RU72797U1 - DEVICE FOR CONTROL OF INSULATION OF ELECTRICAL SYSTEMS - Google Patents

Abstract

The utility model relates to the field of electrical engineering and can be used to protect direct current electrical installations with insulated wires from the earth from emergency conditions.

The purpose of the model is to create a device of electrical systems having high measurement accuracy by reducing the influence of capacitive load resistance on the measured readings of the leakage current, reducing the number of elements in the measuring unit and increasing electrical safety.

The device comprises a network generator, an accession unit with a differential circuit breaker, a valve protection unit, a blocking device made on the basis of an oscillating circuit, a rectifier, an actuating element and a measuring unit made in the form of a relay shunted by a capacitor. The network generator is connected in series with the load through the connection unit and the valve protection unit. The input of the blocking block is connected to the output of the block of attachment. The rectifier input is connected to the output of the blocking unit, and the rectifier output is connected to the input of a non-industrial frequency generator. The input of the actuating element is connected to the output of the connection unit, and the inputs of the measuring unit are connected to the outputs of the rectifier.

Description

The utility model relates to the field of electrical engineering and can be used to protect direct current electrical installations with insulated wires from the earth from emergency conditions.

A device for monitoring the insulation of electrical installations with non-industrial frequency currents, based on the imposition of high frequency currents on the currents of a controlled network [1]. The device comprises a network generator, an attachment unit, a high frequency generator and a measuring device. The connection unit has two isolation capacitors connected in parallel. The DC network generator is connected via a connection unit to a load having a significant capacity. The high-frequency generator is connected with one output through isolation capacitors located in the unit for connecting to the load wires, and the other through the measuring device to the ground.

The device operates as follows. The current from the network generator and current from the high-frequency generator are supplied to the isolation capacitors of the connection unit. In the connection unit, currents are superimposed and supplied to the ground. In this case, most of the current passes through the capacitance of the earth load. After the load, the resulting current flows to the measuring device.

In normal operation, the insulation resistance of the load matters within the established standards. In this case, the measuring device shows the magnitude of the leakage current within the established standards. In emergency operation, the load insulation resistance decreases and the measuring device shows a leakage current exceeding the established norms, which corresponds to the emergency state of the monitored network.

The disadvantage of this solution is the low reliability of measuring the leakage current due to the significant influence of the capacitance of the load. Moreover, the measured readings are distorted by the magnitude of the leakage current, and the larger the leakage current, the greater the measurement error, which affects the accuracy. The error of the measured current is from 5-10 mA.

The closest in technical essence and the achieved result is a device for monitoring the insulation of electrical installations at constant current [2]., Based on the use of the method of receiving the signal, filtering it and detecting from the measured leakage current in a controlled load network. In this case, the leakage current is obtained by superimposing a current from the non-industrial frequency generator on the controlled network.

The device comprises a network generator, a unit for connecting to a load, a non-industrial frequency current generator, and a measuring unit.

The unit for connecting to the load contains: two isolation capacitors, which are connected to the network generator by their inputs, and connected to the input of the non-industrial frequency current generator by their combined outputs.

The network generator through the connection unit is connected to the load, the output of which is connected to ground.

The non-industrial frequency current generator is connected to ground by its output.

The measuring unit includes a current sensor, which is the input of the measuring unit, two switches, a filter, a detector, an information processing unit, an impedance, the output of which is the output of the unit.

The primary winding of the current sensor covers the load wires, and the secondary winding with its output is connected to the input of the first switch, one of the outputs of the controlled network is connected to the input of the second switch. The first output of the first switch is connected to

the input of the filter, the output of which is connected to the first input of the detector, the second input of which receives current from a non-industrial frequency generator. The second output of the first switch is connected to the second input of the information processing unit.

The detector output is connected to the first input of the information processing unit.

The third input of the information processing circuitry is connected to the first output of the second switch, the second output of which is connected to an impedance input representing resistive-capacitance resistance, the output of which is connected to ground.

The device operates as follows.

The current of the generator of a non-industrial network flowing to the ground through the load conductors is controlled by a current sensor. The current flows to the information processing unit in parallel through the first switch and the detector filter. In turn, the current from the non-industrial frequency generator also flows to the information processing unit. The current from the conductors of the controlled network also enters the information processing unit through a second switch connected to the impedance. The resulting current from the information processing unit is supplied to the display unit.

The non-industrial frequency generator current flowing to the ground via the load conductors is controlled by a current sensor located in the measuring unit.

In the first case, the leakage current is measured without connecting an impedance. In the second case, the leakage current in a controlled load network is measured with impedance using a second switch.

As a result of alternating two measurements with and without impedance, the calculated value of the network insulation resistance from known impedance values is obtained. Moreover, the measurement error has

place due to a significant number of elements in the measuring unit, having their own errors ..

In normal operation, i.e. in the presence of load insulation resistance within the established standards, the display circuit in the measuring unit shows the value of the resulting load current corresponding to the established standards.

In emergency mode, i.e. when the insulation resistance decreases below the established norms, the resulting current increases above the established norms, information on the value of the load insulation resistance exceeding the technical requirements is fed to the display circuit.

The known solution allows the measurement of the insulation resistance of the load with a certain degree of accuracy, due to the introduction of impedance into the measuring circuit.

However, it has insufficient accuracy, this is due to the fact that due to the influence of capacitance of the load and the error of a significant number of elements located in the measuring unit, the error in measuring the leakage current is 2 -5 mA.

The purpose of the utility model is to create a device of electrical systems that has high measurement accuracy by reducing the influence of capacitive load resistance on the measured readings of the leakage current, reducing the number of elements in the measuring unit and increasing electrical safety.

To solve the problem in a known device for monitoring the insulation of electrical systems containing a network generator, a connection unit, a load, a non-industrial frequency current generator and a measuring unit, while the network generator is connected in parallel through a load connection unit, the connection unit is additionally equipped with a differential machine, in parallel connected to

to the network generator, as well as additionally installed a valve protection unit, the input of which is connected to the third and fourth output of the connection unit, and the output is loaded, a blocking unit based on an oscillating circuit, the input of which is connected to the fifth output of the connection unit, a rectifier, the first input of which is connected to the output of the blocking block, and the second input to the input of the non-industrial frequency generator, an actuating element including a trip coil of the differential automaton connected to the first and second outputs and attachment unit and the measuring unit is designed as a switch shunted by a capacitor, and connected by their inputs to the outputs of the rectifier.

Thanks to the distinctive features, the accuracy of current measurement and electrical safety are increased. This is due to a decrease in the capacitance of the load current due to the blocking unit. Moreover, the capacitance of the leakage current due to the valve protection unit has little effect on the load resistance, which leads to an increase in the accuracy of measuring the leakage current.

In FIG. a diagram of a device for monitoring the insulation of electrical systems is presented.

A device for monitoring the insulation of electrical systems contains a network generator I, a connection unit 2, a load 4, a valve protection unit 3, a non-industrial frequency current generator 5, a rectifier 6 made according to the bridge circuit, a blocking unit 7, a measuring unit 8, an actuator 9.

The accession unit 2 connected to the valve protection unit 3 and the load 4 contains a differential automaton 10 connected in series with isolation capacitors 11. The inputs of the differential automaton 10 are the inputs of the accession unit 2. Two outputs of the differential automaton 10 are two outputs

the connection unit 2, the first and second outputs of the differential machine 10 are the third and fourth output of the connection unit 2, and the output of the isolation capacitors II is its fifth output.

The measuring unit 8 is a relay 12, shunted by the capacitor 13. The input of the relay 12 is the input of the measuring unit 8, and the output of the relay 12 is its output.

The actuating element 9 is a trip coil 14 of the differential machine 10 with the closing contact 15. The input of the coil 14 is the input of the actuating element 9, and the output of the contact 15 is its output.

The blocking block 7 is an oscillating circuit 16. The input and output of the oscillating circuit 16 is the input and output of the blocking block

Two outputs of the generator of the network I are connected to the inputs of the connection unit 2, the first and second outputs of which are connected to the inputs of the valve protection 3, the outputs of which are connected to the load 4, the Third, fourth and fifth outputs of the connection unit 2 are connected to the inputs of the actuating element 9 and the blocking unit 7 .

One output of the non-industrial frequency current generator is connected to the first input of the rectifier 6, and the second output to ground.

The PN-140 generator was chosen as the generator of network I, the valve protection unit 3 is equipped with VK-200 power diodes, the non-industrial frequency current generator 5 is AD-20M, and the rectifier is 6 with D226D rectifiers. In the connection block, a PMV differential machine and a KBG-MP 600V type capacitor are used. In the blocking unit 7, the dr-600 choke and the KBG-400V capacitor are used. As the actuating element 9 used coil PMV starter. In the measuring unit 8, a relay of the RCP and a milliammeter M2001-24 are used.

The device operates as follows.

The current of the generator of the network I is supplied to the differential machine 10 of the accession unit 2 and then to the valve protection unit 3 and to the load 4. At the same time, the current of the generator of non-industrial frequency 5 is supplied to the load 4 through the rectifier 6, the blocking block 7, the isolation capacitor 11 of the connection unit 2, the block valve protection 3 and further to the ground, which is the main path. In the accession unit 2, the currents from the generator of the network I and non-industrial frequency 5 are superimposed and the resulting leakage current, which controls pin 15, is supplied to the relay 12 of the measuring unit-8. In addition, the current from the generator of the network I enters through the differential machine 10 of the accession unit 2 to the trip coil 14 of the actuator 8.

In normal operation, i.e. in the presence of insulation resistance within the established standards, the load current 4 has an acceptable value, and the resulting current is insufficient to close contact 15 of the relay 12 of the measuring unit R. Moreover, the contact 15 of the actuating element 9 is in the off state. The currents from the generators of the network and non-industrial frequency 1.5 continue to flow to the load 4. The measuring unit 8 shows the leakage rate of the resulting load current 4 corresponding to the technical standards.

In emergency mode, i.e. when the insulation resistance of the load 4 is lower than the established norms, the resulting current increases above the permissible values and turns on the contact 15 of the relay 12 of the measuring unit 8, which shows the leakage value of the resulting load current 4 of the controlled network, "exceeding the technical standards.

In this case, contact 15 of the relay 12 is turned on and a current is supplied to the disconnecting coil 14 of the actuating element 9, which disconnects the current of the network generator 1 through the differential machine 10 of the connection unit 2. from the load 4. At the same time, the valve protection unit 3

disconnects load 4 from the monitored network. The current from the non-industrial frequency generator 5 continues to flow to the monitored network along the second path with no capacitive load 4.

Using the utility model shows that the measurement error decreases to 0.5-1 mA, which indicates a 4-fold increase in measurement accuracy compared to the prototype.

Sources of information taken into account

1. Tsapenko E.F. insulation control in networks up to 1000 V / E.F. Tsapenko. M .; Energy. 1972. - 137 p.

2. Patent No. 2275645, IPC G01R 27/08, (G01R 27/08 31/02. Method, measurement of insulation resistance of connections in branched DC and AC networks and a device for its implementation. / Kislov EA, etc. - .№2004117696 / 23. Declaration of 10.06.2004. Publish. 20.11.2005. Bull. No. 35.

Claims (1)

The device for monitoring the insulation of electrical systems contains a network generator, an accession unit, a load, a non-industrial frequency current generator and a measuring unit, while the network generator is connected in parallel through a load connection unit, characterized in that the connection unit is additionally equipped with a differential machine connected in parallel with the generator network, and in addition, a valve protection unit is installed, the input of which is connected to the third and fourth output of the connection unit, and the output is with a load, for an oscillating unit based on an oscillatory circuit, the input of which is connected to the fifth output of the attachment unit, a rectifier, the first input of which is connected to the output of the blocking unit, and the second input is to the input of the non-industrial frequency generator, an actuating element including a differential coil disconnecting coil connected to the first and the second outputs of the connection unit, and the measuring unit is made in the form of a relay, shunted by a capacitor, and connected by its inputs to the outputs of the rectifier.