RU60225U1 - DEVICE FOR MEASURING RESISTANCE OF ELECTRIC NETWORK INSULATION - Google Patents

Abstract

A device for measuring the insulation resistance of electrical networks of any kind of current that are under operating voltage or are de-energized and isolated from the earth, containing an adjustable voltage source, a connection unit, a current measurement unit and an output device, characterized in that a filtering unit is additionally introduced into it, a control unit and two blocks of controlled currents, and the outputs of the control block are connected to the inputs of the blocks of controlled currents, and the blocks of controlled currents are connected between the outputs of the connection block and a current measuring unit, the output of the adjustable voltage source is connected to one input of the control unit, and a filter output is connected to the second input of the control unit, the input of which is connected to the midpoint of the connection unit, and the outputs of the filter and current measuring unit are connected to the inputs of the output device.

Description

The utility model relates to electrical engineering and is designed to measure the insulation resistance of electrical networks of any kind of current that are under operating voltage or de-energized and isolated from the "earth".

A device for measuring the insulation resistance of electric networks under voltage [USSR Author's Certificate No. 892348, class. G 01 R 27/16, H 02 H 3/16, 1981], comprising an auxiliary DC voltage source, a switch, a synchronizer, a limiting resistor, a damped oscillator, a magnetic amplifier with two toroidal cores with additional windings and a resistor, a narrow-band filter and an indicator .

However, the main disadvantage of this device is its low speed. This is due to the fact that after each switching of the auxiliary DC voltage source, it is impossible to immediately measure current. After switching, a sufficient period of time is needed to recharge the network capacities. After this period of time, it is possible to measure the current and only then make the next switching. To eliminate the influence of the variable voltage components of the controlled network on the measurement result, the number of such switching can be large. Since the network capacitance can reach several hundred microfarads, the time of measuring the insulation resistance of the network can reach several tens or even hundreds of seconds. This is often unacceptable, because due to the possible probable connection or disconnection of individual consumers during the measurement, an unacceptably large measurement error may appear.

In addition, with such a long measurement cycle, a significant change in the insulation resistance can occur and, as a result,

there is a danger of electric shock and fire hazard.

A device for measuring the insulation resistance of AC electric networks [USSR Author's Certificate No. 1765785, class. G 01 R 27/18, 1992], containing two groups of rectifiers, a bipolar switch for three positions, an earthing switch, a unit for changing the internal resistance of a voltmeter, and a direct current measuring device. The essence of the device is as follows. Two three-phase rectifiers (assembled according to the Larionov circuit) are connected to the phases of the AC network. Then, three average voltage values are measured in turn: at the output of the bridge, between the positive pole of the bridge and the ground, between the negative pole and the ground. Then, the insulation resistance is calculated by the formula.

The main disadvantage of this method is its low speed, due to the need to measure the average voltage values, since it is the average voltage values that are carriers of information about the value of insulation resistance.

In addition, this method is unsuitable for de-energized networks.

The closest in technical essence to the proposed utility model (prototype) is a device for measuring insulation resistance [V. Lachin Monitoring and forecasting the state of electric power facilities with discretely distributed parameters. - Rostov n / A: Publishing House SKNTs VSh, 2001. - p.129-130.], Containing a three-phase rectifier bridge (connection block), current measuring unit, adjustable source voltage, synchronizer, output device. It is possible to measure the insulation resistance of a double-type current network if its parameters are reduced to the equivalent parameters of a direct current network. To eliminate the influence of the constant, interfering component of the mains voltage, a direct current is measured that flows through the current measuring unit twice: first, at one

the polarity of the auxiliary regulated voltage source, then at another, and then the measurement results are subtracted. When subtracting, the value of the leakage current doubles, since it changes the polarity when the polarity of the regulated voltage source changes, and the "interfering" component of the network current becomes zero, since its polarity remains unchanged, regardless of the change in the regulated voltage source.

Subtraction of the measured current values and the formation of an output signal proportional to the insulation resistance of the network is carried out in the output device. The considered device allows continuous measurement of insulation resistance in double-type current networks that are energized or de-energized.

However, in the measuring circuit of the device there is also an alternating voltage component, the value of which is determined by the voltage value of the controlled network and the degree of its asymmetry. And the presence of this alternating voltage in the measurement circuit leads to an error in measuring the network capacity. Moreover, this error is greater, the greater the voltage of the controlled network and the more asymmetric the network. Therefore, the proposed device is operable only in a limited voltage range of the controlled network and only with a certain asymmetry.

In addition, this device has a long measurement process, which increases with increasing capacity of the monitored network.

The objective of the proposed utility model is to expand the functionality. The technical result consists in reducing the error and measurement time.

The task is achieved by the fact that in a device for measuring the insulation resistance of electrical networks of any kind of current that are under operating voltage or de-energized and

isolated from the "ground", containing an adjustable voltage source, a connection unit, a current measuring unit and an output device, a filtering unit, a control unit and two blocks of controlled currents are introduced, the outputs of the control block connected to the inputs of the blocks of controlled currents and the blocks of controlled currents included between the outputs of the connection unit and the current measuring unit, the output of the adjustable voltage source is connected to one input of the control unit, and the filter output, the input of which is connected to the second input of the control unit dklyuchen to a midpoint connection unit, and the filter outputs and the current measuring unit are connected to the inputs of the output device.

Fig. 1 is a diagram of the device, and Fig. 2 and Fig. 3 are timing diagrams explaining its operation, and Fig. 2a shows the phase voltage of the monitored network, Fig. 2b shows the voltage at the input of the filtering unit, Fig. 3a is the voltage at the output of the filtering unit, and in FIG. 3b is the current impact on the network.

The device comprises a control unit 1, a first controlled current unit 2, a connection unit 3, a controlled network 4, an adjustable voltage source 5, a filtering unit 6, a second controlled current unit 7, a current measuring unit 8 and an output device 9. Moreover, the outputs of the control unit 1 are connected to the inputs of the blocks of the controlled currents 2 and 7, and the blocks of the controlled currents 2 and 7 are connected between the outputs of the connection unit 3 and the current measuring unit 8, the connection unit 3 is connected to the controlled network 4, the output of the regulated voltage source 5 is connected to one th entry of the control unit 1, and to a second input of the control unit 1 connected to the output filter unit 6, whose input is connected to a midpoint connection unit 3, and outputs the filtering unit 6 and the current measuring unit 8 is connected to the output device 9 inputs.

The device operates as follows. The voltage at the output of the filtration unit 6 generally contains an alternating component, determined by the alternating voltage of the controlled network 4 and a constant component, if the controlled network 4 is a double current network. Moreover, the values of these components are determined by the parameters of the controlled network (figa) and the degree of its asymmetry. The output of the filtering unit 6 contains only the average value (constant component) of these voltages (figa). The control unit 1 connects the controlled current unit 2 through the connection unit 3 to the monitored network 4 and the process of charging the equivalent capacitance of the monitored network to a predetermined voltage value _occurs (U _REF in FIG. 6 of the Appendix). The magnitude of the voltage change on the network capacitance is set by the magnitude and polarity of the regulated voltage source 5. Since the charging current is large, the time to reach the set voltage is short (t ₁ in FIG. 5 of the Appendix) and upon reaching this set voltage value the current value of the controlled current unit is reduced to such the value of I ₁ so that the average voltage U ₁ at the output of the filtering unit 6 remains constant (figa). The process of charging equivalent network capacity is given in the appendix. The values of voltage U ₁ and current I ₁ measured by the current measuring unit 8 are stored in the output device 9. Then, using the control unit 1, the input of which is affected by an adjustable voltage source 5 with a changed voltage polarity, a controlled current unit 7 is connected, which generates a current of the opposite directions than the controlled current unit 2 and repeat the above operations. Remember in the output device 9 a new value of the average voltage U ₂ at the output of the filtering unit 6 and the current value I ₂ of the controlled current unit 7 necessary to maintain a constant voltage U ₂ (figa) at the outputs of the filtering unit 6.

In the output device 9 is the processing of the results of the measured and stored values of currents and voltages, which is as follows.

The differences of voltages U = U ₁ -U ₂ and currents I = I ₁ -I _{2 are} calculated. Obviously, the voltages U ₁ and U ₂ contain two components. The first U _POM (interference) is determined by the voltage of the monitored network 4 and the degree of its asymmetry, and the second U _RH is determined by the predetermined unit of the regulated voltage source 5 voltage.

Moreover, U ₁ = U _POM + U _READ , and U ₂ = U _POM -U _READ , where U _POM is the interference voltage, because these voltage values are obtained for different directions of currents generated by blocks of controlled currents 2 and 7.

The currents I ₁ and I ₂ ensure that the DC voltage at the output of the filtering unit 6 is maintained after changing it by a predetermined value U _ZAD , with I ₁ = I _ZAD and I ₂ = -I _ZAD . Thus, U = U ₁ -U ₂ = 2U _REAR , and I = I ₁ -I ₂ = 2I _REAR . As shown in Annex U _REF = I · R _{REF OUT.}

Next, calculate the equivalent insulation resistance of the controlled network 4

It is easy to see that for different values of currents I ₁ and I _2, the voltage difference U ₁ and U ₂ corresponding to these currents and divided by the difference of these currents will determine the equivalent insulation resistance of the controlled network 4.

The considered device allows you to measure the equivalent insulation resistance of electrical networks of any kind of current at significant voltage values of the controlled network and does not require multiple measurements.

Thus, the technical result is that the proposed device has a smaller measurement error and a shorter measurement time.

Claims (1)

A device for measuring the insulation resistance of electrical networks of any kind of current that are under operating voltage or are de-energized and isolated from the earth, comprising an adjustable voltage source, a connection unit, a current measurement unit and an output device, characterized in that a filtering unit is additionally introduced into it, a control unit and two blocks of controlled currents, and the outputs of the control block are connected to the inputs of the blocks of controlled currents, and the blocks of controlled currents are connected between the outputs of the connection block and by the current measuring unit, the output of the adjustable voltage source is connected to one input of the control unit, and the filter output is connected to the second input of the control unit, the input of which is connected to the midpoint of the connection unit, and the outputs of the filter and current measuring unit are connected to the inputs of the output device.