SU834604A1 - Method of continuous measuring of insulation of ac circuits containing static converters - Google Patents

Description

The invention relates to measuring equipment, in particular to methods for measuring the insulation resistance of electrical networks containing static converters.

A known method of measuring the insulation resistance of electrical AC networks, used in the device ’’ Electron, based on the fact that a constant voltage is applied to the insulation and the magnitude of the current in the circuit of the measuring voltage source determines the value of the insulation resistance EP.

The disadvantage of this method is the impossibility of measuring the insulation resistance in alternating current electric networks containing static converters, which is due to the presence of an additional constant voltage component on the insulation of such networks, the magnitude and sign of which depend on the compensation ratio, at which there is no current in the measuring circuit, and in another - measurement of insulation resistance with connected measuring and compensation sources, moreover, ₅ the compensation voltage is equal to the value, set updated in the previous time interval. If during the cycle a change in the insulation resistance of the circuits or poles occurs (for example, 10 when connecting or disconnecting consumers with a reduced insulation resistance), the measurement result is incorrect.

The purpose of the invention is to increase the accuracy of the measurement by eliminating the time shift between compensation and measurement.

This goal is achieved by the fact that in the method of continuous measurement 20 of the insulation resistance of AC electric networks containing static converters, which consists in compensating for the DC component of the voltage between the 25th phase of the network and the housing (. Ground), then the measuring DC voltage is applied and determined the value of insulation resistance by the value of the DC component of the current in the measuring circuit; compensation is made continuously, directly in the process of measurement, for which ydelyayut first and second harmonic voltage insulation, determine the amplitude and the initial phase is 35 second-harmonic voltage insulation, wherein the amplitude of the second harmonic determine the magnitude of the compensating voltage and the initial phase - the polarity 40 of the compensating voltage.

The essence of the proposed method lies in the fact that, as can be seen from expression (1), the amplitude of the second harmonic of the voltage on the insulation is proportional to -45 flax of the DC component of the voltage, due to the presence of rectifier elements in the controlled network, and its initial phase with one sign of the DC component is not - 50 differs from the initial phase with the opposite sign of the constant component by 180 °.

X _v V

R ~ ^{+ R} = '

Jr

IL

C0S2 twit ..., (Ί) where R * ~ ^con P ° ^TIiB_

2- insulation of alternating current circuits;

insulation resistance of direct current circuits;

V is the line voltage of the network (amplitude value).

The drawing 'shows one of the variants of the device that implements the proposed method.

• The device for continuous measurement of insulation resistance contains a block I for isolating the second harmonic of the voltage across the insulation, block 2 for determining the amplitude of the second harmonic of the voltage across the insulation, block 3 for determining the initial phase of the second harmonic of the voltage across the insulation, block 4 defining the value of the compensating voltage, block 5 defining the polarity compensating voltage, measuring unit 6, compensation unit 7, source 8 of the measuring voltage, threshold unit 9 and signaling device Yu.

The device operates as follows.

Using block I, the alternating component of the voltage across the insulation is extracted, from which the first and second harmonics of this voltage are separated, the second harmonic is fed to the input of block 2. A signal proportional to the amplitude of the second harmonic is fed to the input of block 4. At the same time, the first and second harmonics are fed to the input of block 3, where the angle of shift of the initial phase of the second harmonic is determined with respect to the initial phase of the first harmonic. A signal proportional to the phase angle is fed to the input of block 5. Blocks 4 and 5 act on the compensation block 7 to create a current in the measuring circuit that is equal in magnitude and opposite in direction of current due to the presence of rectifier elements in the controlled network.

Thus, the measuring voltage source 8 creates a current in the measuring circuit inversely proportional to the value of the insulation resistance. The measuring unit 6 serves to directly determine the insulation resistance. The signal j is proportional to the current value in the measuring circuit, is fed to the input of the threshold unit 9, which only responds to the current value corresponding to the value of the insulation resistance below the permissible norm, activating the signaling device 10.

Claims (2)

(54) METHOD FOR CONTINUOUS MEASUREMENT OF THE RESISTANCE OF THE INSULATION OF ELECTRIC CURRENT ACCESSORIES CONTAINING STATIC PENSORS, in which the current in the measuring circuit is absent, and in the other - the measurement of insulation resistance with the help of workout kits and compensation kits and compensation kits, which will be used to compensate for the use of workout kits and compensation kits. time interval. If during the cycle time there is a change in the insulation resistance of the circuits or poles (for example, when consumers with low insulation resistance are connected or disconnected), the measurement result is incorrect. The purpose of the invention is to improve the measurement accuracy by eliminating the time shift between compensation and measurement. The goal is achieved by the method of continuous measurement of the insulation resistance of electrical AC networks containing static converters, which compensate the constant component of the voltage between the phase of the network and the housing ground), then apply the measuring voltage of direct current and determine the value of the insulation resistance by the magnitude of the constant component of the current in the measuring circuit, the compensation is performed continuously, directly into the measurement process, for which The first and second harmonics of the voltage on the insulation are determined, the amplitude and the initial phase of the second harmonic of the voltage on the insulation are determined, and the magnitude of the second harmonic determines the value of the compensating voltage, and the initial phase - the polarity of the compensating voltage . The essence of the proposed method is that, as can be seen from expression (l), the amplitude of the second harmonic voltage on the insulation is proportional to the constant component voltage due to the presence of rectifier elements in the monitored network. the phase at one sign of the constant component does not differ from the initial phase at the opposite sign of the constant component by 180.. and COS 2 CWit ... where .R, fU (TT O resistance 2. Cd lien of insulation, AC circuit; R..R., R- () is the resistance of the insulation of the DC circuit; V is the line voltage of the network (amplitude value). The drawing shows one of the variants of the device that implements the proposed method. The device for continuous measurement of the insulation resistance contains a block 1 for isolating the second harmonic of the voltage of an insulation, block 2 for determining the amplitude of the second harmonic of voltage isolation unit 3 determining the initial phase of the second harmonic voltage on the isolator and, block 4, setting the value of the compensating voltage, block 5, setting the polarity of the compensating voltage, measuring unit 6, compensation unit 7, measuring source 8, threshold unit 9 and alarm device 10. The device operates as follows. 1, the variable component of the isolation voltage is extracted, from which the first and second harmonics of this voltage are extracted, the second harmonic is fed to the input of block 2. A signal proportional to the amplitude of the second harmonic is fed to the input of block 4. O neous first and second harmonic are input to the block 3 where it is determined angle shift of the initial phase of the second harmonic relative to the initial phase of the first harmonic. The signal proportional to the phase shift angle is fed to the input of block 5. Blocks 4 and 5 act on compensation block 7 to create a current in the measuring circuit that is equal in magnitude and opposite in direction of current due to the rectifying elements in the monitored network. Thus, the measuring voltage source 8 generates a current in the measuring circuit that is inversely proportional to the insulation resistance value. The measuring unit 6 serves to directly determine the insulation resistance. The signal j proportional to the current value in the measuring circuit enters the input of the threshold unit 9, which responds only to the current value corresponding to the insulation resistance value below the permissible norm, actuated by the warning device 10. Invention Method A method of continuous measurement of the insulation resistance of electrical AC networks containing static transducers, which consists in compensating the constant component of the voltage between the mains phase and the housing (Zempei), then measuring direct current voltage and determine the value of the insulation resistance by the magnitude of the constant component of the measuring circuit, characterized in that, in order to improve the measurement accuracy by eliminating the time shift between compensation and measurement, compensation is made continuously, directly the measurement process, for which the first and second harmonics of the isolation voltage are selected, determine the amplitude and initial phase of the second harmonic of the isolation voltage, and determine the amplitude of the second harmonic the value of the compensating voltage, and in the initial phase - the polarity of the compensating voltage. Sources of information taken into account during the examination 1. V.T. Samoylov Automation of shipboard electrical installations. L., Shipbuilding, 1972, p. 159-162. 2. Patent of the GDR No. 129829,. cl. G 01 R 27/18, 08.02.78 (prototype). Rh