SU1128193A1 - Device for checking electric network insulation resistance - Google Patents

Abstract

1. DEVICE FOR MONITORING THE RESISTANCE OF ELECTRIC NETWORK INSULATION, containing a source of operational voltage, a current sensor, a separation block, and the first threshold unit, characterized in that, in order to enhance the functionality of the device, to ensure constant monitoring of the insulation resistance of disconnected sources and consumers of electricity, a rectifier, an inrush current sensor, a second threshold unit, a logic unit, an artificial zero point unit, a status indicator and w Chains of series-connected capacitors and resistors, with one output of a source of operating voltage through a series-connected current sensor, a dividing unit and an artificial zero point unit connected to a monitored network, and the other output of this source of operating voltage through a series-connected detector and rectifier The measured current is connected to the same input of the artificial zero point block, the current sensor and rectified current sensor outputs are connected to the inputs of the corresponding first and second horny blocks, the outputs of which are connected respectively to the first and second inputs of the logic unit, the output of which is connected to the status indicator, the first terminals of the first, second, third and first terminals of the fourth, fifth and sixth chains of series-connected capacitors and resistors are connected to the moving contacts of the switches of sources and consumers of electricity, respectively, and the second terminals of the first, second, n. the third, as well as the conclusions of the fourth, fifth, and sixth chains of successively connected capacitors and resistors | o) a; cells are fixed to the fixed contacts. switches of sources and consumers of electricity, respectively. 2. A device according to claim 1, wherein the logic block consists of two serially connected keys, the controlled inputs of the first and second keys are the first and second inputs of the logic block, respectively.

Description

The invention relates to electrical engineering. A device for monitoring the insulation resistance of electrical networks is known, which contains a source of operational voltage, a current sensor, a separation unit, a threshold device ij. This device does not allow monitoring the decrease in the insulation resistance of disconnected sources and energy consumers. Closest to the present invention is a device for monitoring the insulation of electrical networks, containing a source of operating voltage, a current sensor, a separation unit, a setpoint 2. . The known device also makes it impossible to control the insulation resistance of disconnected sources and consumers of electricity. The purpose of the invention is to expand the functional possibilities, to ensure simple monitoring of the insulation resistance of disconnected sources and energy consumers. This goal is achieved by the fact that the device containing the operating voltage source, the current sensor, the separation unit and the first threshold unit is additionally introduced with rectifier No. 1tel, the rectified sensor: the current circuit, the second threshold unit, the logic unit, the artificial zero point unit, the indicator states and six circuits of series-connected capacitors and resistors, one output of the operating voltage source through the series-connected current sensor, the separation unit and the artificial zero point unit connected to a monitored network, and the other output of this source of operating voltage is connected via a serially connected sump and a rectified current sensor to the same input of an artificial zero point unit, the current sensor and the high current sensor outputs are connected to the first and second threshold inputs blocks, the outputs of which are connected respectively to the first and second inputs of the logic block, the output of which is connected to the status indicator, the first conclusions of the first, second, third and first outputs of the fourth Oh, pto and shes. The chains of the series-connected cones of the gators and peezistors are connected to the moving contacts of the switches of sources and consumers, respectively, the second terminals of the first, second and third, as well as the terminals of the fourth, fifth and sixth chains of the series-connected capacitors and resistors are connected to the fixed contacts of the switches sources and consumers of electricity, respectively. In addition, the logic block consists of two keys connected in series, the controlled inputs of the first and second The keys are respectively the first and second inputs of the logic block. The drawing shows a block diagram of a device for monitoring the insulation resistance of electrical networks. The device contains an operating voltage source 1, a sensor 2 current, a separation unit 3, a rectifier 4, a sensor 5 high current, a block 6 of an artificial zero point, the first 7 and second 8 threshold blocks 9. logic, a state indicator 10, capacitors 11, resistors .12, and the logic block 9 consists of series-connected switches 13 and 14. The drawing also shows the source 15 of electricity (generator), the consumer 16 of electricity (load), switching equipment (switches) 17, resistances 18-26 and Capacities of 27-35 network phases relate body. One output of source 1 of operating voltage via serially connected current sensor 2, separation unit 3 is connected to the input of unit 6 of an artificial zero point, the second code of source 1 of operational voltage via series-connected rectifier 4 and sensor 5. rectified current is connected to the input unit 6 artificial zero point, the outputs of the sensors 2 and 5 current through the threshold blocks 7 and 8, respectively, are connected with their corresponding inputs of the logic block 9, the output. connected to the input of the 10 status indicator. The outputs of the successively connected capacitors 11 and resistors 12 are connected to movable fixed contacts with a switch of sources and consumers of energy. The device operates as follows. The operational signal is alternating then. At a frequency higher than the industrial one from the first output of the source 1. Operational voltage through the sensor 2 of the current of the incompressible frequency, the separation unit 3, block 6 of the artificial zero point is fed relative to the body (ground) to the controlled network, and through the capacitors 11 and the resistors 12 this signal flows around the insulation resistance, currently disconnected sources and consumers of electricity. The value of the current of this signal, detected by the sensor 2 of the current of a non-pulsed frequency, proportional to the conductivity value of the entire monitored network, is fed to the input of the threshold unit; 7. If the signal at the input of the threshold unit 7 exceeds the threshold of its operation (setpoint value), then the signal from the output of the threshold unit 7 interrupts by unlocking the key 13 the current flow from top 4 to the state indicator 10, even a signal of low insulation resistance settings The signal from the second output of the source 1 of the operational voltage of the non-industrial frequency is rectified by rectifier 4 and through the sensor 5 of the rectified current is fed to the input of block 6 of the artificial zero point. This signal flows around the insulation resistances of only that part of the monitored network that is under operating voltage. Therefore, the signal from the output of the sensor 5 of the rectified current, which enters the input of the threshold unit 8 nponopuHOHaj eH of conductivity (inversely proportional to the insulation resistance) of the part of the network that is under operating voltage. From the output of the threshold unit 8, this signal is fed to another input of the logic unit 9, in particular, the opening of the key 14 and preventing voltage from entering the state indicator 10. Thus, the voltage from the rectifier 4 is fed to the indicator 10 only if there is no single-phase short circuit both in the part of the monitored network under operating voltage and in the disconnected power sources and consumers. At the same time, information about the triggering of the threshold units 7 or 8, or about their simultaneous operation, is displayed to the operator if necessary, which gives an idea that in the disconnected or disconnected part of the monitored network, the insulation resistance drops below the setpoint. If there are large capacities in a controlled network relative to the case, two non-industrial frequencies are applied to the controlled network (using the two-frequency method), moreover, both frequencies are higher. To eliminate the influence of the indicator circuit 10 on the mode of the valve elements on top 4, and, consequently, on the measuring circuit, in which there is a 10 state indicator, on top of section 4, a special load resistance is provided, ensuring the selection of the operating point mittel, or two separate, rectifier outputs are used. If necessary, plugs (not shown) can be inserted at the frequency of the working voltage, (or some of its harmonics) in series with resistors 12. And capacitors 11. The technical and economic effect of the invention is due to the possibility of learning information about the state of isolation of disconnected sections of the network, which makes it possible to exclude the introduction of a section of a network with reduced insulation resistance to the working network, and thereby improve the fire and electrical safety conditions.

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Claims (2)

1 . DEVICE FOR 'MONITORING RESISTANCE OF ELECTRIC NETWORK INSULATION, containing an operating voltage source, a current sensor, a separation unit and a first threshold unit, characterized in that, in order to expand the functionality of the device, providing constant monitoring of the insulation resistance of disconnected sources and consumers of electricity, it additionally introduced rectifier, rectified current sensor, second threshold block, logic block, artificial zero point block, status indicator and six chains to from series-connected capacitors and resistors, moreover, one output of the operating voltage source through a series-connected current sensor, a separation unit and an artificial zero point unit is connected to a controlled network, and the other output of this operating voltage source through a series-connected rectifier and a rectified current sensor is connected to the same input of the artificial zero point block, the outputs of the current sensor and the rectified current sensor are connected to the inputs of the first and of the horn blocks, the outputs of which are connected respectively to the first and second inputs of the logic block, the output of which is connected to the status indicator, the first conclusions of the first, second, third and first conclusions of the fourth, fifth and sixth chains of series-connected capacitors and resistors are connected to the moving contacts of the switches sources and consumers of electricity, respectively, and the second conclusions of the first, second and. the third, as well as the conclusions of the fourth, fifth, and sixth chains of series-connected capacitors and resistors, are connected to the fixed contacts. 'switches sources and consumers of electricity, respectively. 2. The device according to claim 1, characterized in that the logic unit consists of two series-connected keys, the controlled inputs of the first and second keys are the first and second inputs of the logic unit, respectively.