RU2321008C2 - Method of measurement of resistance of electric circuits' insulation (versions) - Google Patents

Abstract

FIELD: electric measurement.

SUBSTANCE: method can be used for measuring resistance of insulation of electric circuits of any kind of current, which circuits are subject to working voltage or de-energized and isolated from earth. Method of measurement of resistance of insulation and inductance of electric circuits is based upon selection of any kind of current electric circuit, being under voltage of de-energized and insulated from earth as controlled circuit. Constant regulated measuring voltage source is connected to controlled circuit. Voltage of source equals to voltage of circuit in point of connection. Current passing through this constant measuring voltage source is measured and meanings of current and voltages are memorized. Then constant regulated measuring voltage source is disconnected and permanent current source is connected and inductance of circuit is subject to charging during period of change of voltage in or during 20 ms. Voltage in point of connection is measured in specified period of time and that voltage is memorized. The permanent value current source is disconnected and regulated constant measuring voltage source is connected instead, which has voltage to be equal to voltage in circuit in point of connection. Value of current assign through that source is measured and memorized, and results of measurement are processed by formulas for calculation of value of isolation resistance and inductance of circuit.

EFFECT: reduced time of measurement; improved precision of measurement.

2 cl, 2 dwg

Description

The invention relates to electrical measurements, namely to measurements of 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 known method of measuring insulation resistance [USSR Author's Certificate No. 408238, class. G01R 27/18, 1974], which consists in connecting an auxiliary DC voltage source to the controlled network, performing its regular switching so that the switching moments are not correlated with the change in the voltage of the controlled network, and determining the value of the insulation resistance of the network by the sum of the voltage values in the measuring point measured at times prior to switching. The method provides the ability to measure the insulation resistance of both de-energized circuits and networks under constant or alternating voltage.

However, the main disadvantage of this method 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 the voltage at the measuring point. After switching, a sufficient period of time is needed to recharge the network capacities. After this period of time, you can measure the voltage and only then make the next switching. 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 the risk of fire.

There is also a method of measuring insulation resistance [Ivanov EA, Kuznetsov S.E. Methods of monitoring the insulation of ship electrical systems. Tutorial. - St. Petersburg: "Elmore", 1999, pp. 53-54], which can be used in AC and double current networks. The essence of the method is as follows. A three-phase rectifier bridge assembled according to the Larionov circuit is 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 ground, between the negative pole and 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 invention (prototype) is a method of measuring insulation resistance, which is as follows [USSR Author's Certificate No. 1737363, class. G01R 27/18, 1992]. The network capacitance is charged with respect to the ground by a constant current of constant value to the specified voltage value, the constant current source is turned off, the measured constant voltage source of the specified value is connected and the leakage current is measured, then the measurement cycle is repeated with the voltage polarity changing on the network capacitors and the measurement results are processed and the number of measurement cycles depends on the type of current of the controlled network. This method can significantly reduce the measurement time by accelerating the charge of the network capacitance from a constant current source and in deenergized networks or in DC networks provides good results, since the number of measurement cycles here does not exceed two. However, in AC or dual current networks, the number of measurement cycles is significantly larger, which is necessary to eliminate the influence of AC voltage on the measurement result. This leads to an increase in measurement time and a decrease in the accuracy of measurement of insulation resistance.

The technical result from the implementation of this invention is to reduce the measurement time, increase the accuracy of measuring the insulation resistance in networks of any kind of current, energized or de-energized, due to the possibility of measuring the capacitance of such networks.

The problem is achieved in that the method of measuring the insulation resistance and capacitance of electric networks according to the first embodiment of the possible implementation is that as a controlled network, select a live electric network, connect a controlled constant measuring voltage source to the controlled network, the voltage value of which is equal to the network voltage at the connection point, measure the current through this constant voltage source and store these voltage and current values , then turn off the source of adjustable constant measuring voltage and connect the current source of constant value and charge the network capacitance for exactly the voltage period of the controlled network, measure the voltage at the connection point exactly after the period of the voltage of the network and store it, then turn off the current source of constant value and connect the source adjustable constant measuring voltage, the voltage value of which is equal to the mains voltage at the connection point, measure and store the values chenie current flowing through the source, and on the basis of obtained measurement results determined value of insulation resistance and capacity-controlled network.

The problem is achieved in that the method of measuring the insulation resistance and capacitance of electric networks according to the second embodiment of the possible implementation is that as a controlled network choose an electric network of any kind of current under voltage or de-energized and isolated from the ground, while to the controlled network connect a source of adjustable constant measuring voltage, the voltage value of which is equal to the network voltage at the connection point, measure the current through this constant source and Tonnage voltage and storing these values of voltage and current, then disconnect the source of regulated DC voltage measurement and connect a current source of constant value and produce a charge capacity of the network during the time t _edited = 20 ms, the measured voltage at connecting point exactly t _edited = 20 ms, and remember it, then turn off the current source of constant value and connect the source of adjustable constant measuring voltage, the voltage value of which is equal to the voltage at the point of connection I measure and remember the value of the current flowing through this source, and process the measurement results according to the formulas, calculating the values of insulation resistance and network capacitance.

The invention differs from the prototype in that in networks of any kind of current under voltage or de-energized and isolated from the earth, a controlled constant measuring voltage source is connected to the controlled network, the voltage value of which is equal to the network voltage at the connection point, the current is measured through this constant measuring voltage source and remember these values of voltage and current, then turn off the source of adjustable constant measuring voltage and connect the current source of constant value They charge the network capacity during either the voltage period of the monitored network or the time interval t _ISM = 20 ms, measure the voltage at the connection point exactly after the specified period of time and store it, then turn off the current source of constant value and connect the source of adjustable constant measuring voltage, the voltage value of which is equal to the network voltage at the connection point, measure and store the value of the current flowing through this source, and process the measurement results by formula is calculating the value of insulation resistance and capacity of the network.

In Fig.1 is a diagram of the device explaining the principle of operation of the proposed method, and Fig.2 is a timing diagram explaining the proposed method (Fig.2a is the phase voltage of the controlled network in the case of network symmetry, Fig.2b is the voltage at the output of the unit connection when it is implemented in the form of a Larionov circuit, and in Figs. 2c and 2d, the same voltages, respectively, in the case of a network asymmetry).

The device consists of a control unit 1, a switch 2, a source of adjustable constant measuring voltage 3, a connection unit 4, a controlled network 5, a current measuring unit 6, a voltage measuring unit 7, a constant current source 8, a result processing unit 9, and a recording and indication unit 10. Moreover, a current source of a constant value of 8 is connected between the "ground" and the switch 2, the current measuring unit 6 is connected between the "ground" and a source of adjustable constant measuring voltage 3, which is connected to switch 2 and to the control unit 1, which is connected to the switch 2 and to the voltage measuring unit, to the input of which the output of the switch 2 is connected, the same output of the switch 2 is connected to the input of the connection unit 4, the output of which is connected to the controlled network 5, the output of the measurement unit current 6 and the output of the voltage measuring unit 7 are connected to the inputs of the processing unit 9, the output of which is connected to the input of the registration and display unit.

Connection block 4 is either a three-phase rectifier bridge assembled according to the Larionov circuit, three inputs of which are connected to the phases of the controlled network 5, the middle point of the low-impedance load is to switch 2, or (this option is not shown in Fig. 1) three inductors, one ends which are combined and connected to switch 2, and the other ends to three phases of the monitored network 5, or (this option is not shown in Fig. 1), connection block 4 provides direct connection of switch 2 to one (any) of the phases of the monitored network and 5.

The essence of the proposed method is as follows.

The control unit 1 using the switch 2 connects at time t ₁ (figure 2) the source of adjustable constant measuring voltage 3 through the connection unit 4 to the controlled network 5. Moreover, the voltage value of this source of adjustable constant measuring voltage 3 is equal to the voltage at the connection point, this is ensured by measuring this voltage by the voltage measuring unit 7 and by setting, using the control unit 1, this voltage value at the output of an adjustable constant measuring source voltage 3. The same voltage value U _{1 is} stored in the processing unit 9, and the current measuring unit 6 measures the current flowing through the adjustable constant voltage measuring source 3, and this current value i ₁ is stored in the processing unit 9. After this control unit 1 using the switch 2 turns off the source of adjustable constant measuring voltage 3 and connects at time t ₂ (figure 2) a current source of constant value 8 exactly for a time or period of voltage niya controlled network, or time interval t _ISM = 20 ms. The network capacitance is charged from this current source 8. The voltage of the controlled network is measured using the voltage measuring unit 7 and through the control unit 1 it is repeated in the source of the adjustable constant measuring voltage 3. Exactly after the voltage period of the controlled network or time interval t _ISM = 20 ms value of this voltage U _{2 is} stored in the processing unit 9 and at the same moment, the control unit 1 using the switch 2 turns off the current source of a constant value of 8 and connects the source to voltage constant measuring voltage 3, the voltage value of which is equal to the voltage at the point of connection. At the same moment, the value of current i _{2 is} produced and stored.

In the processing unit 9 results are processed results of measurements of currents I ₁ and I ₂ and voltages U ₁ and U ₂ , which is as follows.

The differences of voltages U = U ₂ -U ₁ and currents I = I ₂ -I _{1 are} calculated. Obviously, the current I ₁ and voltage U _{1 are} determined by the parameters of the controlled network, namely the voltage of the network and its configuration, i.e. values of insulation resistances and network capacities and degree of network asymmetry. The value of U ₂ contains two components: the first exactly repeats the value of U ₁ , and the second U _IZ is determined by the values of the current source, unchanged value of 8 and the capacity of the network 5. The value of I ₂ also contains two components: the first is I ₁ , and the second I _IZ is determined by the resistance network isolation R _IZ and voltage U _IZ . Thus, to measure the insulation resistance, it is necessary to make the following calculations:

In addition, it is possible to calculate the equivalent network capacity by the formula (2). The conclusion of the formula is given in the appendix.

where I _IST is the value of the current source of constant value 2,

T _P = t ₂ -t ₁ - period of the controlled network.

The calculated values of the insulation resistance of the network and the network capacity are transmitted to the registration and display unit 10.

Thus, the proposed method allows to achieve a technical result, which consists in reducing the measurement time, improving the accuracy of measuring the insulation resistance in networks of any kind of current, energized or de-energized, due to the possibility of measuring the capacitance of such networks.

Analysis of the equivalent network circuit and the derivation of formula (2). An equivalent circuit of the measuring circuit of the proposed device is shown in figure 3. The following notation is used here: R _IZ and C _E are the equivalent values of the insulation resistance and network capacitance, respectively equal to the parallel connection of all insulation resistances and all capacitances, respectively, I is the value of the current of the DC source. The resistances of the diodes in the on state, as well as the parallel connection of the parts of the resistor of the attachment unit, were neglected due to their smallness (by several orders of magnitude) compared to the resistance R _FROM .

This scheme can be converted to the next (figure 4).

From the analysis of this system we get

где τ=R_ИЗ·С_Э.

where τ = R _FROM · WITH _E.

Using the series expansion for U _C (t), we obtain

When t _ISM = t ₂ - t ₁ << t, which is always true, because t _ISM is tens of milliseconds (at f = 50 Hz, t _U = 20 ms), and τ is seconds or tens of seconds (so at c = 100 μF and R _FR = 100 kOhm, τ = 10 s), we obtain

This implies:

Claims (2)

1. The method of measuring the insulation resistance and capacity of electrical networks, which consists in the fact that as a monitored network choose an electric network under voltage, while a controlled constant measuring voltage source is connected to the controlled network, the voltage value of which is equal to the network voltage at the connection point, the current is measured through this source of constant measuring voltage and remember these values of voltage and current, then turn off the source of adjustable constant measuring voltages and connect a constant current source of power and charge the network capacitance for exactly the voltage period of the monitored network, measure the voltage at the connection point exactly after the network voltage period and store it, then turn off the constant current source and connect the adjustable constant measuring voltage source, voltage value which is equal to the voltage at the connection point, measure and store the value of the current flowing through this source, and based on x measurements determined value of insulation resistance and capacity-controlled network. 2. The method of measuring the insulation resistance and capacity of electrical networks, which consists in the fact that as a controlled network choose an electric network of any kind of current under voltage or de-energized and isolated from "earth", while a controlled constant measuring voltage source is connected to the controlled network, value the voltage of which is equal to the network voltage at the connection point, measure the current through this source of constant measuring voltage and store these voltage and current values, then from Luciano source of regulated DC voltage measurement and connect a current source of constant value and produce a charge capacity of the network during the time t _edited = 20 ms, the measured voltage at connecting point exactly t _edited = 20 ms and storing it, and then cut off the source of constant current and connected a source of adjustable constant measuring voltage, the voltage value of which is equal to the network voltage at the connection point, measure and store the value of the current flowing through this source and Measure the measurement results using formulas, calculating the values of insulation resistance and network capacity.

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