RU1795380C - Device for measuring network insulation resistance equipment with induction motor - Google Patents

Abstract

Usage: in electrical engineering. The inventive device for measuring the insulation resistance of a network with an asynchronous motor contains a switching device, the power contacts 1 of which are included in the dissection of the phase conductors of the network supplying the electric motor 2, the control circuit of the switching device, including on and off elements 8, 9, 10, 11 switching device, recording node 8, containing a rectifier 3 connected to the terminals of the switching device connected to the terminals of the motor windings, storage condensate p 4 connected to the output of rectifier 3 and a measuring device 5 connected in parallel with the storage capacitor 4. The threshold element 7 with the opening contact and the isolation capacitor 6 are new, and the threshold element 7 is connected to the line voltage via the make contact of the switching disconnect element apparatus, the breaking contact of the threshold element 7 is included in the control circuit of the switching device, the rectifier 3 of the recording node is made according to the scheme of half-wave rectification, and the separator A capacitor 6 is connected between the ground terminal and the rectifier output terminal. 1 ill.

Description

The invention relates to electrical engineering and can be used in the operation of electric networks with voltages up to 1000 V with induction motors as a load for monitoring the insulation of networks with asynchronous motors

A device is known for measuring the insulation resistance relative to earth of electrical networks with isolated neutral & o using a constant operational voltage of a leakage relay, three-phase choke, measuring transformer, switching device, and measuring device.

The disadvantage is the impossibility of use in networks with a grounded neutral.

The closest technical solution to the proposed one is a device for measuring the insulation resistance relative to the ground of electric networks with an electric motor, comprising a storage capacitor, a measuring device, a switching device, the power contacts of which are connected between the terminals for connecting the phases of the network and the terminals for connecting the phases of the measured network section to which is connected to the input rectifier.

A disadvantage of the known technical solution is the low accuracy of the measurement. The known technical solution does not take into account the processes of switching overvoltages that always occur when an inductive load is disconnected, in particular, when a network section with an induction motor is disconnected.

The purpose of the invention is to improve measurement accuracy.

This goal is achieved in that a device for measuring the insulation resistance of a network with an induction motor, comprising a storage capacitor, a measuring device, a switching device, the power contacts of which are connected between the terminals for connecting the phases of the network and the terminals for connecting the phases of the measured network section to which is connected the rectifier input is equipped with a threshold element controlled by a key, an isolation capacitor, two keys, the first terminals of which are connected to the terminal for connecting one of the phases of the network, the second output of the first key is connected to the first output of the threshold element, the second output of which is connected to one output of the controlled key and to the d / g terminal of the other

phase of the network, the second terminal of the controlled key is connected to the first terminal of the coil of the switching apparatus, the second terminal of which is connected to the second terminal of the second key, the first rectifier output is connected to the first terminals of the storage capacitor and measuring device, and the second rectifier output is connected to the second terminals

0 storage capacitor and measuring device and the first output of the separation capacitor, the second output of which is connected to a common bus. In this case, it is advisable to perform straight 5 bodies according to a two-half-wave scheme.

A device for measuring the insulation resistance of an induction motor network is illustrated in the drawing, which shows a diagram of the device.

0 The device contains a switching device with power contacts 1, the measured section of the network with an asynchronous electric motor 2, rectifier 3, storage capacitor 4, measuring device 5,

5 isolation capacitor b, threshold element., First key 8, controlled key 9, coil 10 of the switching device, second key 11, while the input terminals of the power contacts-1 are connected to

0 phases of the network, and the output to the measured section of the network with an asynchronous motor 2 and the input of rectifier 3, the output of which is connected to the storage capacitor 4 and measuring device 5, isolation

5, the capacitor 6 is connected to the positive terminal of the rectifier output with one lining, with the other lining to a common bus, a threshold element, the first output of which is connected to the first output of the first

0 of key 8, and the second output is connected to the first output of the controlled key 9 and to one terminal for connecting the phases of the network, the second output of the controlled key is connected to the first output of the coil 10 of the switching device, the second output of which is connected to the first output of the second key 11, the second terminals of keys 8 and 11 are connected to another terminal for connecting the phases of the network. The threshold element 7 controls the key 9.

0 The device operates as follows.

In the initial state, with closed power contacts 1 of the switching apparatus, the measured network section with an asynchronous electric motor 2 is connected to the network. A linear voltage is applied to the half-wave rectifier 3, the storage capacitor 4 is charged to the value of the amplitude linear voltage, which is shown by the measuring device

5. If necessary, disconnect the induction motor 2 from the mains, manually close the key 8, while a sinusoidal current of the linear voltage of the corresponding phases of the network, in this case phases, flows through the threshold element 7. A and B. At a certain instantaneous current value, which is configured with a threshold element 7, which supplies a signal to the controlled key 9, in the form of breaking the circuit, while the coil 10 of the switching device is de-energized, the power contacts 1 break the network circuit with an asynchronous motor 2. At the terminals of the induction motor 2, a switching overvoltage pulse arises. This pulse is fed to the input of rectifier 3, from the output of rectifier 3 to the storage capacitor 4, where it is measured by measuring device 5. The separation capacitor 6 serves to create a current leakage circuit of switching overvoltage pulses through the resistances Z1 of the corresponding phases of the measured network section relative to the earth.

Thus, thanks to the threshold element 7 and the threshold element 7 controlled by the key 9, the circuit of the measured network section is broken with asynchronous

electric motor at a strictly fixed instantaneous value of the mains voltage, and hence f and the current flowing through the asynchronous electric motor. Due to the described interaction of the elements and the links, the induction motor turns into a stabilized measuring voltage source, the value of which depends on the insulation resistances Z1, 22, Z3 of the shunting of this measuring voltage source.

The prior art solution does not take into account the influence of switching overvoltages that always occur when an asynchronous electric motor is switched off. The value of switching overvoltages varies over a wide range from the values of the mains voltage to multiple excesses of more than three to seven times. The spread in the values of the switching overvoltage will affect the measurement accuracy in a known technical solution.

Owing to the aforementioned set of elements and connections, in the claimed solution, it is possible to achieve a smaller spread of the switching overvoltage values and, consequently, to increase the measurement accuracy.

Claims (1)

SUMMARY OF THE INVENTION 1. A device for measuring the insulation resistance of a network with an asynchronous electric motor, comprising a storage capacitor, a measuring device, a switching device, the power contacts of which are connected to terminals for connecting the phases of the monitored section of the network to which the rectifier input is connected characterized in that, in order to increase the measurement accuracy, a threshold element, a controlled key, an isolation capacitor, two keys, the first terminals of which are connected to the connection terminal, are inserted into it audio mains phase, a second terminal of the first switch is connected to a first terminal of the threshold element, the second terminal of which is connected to one terminal of a controlled key and with a terminal for connecting another phase of the network, the second terminal of the controlled key is connected to the first terminal of the coil of the switching device, the second terminal of which is connected to the second terminal of the second key, the first rectifier output is connected to the first terminals of the storage capacitor and measuring device, and the second rectifier output is connected to the second terminals of the storage capacitor and the measuring device and the first output of the isolation capacitor, the second terminal of which is connected to a common bus, 2. The device of pop. 1, characterized in that the rectifier is made according to the scheme of a half-wave rectifier.