RU2310873C1 - Method for measuring resistance of isolation in electric networks - Google Patents

Abstract

FIELD: method for measuring resistance of isolation in electric networks of any type of current or cleared and isolated from "ground".

SUBSTANCE: in accordance to the invention, a source of controllable constant current is connected to controlling network, then discharge of network capacity is performed down to predetermined value, then value of current is reduced to such a value, that average value of voltage in point of connection to network being controlled remains constant, these current and voltage values are recorded, then these operations are repeated with change of direction of current of source of controlled constant current, new current and average voltage values are memorized in point of connection to controlled network and value of resistance of network isolation is computed.

EFFECT: reduced time of measurement, increased precision of resistance measurement.

3 dwg

Description

The invention relates to electrical measurements, namely to measurements of the insulation resistance of electrical networks of any kind of current, 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 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 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 capacitors are charged with respect to the ground by a constant current of constant value to the value of the set voltage value, the current source of the constant value is turned off, the source of the measured constant voltage of the set 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 objective of the invention is the expansion of functionality.

The technical result consists in reducing the measurement time, increasing the accuracy of measuring the insulation resistance in networks of any kind of current that are energized or de-energized.

The task is achieved by a method of measuring the insulation resistance of electrical networks of any kind of current under voltage or de-energized and isolated from the "ground", namely, that a controlled constant current source is connected to the controlled network, the network capacity is charged to a predetermined value, then the current value is reduced to such a value that the average value of the voltage at the point of connection to the controlled network remains constant, remember these values of current and voltage, then repeat yayut these operations change the DC variable current direction storing new values of current and average voltage at the point connecting to the monitored line and treated with the results of measurements by the formula, calculating the value of insulation resistance of the network.

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 current source is connected to the controlled network, the network capacity is charged to a predetermined value, then the current value is reduced to such a value that the average the voltage value at the point of connection to the controlled network remained constant, remember these values of current and voltage, then repeat these operations with a change in the direction of the current source is regulated th DC storing new values of current and average voltage at the point connecting to the monitored line and treated with the results of measurements by the formula, calculating the value of insulation resistance of the network.

In figure 1. is a diagram of the device explaining the principle of operation of the proposed method, and in FIG. 2 and FIG. 3 are timing diagrams explaining the proposed method (in FIG. 2a is the phase voltage of the monitored network in case of network symmetry, in FIG. 2b is the output voltage the connection unit when it is implemented in the form of a Larionov circuit, in Fig. 3a, the voltage at the output of the filtering unit, and in Fig. 3b, the current to the network.

The device consists of a control unit 1, an adjustable constant current block 2, a connection unit 3, a monitored network 4, a filtering and voltage measuring unit 5, a result processing and indication unit 6. Moreover, the outputs of the adjustable constant current unit 2 are connected to the input of the connection unit 3 and the input of the processing unit of the results and indications 6, the outputs of the connecting unit 3 are connected to the monitored network 4 and to the input of the filtering and measuring unit 5, the outputs of which are connected to the input of the processing unit and indications and 6 and the input of the control unit 1, the output of which is connected to the input of the adjustable constant current block 2.

Connection block 3 is a three-phase rectifier bridge assembled according to the Larionov circuit (not shown in Fig. 1), three inputs of which are connected to the phases of the controlled network 4, the middle load point is to the filtering and voltage measuring unit 5, and the rectifier outputs to the block adjustable direct current 2.

The essence of the proposed method is as follows.

The voltage at the input of the filtering and voltage measuring unit 5 in the general case contains a variable component determined by the alternating voltage of the controlled network, and a constant component if the controlled network is a double current network. Moreover, the values of these components are determined by the parameters of the controlled network and the degree of its asymmetry. The outputs of the filtering and voltage measurement unit contain only the average value (constant component) of these voltages. The control unit 1 connects the adjustable DC unit 2 through the connection unit 3 to the controlled network 4 and the process of charging the equivalent capacity of the controlled network to the predetermined value U _ass . Since the charging current is large, the time to reach the set voltage t _{1 is} short, and upon reaching this set voltage value, the current value of the controlled constant current block 2 is reduced to such a value I ₁ that the average voltage U ₁ remains constant. These values of current I ₁ and voltage U ₁ are stored in the result processing and display unit 6. Then, using the control unit 1, the current direction generated by the controlled constant current unit 2 is changed and the operations described above are repeated. In the processing unit of the results and indications 6, a new value of the average voltage U _{2 is} stored, at the output of the filtration and voltage measurement unit 5, the current value I ₂ is necessary to maintain a constant voltage U ₂ at the outputs of the filtration unit and voltage 5.

In the processing unit of the results and indication 6, the processing of the results of measurements of voltages U ₁ and U ₂ and currents I ₁ and I ₂ takes place, which consists in the following.

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 is} determined by the voltage of the monitored network and its asymmetry, and the second U _ZAD - in advance by the set voltage value due to the influence of the current of the adjustable constant current block 2 of such a value I ₁ or I back that keeps the voltage U ₁ and U ₂ constant at the outputs of the filtering unit and voltage measurements 5.

Moreover, U ₁ = U _POM + U _REF , and U ₂ = U _POM -U _REF . these values are obtained for different directions of the currents of the adjustable constant current block 2.

The currents I ₁ and I ₂ provide a change in voltage at the outputs of the filtering unit and a change in voltage 5 by the value of U _ZAD .

Moreover, I ₁ = I _READ , a I ₂ = -I _READ ,

U = U ₁ -U ₂ = 2U _REAR , and I = I ₁ -I ₂ = 2I _REAR ,

U _REF = I _REF · R _FROM .

Next, the equivalent insulation resistance of the controlled network is calculated

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.

Thus, the technical result consists in the fact that this method provides less error and measurement time.

Claims (1)

A method of measuring the insulation resistance of electrical networks of any kind of current under voltage or de-energized and isolated from the earth, which consists in connecting a controlled constant current source to the controlled network, charging the network capacity to a predetermined value, then reducing the current value to such a value so that the average value of the voltage at the point of connection to the controlled network remains constant, remember these values of current and voltage, then repeat these operations with a change in direction Lenia regulated DC current, storing the new values of current and voltage in the middle point to the controlled network connections and treated with the results of measurements by the formula, calculating the value of insulation resistance of the network.

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