high load carrying currents.

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The invention relates to electrical measuring equipment and is intended to ensure the safety of operation of electrical installations of consumers due to continuous indirect contactless control of leakage current as the difference between the input and output currents of electrical equipment.

The purpose of the invention is to expand the scope of use and improve the accuracy of control.

FIG. Figure 1 shows a block diagram of a device with conditional spacing of modulator cores; in fig. 2 is an example of a possible implementation of the device providing independent adjustment of the elements of the magnetic converter and current leads.

The device contains a power supply 1, an external tubular current conductor 2, an internal tubular current conductor 3, a first differential magnetic modulator 4, a second differential magnetic modulator 5, excitation windings 6 and 7 of the first modulator, excitation windings 8 and 9 of the second modulator, output winding 10 of the first modulator, the output winding 11 of the second modulator, electrical equipment 12, excitation generator 13, selective amplifier 14, detector 15, information display unit 16, comparator 17, blaster control signal generator 18 ka BREAKERS. The first output of power supply 1 is connected to an external tubular conductor 2, and the second output is connected to an internal tubular conductor 3, the second output of which is connected to the first input of electrical equipment 12, the second input of which is connected to the second output of an external tubular conductor 2, The windings of the first 6, 7 and second 8, 9 differential magnetic modulators 4 and 5 are interconnected in series, and their extreme leads are connected to the first and second outputs of the excitation generator 13, the output windings 10 and 11 of the first and second di differential magnetic modulators connected in series and in opposition, and their free terminals are connected to the inputs of the selective amplifier 14, whose output is connected to the input of detector 15, whose output is connected to the first input unit 16

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the information output and the input of the comparator 17, the first output of which is connected to the second input of the information representation unit 16, the second output of the comparator 17 is connected to the input of the control signal generator 18 of the protective tripping unit whose output is the output of the device.

The operation of the device is as follows.

Magnetic modulators 4 and 5 are oriented with respect to external magnetic fields (interference) H. Orientation is performed with the device fully turned on, but in the absence of a load current in conductors 2 and 3, the informative signal in the information display unit 16 is minimized. The excitation generator 13 generates alternating periodic pulses with a frequency f with an amplitude sufficient to provide a significant oversaturation of the cores of the modulators 4 and 5 during the passage of pulses through the windings 6 and 7, 8 and 9. In this case, each of the modulators operates as a ferrosonde, sensitive to all external constant and low-varying magnetic fields compared to the frequency Ј0. The task of preliminary orientation is to find such a spatial arrangement of modulators 4 and 5, when ormativny signal output circuit, common to both the modulator is minimal. The counter-switching of the outputs of each of the modulators in the common circuit ensures an almost zero level of the output signal of interference. The dependence of the output signal of each and of the modulators on the spatial location with respect to the prevailing magnetic field is explained primarily by the anisotropy of the magnetic properties of the cores and the nonidentity of the excitation windings of the cores, as well as the asymmetry of the output winding of the modulator. In practice, the orientation of the modulators is carried out by alternately rotating them around their own axes until the minimum reading of the indicator is obtained in block 16 of the information representation.

With a sufficiently good identity of modulators 4 and 5, an almost zero deviation can be achieved, which

51

subsequently determines the possibility of measuring small values of leakage current. In this position, the modulators 4 and 5 are fixed with structural fasteners (not shown in Fig. 2) on the board 19. The fasteners and the board 19 themselves must be made of magnetic dielectrics. Additionally, a board with modulators can be moved to a magnetic screen, which increases the potential for measuring the entire device under conditions of significant voltage field strengths. The entire system as a whole has a much lower threshold of sensitivity than a separate modulator, and at the same time the influence of destabilizing factors, such as frequency i0 instability, drift zero of an individual modulator, temperature drift, etc., decreases.

The magnetic fields of the conductors 2 and 3 are oriented in relation to the integration circuit of the modulator 4 "The same current of the maximum possible value for a given cross section of the conductors is passed through the conductors 2 and 3 in opposite directions. By alternately turning and, if necessary, by a slight displacement, the conductors 2 and 3 in the window of the modulator 4 relative to its geometrical axis achieve the return of the indicator readings in block 16 to the zero level. The positions of the conductors 2 and 3 are fixed, for example, by means of pins or screws in fastening assemblies 20. In this case, the conductors 2 and 3 independently and in each case have an optimal position in which the magnetic fields of the current flowing through the conductors opposite directions, mutually compensated at almost every point of the integrator circuit of the modulator 4, thus eliminating the methodical multiplicative error of the whole DTT-DN converter, maintaining the sensitivity threshold reached by the introduction of a modulator 5 into the device, to very large values of the compared currents. The magnetic transducer is ready for operation.

When low-voltage power (battery) is turned on, for example, trolley

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The bead, from which all machine control devices operate, is simultaneously supplied with power to the isolation control device. The generator 13 starts producing current pulses with a frequency f0, entering the windings 6, 7 and 8, 9 of the excitation, modulators 4 and 5, respectively, driving their cores to a state characterized by alternating magnetization to saturation and higher. The emf in the output circuit of the modulators 4 and 5, formed by the output windings 10 and 11, in the absence of a magnetic field acting on the modulator 4, contains almost no even harmonics of the excitation signal, i.e. Ezf0 0. When power equipment 12 is connected to the power supply network, a part of the input current branches along the leakage current path. If the insulation resistance is greater than the allowable, then the leakage current and, accordingly, the difference in current in the modulator unit's electrical circuits are in the dead zone of the modulator 4. That is, it does not cause any noticeable change E., which could be fixed using the selective amplifier 14, the de-detector 15 and the indicator in the information representation unit 16. The meter indicates no leakage current.

If the insulation deteriorates and the leakage current increases and the current difference in the conductors 2 and 3 is proportional to it, the magnetic field strength grows surrounded by the conductor; that the fsix is in the output winding 10 of the modulator 4 by a linear increase in the amplitude of the second harmonic, and eats its extraction and amplification in the amplifier 14 through the detector 15 is converted into a constant voltage, the amplitude of which is proportional to the leakage current being measured. The indicator readings in block 16, due to the fact that the entire processing path of the informative variable, namely the amplitudes E2f0, is linear, is also proportional to the leakage current. If the leakage current reaches the maximum allowable value, the DC voltage at the detector output reaches the value of the predetermined setpoint voltage applied to the second input of the comparator 17, and the comparator is triggered. At its output, a signal appears providing simultaneous activation of autonomous signaling in information presentation unit 18 and launching the control signal generator 18 of the protective tripping unit, by means of which powerful high-current switching devices can be switched off, disconnecting the source 1 from electrical equipment.

Claims (1)

Invention Formula An electrical equipment isolation control device containing a differential magnetic modulator, made on two ring cores, through the window of which a conductive system passes, connecting the electrical equipment with an external power source and consisting of an external tubular and internal tubular or cylindrical insulated from each other current leads, the longitudinal axes of which are parallel to the axis of the ring cores, the generator of the excitation current of the differential magnetic modulator , the output of the excitation current pulse of the differential magnetic modulator is connected to the first output of the excitation winding of the first differential modulator, the second terminals of the external tubular and internal tubular conductors connected to terminals for connecting a control object, characterized in that, in order to expand areas of use and control accuracy, additionally introduced are a second identical differential magnetic modulator, a selective amplifier detector, comparator, information representation unit, shaper of a control signal of a protective disconnecting unit, second output of a differential excitation current pulse generator the magnetic modulator is connected to the first output of the excitation winding of the second differential magnetic modulator, the second output of which is connected to the second output of the excitation winding of the first differential magnetic modulator, the output windings of the first and second differential magnetic modulators are connected to each other in series and meeting, and free pins connected to the input of the selective amplifier, the output of which is connected to the input of the detector, the output of which is connected to the input of the comparator and the per0 The first input of the information representation unit, the first output of the comparator is connected to the second input of the information presentation unit, the second output of the comparator is connected to the input of a liter of the control signal of the protective shutdown unit. T SC1 v 3