RU86807U1 - DEVICE FOR CONTROL OF INSULATION OF ELECTRICAL SYSTEMS - Google Patents

Abstract

A device for monitoring the insulation of electrical systems, containing a network generator, connection unit, load, valve protection unit, non-industrial frequency current generator, a rectifier, a blocking device, a measuring unit, an actuating element, while the network generator is connected to the connection unit with its two outputs, the first and the second outputs of which are connected to the input of the valve protection unit, the output of which is connected to the load, the non-industrial frequency current generator is connected with its output to the input of the rectifier, you the odes of which are connected to the measuring unit, and the third output through the blocking unit is connected to the connection unit, the executive element is connected with its inputs to the third and fourth outputs of the connection unit, and connected to the ground with its output, characterized in that an additional current sensor installed in the connection unit, a triac, a relay and an alarm lamp installed in the actuator, while the current sensor is connected to the controlled network through an isolation capacitor with its input in connection block, and its output is connected to the inputs of the triac and signaling lamps that their outputs are connected to the ground.

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 is known for monitoring the insulation of electrical installations, in which a controlled alternating voltage of a predetermined frequency different from the network frequency is applied to the controlled network. The current in a controlled connection is measured, the captured signal is filtered, and the signal is synchronously detected to determine the leakage current. Then, a calibration resistive-capacitive impedance is connected to a controlled connection and a secondary leakage current is measured when the impedance is connected. Further, the results of two measurements of the leakage current determine the non-stationary value of the transmission coefficient of the measuring path and the value of the insulation resistance of the controlled connection [1]. 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.

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 device operates as follows.

The non-industrial frequency generator current 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 of the non-industrial frequency generator is also supplied 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. In this case, the measurement error takes place due to a significant number of elements in the measuring unit, which have 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 operation, 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 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 closest in technical essence and the achieved result is a device for monitoring the insulation of electrical installations at constant current [2].

The device comprises a network generator, an attachment unit, a load, a valve protection unit, a non-industrial frequency current generator, a rectifier, a blocking device, a measuring unit, an actuating element.

The connection unit connected to the valve protection unit and the load comprises a differential circuit breaker connected in series with isolation capacitors. The inputs of the differential automaton are the inputs of the accession unit. Two outputs of the differential automaton are two outputs of the attachment unit, the first and second outputs of the differential automaton are the third and fourth outputs of the attachment unit, and the output of the isolation capacitors is its fifth output.

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

The actuating element is a tripping coil of a differential machine. The input of the coil is the input of the actuating element, and the output of the contact is its output.

The blocking block is an oscillating circuit, the input and output of which is the input and output of the blocking block.

Two outputs of the network generator are connected to the inputs of the connection unit, the first and second outputs of which are connected to the inputs of the valve protection, the outputs of which are connected to the load. The third, fourth and fifth outputs of the accession unit are connected to the inputs of the actuating element and the blocking unit.

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

The device operates as follows.

The current of the network generator is supplied to the differential machine of the accession unit and then to the valve protection unit and to the load. At the same time, the current of the non-industrial frequency generator is supplied to the load through the rectifier, the blocking block, the isolation capacitor of the connection block, the valve protection block and then to the ground, which is the main path. In the connection unit, the currents from the network generator and non-industrial frequency are superimposed and the resulting leakage current is controlled by the relay contact of the measuring unit. In addition, the current from the network generator is supplied through the differential machine of the accession unit to the disconnecting coil of the actuating element.

In normal operation, i.e. in the presence of insulation resistance within the established norms, the load current has an acceptable value, and the resulting current is insufficient to close the relay contact of the measuring unit. The relay contact of the measuring unit is in the off state. Current from the network generator and non-industrial frequency continue to flow to the load. The measuring unit shows the value of the resulting load current in accordance with technical standards.

In emergency mode, i.e. when the load insulation resistance decreases below the established norms, the resulting current increases above the permissible values and turns on the relay contact of the measuring unit, which shows the leakage value of the resulting load current of the controlled network exceeding the technical standards.

In this case, the relay contact of the measuring unit is turned on and a current is supplied to the disconnecting coil of the actuating element, which disconnects the current of the network generator through the differential circuit breaker of the connection unit from the load. The valve protection block disconnects the load from the monitored network. The current from the non-industrial frequency generator continues to flow to the controlled network along the second path.

A device based on the application of non-industrial frequency voltage to the controlled network from the generator and by introducing a valve protection unit, a blocking device and improving the measuring unit into it increases the measurement accuracy and electrical safety.

The disadvantage of this device is that it does not allow to recognize the type of damage from exposure to thermal radiation from the environment, has a low sensitivity when fixing the response from exposure to thermal radiation from sources of the external environment, the location of damage in a controlled network is not determined.

The objective of the utility model is to create a device for controlling the insulation of electrical systems, which allows one to recognize the type of damage from external sources of thermal radiation, increase sensitivity when exposed to thermal radiation from external sources, and determine the location of damage in the controlled network.

To solve this problem in a known device for monitoring the insulation of electrical systems containing a network generator, connection unit, load, valve protection unit, non-industrial frequency current generator, rectifier, blocking device, measuring unit, actuator, while the network generator is connected with its two outputs to the connection unit, the first and second outputs of which are connected to the input of the valve protection unit, the output of which is connected to the load, the non-industrial frequency current generator the output is connected to the input of the rectifier, the outputs of which are connected to the measuring unit, and the third output through the blocking unit is connected to the connection unit, the executive element is connected with its inputs to the third and fourth outputs of the connection unit, and its output is connected to ground, an additional current sensor installed in the connection unit, a triac, a relay and an alarm lamp installed in the actuator, while the current sensor is connected with its input to the controlled network through a splitter nye capacitors in connection block, and its output is connected to the inputs of the triac and signaling lamps that their outputs are connected to the ground.

Distinctive features of the proposed solution from the prototype are: a current sensor installed in the connection unit, a triac, a relay, an alarm lamp, while the current sensor is connected to the controlled network through isolation capacitors in the connection unit, and connected to the inputs of the triac and lamp by its output alarms that are connected to ground with their outputs.

Thanks to the distinguishing features, the claimed solution allows you to recognize the type of damage, increase the sensitivity of the device to the response from external sources of thermal radiation and determine the location of damage in a controlled network at the location of the current sensor. This is due to the fact that when an external source of thermal radiation acts on the current sensor, the signal of which is transmitted to the triac and then to the relay, which closes the contact to the disconnect coil of the differential machine that disconnects the mains generator from the load.

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

A device for monitoring the insulation of electrical systems contains a network generator 1, an accession unit 2, a valve protection unit 3, a load 4, a non-industrial frequency current generator 5, a rectifier 6 made in a bridge circuit, a blocking device 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 the isolation capacitors 11 and in parallel with the isolation capacitors 12. the inputs of the differential automaton 10 are two outputs of the accession unit 2, the first and second outputs of the differential automaton 10 the third and fourth output of the accession unit 2, and the output of the isolation capacitors 11 - its fifth output. The sixth output of the accession unit 2 is the output of the current sensor 13, the input of which is connected to the combined outputs of the isolation capacitors 12.

The blocking block 7 is an oscillating circuit 14, the input and output of the oscillating circuit 14 are the input and output of the blocking block.

The measuring unit 8 is a relay 15 shunted by the capacitor 16. the input of the relay 15 is the input of the measuring unit 8, and the output of the relay 15 is its output.

The actuator 9 is a trip coil 17 of a differential automaton 10, a triac 18, the output of which is connected to the input of the relay 19, the output of which is connected to ground, a signal lamp 20, the input of which is connected to the output of the current sensor 13 in parallel with the input of the semistor, and the output is connected to ground. The input of the coil 17 is the input of the actuator 9, and the output of the combined contacts 21, 22 is its one output, the other output is the input of the triac 18 and the signal lamp 20 interconnected. Another output of the accession unit 9 is the combined output of the relay 19 and the signal lamp 20 connected to ground.

Two outputs of the network generator 1 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 unit 3, the outputs of which are connected to the load 4. the third, fourth, fifth and sixth outputs of the connection unit 2 are connected to the inputs of the actuator 9 and barrage block 7.

The PN-140 generator was chosen as the generator of network 1, the valve protection unit 3 is equipped with VK-200 power diodes, the non-industrial frequency current generator 5 is AD-20M, the rectifier 6 is equipped with D226D diodes.

In accession block 2, a PMV differential machine and KBG-MP 600V type capacitors, a current sensor of the DPS type were used. In the blocking unit 7, the dr-600 choke and the KBG-400V capacitor are used. As the actuating element 9, the coil 17 of the PMV starter was used, the ILV relay was used. In measuring unit 8, a RES64A relay with a switching current of 1.2-1.3 mA and a milliammeter M2001-24 are used.

The device operates as follows.

In the absence of the influence of thermal radiation from external sources on the monitored network, the current of the generator of the network 1 is supplied to the differential machine 10 of the connection unit 2 and then to the valve protection unit 3 and load 4. simultaneously, the current of the generator of non-industrial frequency 5 is supplied to load 4 through the rectifier 6, the blocking block 7, isolation capacitors 11, 12 of the accession unit 2, the valve protection unit 3, the load 4 and further to the ground, which is the main path. In the connection unit 2, the currents from the generator of the network 1 and the generator of non-industrial frequency 5 are superimposed and the resulting leakage current, which controls the contacts 21, 22, is supplied to the relay 15 of the measuring unit 8. In addition, the current from the generator of the network 1 is supplied through the differential machine 10 of the connection unit 2 to the trip coil 17 of the actuating element 9.

In normal operation, i.e. if there is insulation resistance within the established norms, the load current 4 has an acceptable value, and the resulting current is insufficient to close the contact 21 of the relay 15 of the measuring unit 7. while the contacts 21, 22 of the actuating element 9 are in the off state. The currents from the network generator 1 and the non-industrial frequency generator 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. The current sensor 13 in the accession unit 2, the triac 18 in the actuating element 9 are closed, the signal lamp 20 is not lit.

In emergency mode, i.e. when the insulation resistance of the load 4 is reduced below the established norms, the resulting current increases above the permissible value and turns on the contact 21 of the relay 15 of the measuring unit 8, which shows the leakage of the resulting current load 4 of the monitored network, exceeding the technical standards. In this case, contact 21 of the relay 15 is turned on and a current is supplied to the disconnecting coil 17 of the actuator 9, which disconnects the current of the network generator 1 through the differential machine 10 of the connection unit 2 from the load 4. The valve protection unit 3 disconnects the load 4 from the controlled network. The current from the non-industrial frequency generator 5 continues to flow to the controlled network along the second path.

When thermal radiation from an external source affects the controlled network, the current sensor 13 in the connection unit 2 opens and the current from the non-industrial frequency generator 5 is fed to the input of the triac 18 and the signal lamp 20, while the triac opens the output of which is connected to the input of the relay 19 and the generator current circuit non-industrial frequency closes to the ground. Next, the contact 22 of the relay 19 is turned on, which is also involved in the supply of current to the trip coil 17 of the differential machine 10. The signal lamp 20 is on and continues to light after the generator 1 is disconnected from load 4, which indicates the process of recognizing the type of damage. In this case, the response sensitivity of the insulation control device of electrical systems is significantly increased.

At the same time, it is possible to find the place of damage in the monitored network when it is disconnected from the network generator 1, since the current from the non-industrial frequency generator 5 arrives, regardless of the state of the monitored network, to the triac 18, relay 19 and signal lamp 2-, which will be located all the time during the search in the on state. The place of damage is found at the location of the current sensor 13 in the controlled network.

Sources of information taken into account

1. Patent No. 2275645, IPC G01R 27/08, (G-01R 27/08 31/02. Method, measuring the insulation resistance of connections in branched DC and AC networks and a device for its implementation. / Kislov EA, etc. .-. No. 2004117696/23. Declared June 10, 2004. Published on November 20, 2005. Bull.

2. Patent No. 72797, IPC Н02Н 3/17, Device for insulation control of electrical systems. / Balyuk A.A., Borzeev I.Ya. - No. 2007147759. declared 12/20/2007. Published on April 27, 2008. Bull. Number 32.

Claims (1)

A device for monitoring the insulation of electrical systems, containing a network generator, connection unit, load, valve protection unit, non-industrial frequency current generator, a rectifier, a blocking device, a measuring unit, an actuating element, while the network generator is connected to the connection unit with its two outputs, the first and the second outputs of which are connected to the input of the valve protection unit, the output of which is connected to the load, the non-industrial frequency current generator is connected with its output to the input of the rectifier, you the odes of which are connected to the measuring unit, and the third output through the blocking unit is connected to the connection unit, the executive element is connected with its inputs to the third and fourth outputs of the connection unit, and connected to the ground with its output, characterized in that an additional current sensor installed in the connection unit, a triac, a relay and an alarm lamp installed in the actuator, while the current sensor is connected to the controlled network through an isolation capacitor with its input in connection block, and its output is connected to the inputs of the triac and signaling lamps that their outputs are connected to the ground.