SU1737363A1 - Method of testing the electric networks insulation resistance - Google Patents

Abstract

The invention relates to electrical measurements, namely to the measurement of the insulation resistance of electrical networks, which are under operating voltage or de-energized. The purpose of the invention is to reduce the measurement time and increase the accuracy of measurements in extensive electrical networks with high capacitance and variable structure. The method consists in charging the network capacity to the earth with a constant current of a constant value up to the value of a predetermined voltage value, disconnecting the current source of a constant value, connecting a source of measuring constant voltage of a predetermined value, and measuring the leakage current, then repeating A measurement cycle with a change in the polarity of the voltages on the network capacitors is observed. 2 Il.

Description

The invention relates to electrical measurements, namely to measurements of the insulation resistance of electrical networks, which are under operating voltage or de-energized, and the network voltage can be either constant or variable.

A known method for measuring the insulation resistance of electrical networks, which implies that a single jump of the measuring voltage is applied to the network, the time when the specified voltage reaches the extremum at the insulation impedance is recorded, the magnitude of the voltage drop from the active component of the measuring current is measured. the voltage across the impedance of the insulation is

the ratio with the reference (reference) value of the voltage drop from the active component of the total current and determine the value of the insulation resistance using the derived calculation formula. The main advantage of this method is to increase the speed of the insulation resistance measuring devices.

However, an increase in speed contributes to a decrease in measurement error, since it reduces the probability of changes in both the insulation resistance and the network capacity due to the connection and disconnection of consumers during the measurement.

There is also known a method for measuring the insulation resistance, which consists in connecting to the monitored network of the VOP |

WITH

V |

CJ

ON SA)

power source of DC voltage, performing its regular switching in such a way that switching times are not correlated with changes in the voltage of the monitored network, and determining the insulation resistance value of the network based on the sum of the voltage values at the measuring point measured at the moments preceding the switching . The method is characterized by the ability to measure the insulation resistance of both de-energized networks and networks under constant or alternating voltage.

However, this method has a significant drawback, which consists in its low speed. This is due to the fact that after each switching of the auxiliary DC voltage source, the voltage measurement at the measuring point can be made only through an interval sufficient to recharge the network capacitances and only then make the next commutation. Since the network capacity can reach several hundred microfarads, the measurement time of the network insulation resistance can be several tens or even hundreds of seconds. This is often unacceptable since, due to the possibility of the consumers being connected or disconnected during the measurement, there can be an unacceptably large measurement error.

Closest to the invention is a method implemented in a device for monitoring the insulation resistance of a DC network based on measuring the leakage current through the insulation from an auxiliary DC power source. In order to shorten the cycle of operation of the measuring converter, a second auxiliary source of direct current was introduced, which, together with the additional diagonal, provides automatic compensation for the unbalance of the four-arm bridge of the measurement circuit. In a bridge circuit for measuring the insulation resistance of a DC network, there are two stages in the operation of the measuring converter; balancing the measuring bridge by moving the movable contact of the potentiometer connected to the grounding, and the fixed contacts of the potentiometer are connected to the poles of the monitored network; measurement of leakage current under the action of an auxiliary measuring voltage source included in the measuring bridge diagonal after its balancing.

The reduction of the operating cycle of the measuring transducer according to this method is achieved by eliminating the first stage of operation from the measurement process

- balancing the measuring bridge. A sensor (current rectifier in the additional diagonal of the bridge — winding of the measuring transformer) is used to automatically balance the measuring bridge. This makes it possible to continuously receive signals on the value of the insulation resistance according to the results of the evaluation of the value of the current flowing under the action of an auxiliary DC voltage source. In the description, this source is called a DC source, which is natural, since in usual terminology any voltage source, in particular, batteries, can be called a DC source.

However, it uses the usual constant voltage source under the action of which a leakage current flows through the insulation I, defined by the expression

I E / R + RBH,

where E is the voltage of the auxiliary source;

0 RBH is the resistance of the measuring circuit of the measuring converter; R is the desired insulation resistance. On the scale of calibration, depending on the current I, the resistance of the insulation is determined R. The second auxiliary source of constant voltage does not have a special function in the formation of the measuring process; it is intended to create the necessary initial conditions

0 work summing transformer.

When using devices based on this method, the cycle time of the transmitter is reduced. However, in networks with a large capacity relative to the earth (hundreds of microfarads), the method in question does not provide the necessary speed; at connection of any receiver of the electric power

0 transition process in the measuring circuit can reach tens of seconds.

The purpose of the invention is to reduce the measurement time and improve the accuracy of measurements of the insulation resistance in

5 branched electrical networks with a large network capacity and variable structure.

This goal is achieved by the fact that in the method of measuring the insulation resistance of electrical networks, based on measuring the leakage current through the insulation from an auxiliary source of a constant measuring voltage, it is first charged to the network with respect to the earth by a constant current of set the voltage value, then disconnect the current source of a constant value, connect the source of the measuring DC voltage to the specified value and measure the leakage current, then the measurement cycle is repeated with the polarity of the voltage across the network capacitors and the measurement results are processed, and the number of measurement cycles depends on the type of current of the monitored network.

FIG. 1 shows a diagram explaining the principle of the proposed method; figure 2 is an example of a device implementing a method.

The device consists of a key 1 connected to two keys 2 and 3 and connecting one of the power sources 4 and 5 to the network. The power sources consist of current generators 6 and 7 and voltage generators 8 and 9. These power supplies are connected to an electrical network consisting of a network voltage source 10, a load 11, resistances 12 and 13 of the insulation of the network poles, and capacities 14 and 15 of the network.

The essence of the proposed method consists in the following.

Using key 1, the power supply source 4 is connected to the network, and with the help of key 2, a current source is connected to the network, and the charging of the network capacities begins. As soon as the voltage at point a reaches the value of the voltage of the voltage source 8, with the help of the switch 2, the voltage source 8 is connected to the network and the leakage current i is changed. This leakage current contains two components: the beneficial, due to the influence of the source 8 of the voltage, and the disturbing; caused by the influence of the source 10 of the network voltage. Then, using key 1, power source 5 is connected to the network, and using key 3, a current source 7 is connected to it and the network capacitors are charged until the voltage at point a reaches source voltage 9 tension Next, connect the source 9 and measure the leakage current. This current, as well as in the previous case, contains two components. Since the polarities of the sources 8 and 9 of the voltage and voltage of the current generators 6 and 7 are opposite, it means that the useful components of the measured currents have different signs, and the interfering components (in the case of a constant voltage of the network 10) have unchanged sign and size. If we now subtract the total values of the measured leakage currents, we find that the useful components are added up and the disturbing components are subtracted and become zero. If the values of current sources 6 and 7 and voltages 8 and 9 are equal, then the described subtraction operation will double the useful component of current i, which is inversely proportional to the network insulation resistance, i.e. parallel connection of resistances 12 and 13 Thus, by performing these operations, it is possible to measure the insulation resistance of networks.

We show that the proposed method can shorten the measurement time of the insulation resistance. In the known method, auxiliary voltage E affected the network through the limiting resistance R and the voltage at the measuring point changed according to the law.

u -ERTfc-o-e STi Tc

The measurement can be carried out after the end of the transient processes, i.e.

R RHS

(R // RM3) C 5C0)

R + Kiz

In the proposed method (Fig. 1), the voltage at the measuring point varies according to the law

Uc (t) I Rna (1 - e).

The connection of the voltage source can be made when the voltage at the measuring point reaches (as in

R

previous case) level Е „-,

to

rr-- t2

i.e.

- I Reese (1 - e kiz with

R I RHS

Transform this expression, we get t2 RH3Clu 1- | (R | M

Using the decomposition of the logarithmic function in the series, we get

t2 RHS C I (R + Reese)

+

-...

2 / I2 (R + RM3) 2 3fl3 (R + RM3) 3 If the value of current I in the proposed method is the same as the maximum current value in the method, taken as a prototype, i.e. J E / R, then we get

 WITH

R

R

R + Rn 2 (R + Rmy

+

+

Rj

6 (R + Reese) 3 (2)

If you select the value of current i significantly

greater than the value of E / R, i.e. | then

to

will get

TCR + RMS)

t21 -Rn3C

 1 therefore

SSTR) (3) Let us determine the measurement time values for all three cases from expressions (1-3) with the following network parameters: Е 100 V, R ЮкОм, Rn3 100 кОм, С 100 microfarads, (1 А (for the third case). We get

ti 4.5 s; t2 0.9 s; t2 0.009 s. Thus, the proposed method of measuring the insulation resistance makes it possible (by several orders of magnitude) to shorten the measurement time. Moreover, it is advisable to take a current generator of large magnitude (for example, as in the considered example in the third case). In this case, after time t2, a voltage source is connected to the mains and the leakage current is measured, then the measurement process is repeated with a change in the current generator current direction and a change in the polarity of the voltage. Thus, the whole process of measuring the insulation resistance (at a constant voltage of the monitored network) will be for values of approximately 20 ms in the example, while in the method, taken as a prototype, it will exceed 9 s.

The accuracy of connection and disconnection of consumers in a monitored network over such a period of time is small, which leads to an increase in the measurement accuracy of the insulation resistance.

In addition, if, for example, it is sufficient to measure the insulation resistance no more than once per second, then with a measurement time of 20 ms, the measuring device is connected to the network for only 1/50 hours of the network operation time. Thus, most of the time, the measuring device is not connected to the network and the network operates in natural mode, which significantly increases the reliability of its operation.

The proposed method can be implemented, for example, by a device whose schematic diagram is shown in FIG. 2

The device consists of keys 1,2 and 3, current generators 4 and 5, voltage generators 6 and 7, reference resistances 8 and 9, comparison device 10, leakage current meters 11 and 12, computing device 13, output device 14 and synchronizer 15 The electric network consists of a source 16 of a network voltage, a load 17, capacitances 18 and 19 of the network, resistances 20 and

21 isolations

The device works as follows.

The synchronizer 15 connects the source 4 current to the monitored network using switches 1 and 2, and the capacitances of the networks 18 and 19 begin charging. As soon as the voltage at point a reaches a predetermined value equal to the value of source voltage 6, which is determined by device 10 compare, key

5 2, controlled by the comparison device 10, connects the voltage source 6 to the network, and the leakage current i flowing through the voltage source 6 and the reference resistance 8 is measured. This current

0 leakage creates a voltage drop across resistance 8, which is measured by a leakage current meter 12. After measurements are taken, the synchronizer 15 changes the state of the key 1 in such a way that through

5, switches 1 and 3, a current source 5 is connected to the mains, the current direction of which is opposite to the current direction of generator 4, and recharging of network capacitances occurs again. As soon as the voltage at point a reaches

0 values of a voltage equal to the value of the voltage of the generator 7 (usually the magnitudes of the current and voltage of the generators 4 and 5 of the current and the generators 6 and 7 of the voltage are taken equal in absolute

5) the comparison device 10 uses a voltage generator 7 to the network using a switch 3, and a leakage current meter 11 measures the voltage drop on the reference resistance 9, which

0 proportional to leakage current i. Computing device 13 forms the difference between two measured leakage currents, and this value, as shown in the description of the method, is inversely proportional to 5 (in the case of constant voltage of the monitored network 16), the insulation resistance of the network, which is indicated by the output device. If the network voltage is variable, then

0, a greater number of the described measurement cycles and in the computing device 13, the results of these measurements are summed up, and the sum value uniquely determines the resistance value of the network insulation, which is displayed by the output device.

The tests of the prototype, which occurred under conditions close to natural, confirmed the correctness of the drift technical solutions, which

allowed to reduce the measurement time, improve the measurement accuracy of the insulation resistance of the network and improve the reliability of the monitored network.

The proposed method for measuring the insulation resistance makes it possible to measure rapidly the resistance of the insulation of networks both de-energized and under direct or alternating voltage. Moreover, most of the time, the measuring device may not be connected to the network, which makes it possible to increase the reliability of the monitored electrical network.

Claims (1)

The invention The method of measuring the insulation resistance of electrical networks, based on 0 five measuring leakage current through an insulation from an auxiliary DC voltage source, characterized in that, in order to shorten the measurement time and increase the accuracy of measurements in extensive electrical networks with a large capacity and variable structure, the network’s capacity relative to the ground is charged a constant current of a constant value to the magnitude of a predetermined voltage value, then disconnecting a current source of a constant value, connecting a source of measuring constant voltage of a predetermined value Cheney and carried out measurement of the leakage current, and then measuring cycle is repeated with changing the polarity of voltages to the capacitances x network. Fig 1