RU2554308C1 - Ac mains isolation resistance measurement device - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device contains a source of measuring voltage, milliamperemeter, a galvanic isolation unit, a subtracting unit, a control unit, a control AC voltage source, a first key, a second key, a current-limiting resistor. Two inputs of the galvanic isolation unit are connected to two phases of the monitored network between which there is AC voltage. The output of the galvanic isolation unit is connected to the second input of the control unit the output of which is connected to the input of the controlled AC voltage source the first output of which is connected to the second terminal of the current-limiting resistor the first terminal of which is connected to the second output of the measuring voltage source. The second output of the controlled AC voltage source is connected through the milliamperemeter to earth. The first output of the measuring voltage source through the first key is connected to any phase of the monitored network. The first input of the subtracting unit is connected to the first output of the controlled AC voltage source, and the subtracting unit output through the second key is connected to the first input of the control unit.

EFFECT: reduction of error and time of measurement of isolation resistance.

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Description

The invention relates to electrical engineering and is intended to measure the insulation resistance of AC electrical networks that are energized and isolated from the ground.

A device for measuring the insulation resistance of a network [A.S. USSR No. 118896, class 21e, 29 ₀₁ , 21e, 36 ₁₀ , 59], the operation of which is based on finding equipotential points on a potentiometer connected between the wires of the network using a high-resistance measuring device, which is connected to the electric circuit in series with an auxiliary DC source and a specified motor potentiometer.

In this device, using the potentiometer slider, the zero potential is searched, so that the mains voltage does not affect the measuring circuit.

However, the disadvantage of this device is the long measurement time if the capacitance of the phases relative to the ground is large. With a very large phase capacity relative to earth, measurements become inappropriate, therefore, the device has limited functionality. In the process of measurement, after connecting the auxiliary DC source, it is necessary to wait for the time until the capacitance of the network phases relative to earth is charged. The time constant of the capacitance charge circuit depends on the magnitude of the total phase capacitance and on the resistance of the potentiometer. To obtain a small time constant, at first glance, it is possible to reduce the resistance of the potentiometer, while the current flowing through the potentiometer increases, the power dissipated by the potentiometer increases, and reliability decreases.

The closest in technical essence to the proposed invention (prototype) is a device [Ivanov EA, Kuznetsov S.E. Methods of monitoring the insulation of ship electrical systems. Tutorial. - SPb .: “Elmore”, 1999. p. 49, 50] for measuring insulation resistance in AC networks, the principle of which is based on the method of applying a constant measuring voltage. The device contains an inductive or capacitive filter R ₁ , C _f , a measuring voltage source E, milliammeter A. The filter R ₁ , C _{f is} necessary due to the fact that an alternating voltage component acts at the point of connection to the controlled network, and for measurements it is necessary to eliminate the influence of the variable component of the voltage on the measuring circuit.

The disadvantage of this device is the long measurement time if the capacitance of the phases of the network relative to the ground is large. With a very large phase capacity relative to earth, measurements become inappropriate, therefore, the device has limited functionality. The duration of the transients that occur when applying a constant measuring voltage is directly proportional to the resistance R ₁ and the capacitance of the network phases relative to the ground. If to reduce the measurement time to reduce the resistance R ₁ to reduce the transient process, then due to the fact that a large alternating voltage is applied to it, the power dissipated on it will increase. This reduces reliability. In addition, if the resistance R _{1 is} reduced, the influence of the variable component of the voltage on the measuring circuit will increase, that is, the alternating component of the current in the measuring circuit will increase, and the error will increase.

The objective of the invention is the expansion of functionality. The technical result consists in reducing the error and time of measuring the insulation resistance.

The problem is achieved due to the fact that the device for measuring the insulation resistance of AC networks, containing a measuring voltage source, a milliammeter, additionally includes a galvanic isolation unit, a subtraction unit, a control unit, a controlled AC voltage source, a first key, a second key, and a current limiting resistor moreover, two inputs of the galvanic isolation unit are connected to two phases of the controlled network, between which an alternating voltage acts, the output of the galvanic unit The isolation is connected to the second input of the control unit, the output of the control unit is connected to the input of a controlled AC voltage source, the first output of which is connected to the second output of a current-limiting resistor, the first output of which is connected to the second output of the measuring voltage source, the second output of the controlled AC source is connected through a milliammeter to earth, the first output of the measuring voltage source through the first key is connected to any phase of the controlled network, the first input is the subtraction lock is connected to the first output of the controlled AC voltage source, the output of the subtraction block through the second key is connected to the first input of the control unit.

Figure 1 shows a diagram of a device 1 connected to a monitored network 2. Figure 2 and figure 3 are timing diagrams explaining the principle of operation of the proposed device 1.

The device 1 contains a galvanic isolation unit 3, a subtraction unit 4, a control unit 5, a controlled AC voltage source 6, a milliammeter 7, a measuring voltage source 8, a current-limiting resistor 9, a first switch 10, a second switch 11. A controlled network 2 contains voltage sources 12, 13, 14 load resistance 15, 16, 17, insulation resistance of each phase 18, 19, 20, capacitance of each phase 21, 22, 23. Two inputs of the galvanic isolation unit 3 are connected to two phases of the controlled network 2, between which an alternating voltage . The output of the galvanic isolation unit 3 is connected to the second input of the control unit 5. The output of the control unit 5 is connected to the input of the controlled AC voltage source 6, the first output of which is connected to the second output of the current-limiting resistor 9, the second output of the controlled AC source 6 is connected through a milliammeter 7 to the earth. " The first output of the current-limiting resistor 9 is connected to the second output of the measuring voltage source 8. The first output of the measuring voltage source 8 is connected through any first phase 10 to any phase of the controlled network 2. The first input of the subtraction unit 4 is connected to the first output of the controlled AC voltage source 6, the output of the subtraction unit 4 through the second key 11 is connected to the first input of the control unit 5.

Device 1 operates as follows. The device 1 is periodically connected to the monitored network 2, measures the equivalent insulation resistance of the network, then turns off. In the off state, the first key 10 is open, the second key 11 is closed. In the connected state, the first key 10 is closed, the second key 11 is open.

Consider the operation of the device 1 in the off state, while preparing for the measurement. The input of the galvanic isolation unit 3 receives an alternating voltage with a network frequency. (The galvanic isolation unit 3 can be performed, for example, in the form of a transformer or in the form of an optocoupler isolation circuit.) From the output of the galvanic isolation unit 3, the synchronizing signal is supplied to the second input of the control unit 5. This signal in the simplest case can have a sinusoidal shape, but in in the general case, it may differ from a sinusoid, and be, for example, rectangular pulses. The control unit 5 generates a control signal for a controlled source of alternating voltage 6, which can create a sinusoidal voltage, with amplitude and phase varying over a wide range. The control unit 5 generates such a control signal at its output so that the voltage of the controlled alternating voltage source 6 becomes exactly equal in amplitude and phase to the voltage at the connection point relative to the ground U _c (mains voltage), Fig.2. In order to be able to compare the voltage of the controlled source of alternating voltage 6 with the mains voltage U _c , a subtraction unit 4 is designed. These two voltages are applied to its outputs, the subtraction unit subtracts the instantaneous values of these two voltages, and a signal equal to the difference of these two stresses. The signal from the output of the subtraction unit 4 through the second switch 11 is fed to the first input of the control unit 5. Thus, in the off state of the device 1, preparation is made for the measurement, namely, that the voltage of the controlled AC source 6 E _per becomes exactly equal to the voltage U _c . The algorithm by which the control unit 5 operates is beyond the scope of the present invention. Here, we note that the signal at the output of the control unit 5 is formed by converting the clock signal supplied to the second input. At the same time, the control unit seeks to minimize the difference U _c and E _per .

Consider the operation of the device 1 in the connected state, while measuring the equivalent insulation resistance. The second key 11 is opened, therefore, the first input of the control unit 5 does not receive a signal equal to the difference U _c - E _per . As a result, the amplitude and phase of the controlled AC voltage source 6 remain unchanged during the measurement time. After the first key 10 is closed, a transient occurs with a very small time constant τ, which mainly depends on the resistance of the current-limiting resistor 9 and the total capacitance of the phases of the network 21, 22, 23 relative to the ground. The resistance of the current-limiting resistor 9 is very small (less than 1 Ohm), so the transition time constant is also small. Therefore, the measurement time is reduced. A decrease in the resistance of the current-limiting resistor 9 became possible (compared with the prototype), since it does not drop a large alternating voltage, therefore it does not heat up, except for this, a large alternating current component does not appear in the measuring circuit. Through the closed first key 10, the effect on the monitored network is effected 2. The exposure voltage is equal to the sum of E _per + E _ISM , where E _ISM is the constant voltage generated by the measuring voltage source 8. As a result, at each point in time, the voltage U _c at the value of E _{ISM is} greater than the voltage U _c in the free state of the network, Fig.3. Therefore, in addition to the alternating voltage caused by the network parameters, a constant voltage E _{ISM is} applied to the insulation resistances 18, 19, 20. As a result, a direct current will flow through the milliammeter 7, due to the voltage E _ISM and the equivalent insulation resistance of the network. Since the variable voltage component U _{c is} exactly equal to the variable voltage component U _c until the first switch 10 closes, the current flowing through the milliammeter 7 has practically no variable component with the network frequency. Due to this, the error in measuring the insulation resistance is reduced.

Thus, enhanced functionality is provided.

The technical result consists in reducing the error in measuring the insulation resistance and in reducing the time for measuring the insulation resistance of AC networks.

Claims (1)

A device for measuring the insulation resistance of alternating current networks, containing a measuring voltage source, a milliammeter, characterized in that a galvanic isolation unit, a subtraction unit, a control unit, a controlled alternating voltage source, a first key, a second key, a current limiting resistor are introduced, two input of the unit galvanic isolation are connected to two phases of the controlled network, between which an alternating voltage is applied, the output of the galvanic isolation block is connected to the second mu input of the control unit, the output of the control unit is connected to the input of a controlled AC voltage source, the first output of which is connected to the second output of the current-limiting resistor, the first output of which is connected to the second output of the measuring voltage source, the second output of the controlled AC voltage source is connected to the ground through a milliammeter, the first the output of the measuring voltage source through the first switch is connected to any phase of the controlled network, the first input of the subtraction unit is connected to vomu output controls the AC voltage source, the output of subtraction unit via the second switch is connected to the first input of the control unit.

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