RU2271016C1 - Method for determining isolation parameters for network with solidly grounded neutral with voltage up to 1 kv - Google Patents

Abstract

FIELD: electric engineering, possible use in construction of networks with solidly grounded neutral with voltage up to 1 kV.

SUBSTANCE: method includes measuring voltages, currents and phases of secondary winding of voltage transformer, current value in neutral of force transformer, and also phase of this current relatively to voltage of secondary winding of voltage transformer. All measurements are performed at increased signal frequency in comparison to industrial level. Complexes of full conductivities of phase insulations relatively to ground are determined on basis of appropriate mathematical formulae.

EFFECT: expanded functional capabilities of method due to measuring additional parameters of network.

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Description

The method relates to electrical engineering and can be used in networks with a grounded neutral voltage of up to 1 kV.

A known method of determining the parameters of the insulation of the phases of the network with an isolated neutral, including applying voltage from an independent power source connected in series with the current-limiting element between the ground and the zero-sequence voltage filter (FNNP), as well as registering the current values in each branch of the FNP and the phase of these currents relative to the voltage power source with the subsequent determination of the total insulation resistance of the phases according to well-known expressions (see AS No. 1780044, MKI G 01 R 27/18. - Publ. Bulletin No. 45, 1992).

The disadvantage of this method is the impossibility of its application to determine the parameters of the insulation of the phases relative to the ground in a network with a grounded neutral.

The technical result of the invention is the expansion of the functionality of the method by measuring additional network parameters.

This result is achieved in that in the method for determining the insulation parameters of a network with a grounded neutral voltage of up to 1 kV, including measuring the voltage, as well as the currents and phases of the secondary winding of the voltage transformer, while the secondary winding is connected to a star and connected to the network, the star’s zero point is grounded through a current-limiting element, and the primary winding is connected to a high-frequency signal generator, the current value in the neutral of the power transformer is additionally measured, as well as the phase of this current Tel'nykh voltage secondary winding of voltage transformer and complexes admittance phase insulation relative to the earth is determined by the expressions:

where Ya, Yb, Yc are the complexes of the total conductivities of insulation of phases A, B, C of the network, respectively, Cm;

E is the voltage at the terminals of the secondary winding of the additional voltage transformer (the initial phase is assumed to be zero), V;

Y0 — complex of full conductivity of the current-limiting element, cm;

Ia, Ib, Ic - currents in the secondary winding of an additional voltage transformer, A.

The value of Yе is determined from the expression:

where Y _N is the neutral grounding conductivity complex of the power transformer, cm;

Y _T - conductivity complex of the windings of a power transformer, see

The essence of the invention lies in the fact that in the method for determining the insulation parameters of a network with a grounded neutral, in addition to measuring the voltage, as well as the currents and phases of the secondary winding of the voltage transformer, they additionally measure the current value in the neutral of the power transformer, as well as the phase of this current relative to the voltage of the secondary winding of the voltage transformer, in this case, all measurements are carried out at a higher signal compared to the industrial frequency.

Measurement of the current value in the neutral of the power transformer, as well as its phase relative to the voltage of the secondary winding of the voltage transformer, allows you to take into account the fraction of the current flowing through the neutral of the power transformer, which makes the method applicable in networks with a grounded neutral.

The use of an increased frequency signal for measuring insulation parameters makes it possible to reduce the influence of external interference at the industrial frequency and to reduce the fraction of current flowing through the power transformer, and therefore, to increase the measurement accuracy.

Figure 1 shows a device for implementing the method for determining the insulation parameters of a network with a grounded neutral.

The device contains a power transformer 1, neutral grounding of the power transformer R, voltage transformer 2, current limiting element 3 with parameters Z0, high frequency signal generator 4, current transformers 5-8, bandpass filters 9-12, voltmeter 13, milliammeters 14-17, phase meters 18-21. Figure 1 also shows the active Ra, Rb, Rc and capacitive Xa, Xb, Xc components of the insulation resistance of the phases relative to the ground.

The method is implemented as follows by the example of the operation of the device.

The signal of increased frequency from the generator 4 is supplied to the network through a voltage transformer 2, the secondary windings of which are connected to the phases of the controlled network, and their zero point is grounded through a current-limiting element 3. The signal generator 4 is loaded on the primary winding of the voltage transformer 4. The voltage on the secondary winding of the transformer 2 is measured voltmeter 13. The currents in the secondary windings of the additional transformer are measured using current transformers 5-8, loaded on ammeters 14-17 through bandpass filters 9-12, sl narrower to emphasize the high frequency signal. The current is also measured at an increased frequency in the neutral of power transformer 1. In addition, phase meters 18-21 are introduced into the circuit to measure the phase shift between currents in the secondary windings of transformer 2 (as well as in the neutral of transformer 1) and the voltage on the secondary winding of transformer 2.

The insulation parameters relative to earth are taken concentrated, the longitudinal active and inductive resistances of the phase conductors are not taken into account, the interphase active and capacitive resistances are infinitely large.

The calculated equivalent circuit of this network, shown in figure 1, for non-industrial frequency currents is presented in figure 2. Considering that due to the introduction of bandpass filters, currents in the network are measured only at the frequency of the operational signal, phase EMFs at a frequency of 50 Hz are not taken into account in the circuit. The windings of the power transformer are presented in the form of complex resistances Zt1, Zt2, Zt3. The secondary windings of the additional transformer are presented in the form of resistances Z1, Z2, Z3 and EMF E1, E2, E3. The neutral resistance of the power transformer is taken active and equal to R.

For further calculations, the scheme is converted taking into account the following assumptions:

- EMF E1, E2, E3 are equal in phase and amplitude, that is, E1 = E2 = E3 = E = Eg / Kt (Eg is the EMF of the signal generator, KT is the transformation coefficient of the additional transformer);

- resistance Zt1 = Zt2 = Zt3 = Zt;

- Resistances Z1, Z2, Z3 are taken in magnitude much less than the resistances Zt and Za, Zb, Zc and, accordingly, are not taken into account.

A simplified design diagram is shown in figure 3.

The system of equations for the potentials of points 1 and 3 has the form:

Where

From this system:

Points Ia, Ib, Ic are defined as:

после преобразований выражений получим систему из трех уравнений с тремя неизвестными относительно величин Ya, Yb, Yc:The sum Y _T + G can be denoted by Y _N. Then, taking into account the fact that the currents Ia, Ib, Ic are known from the measurement results

after transformations of the expressions, we obtain a system of three equations with three unknowns with respect to the quantities Ya, Yb, Yc:

Having solved the system, we get:

Where

Knowing the complexes of full insulation conductivities, it is possible to determine the active and capacitive insulation resistances of phases relative to the ground:

The proposed method in comparison with the prototype allows the process of measuring the insulation parameters in networks with earthed neutral, which helps to increase the level of electrical safety during the operation of this type of network.

Claims (1)

A method for determining the insulation parameters of a network with a grounded neutral voltage of up to 1 kV, including measuring voltage, as well as currents and phases of the secondary winding of the voltage transformer, while the secondary winding is connected to a star and connected to the network, the star’s zero point is grounded through a current-limiting element, and the primary winding connected to a high frequency signal generator, characterized in that it additionally measures the value of the current in the neutral of the power transformer, as well as the phase of this current relative to the voltage the secondary winding of the voltage transformer and the complexes of the full conductivities of the insulation of the phases relative to the ground are determined by the expressions

where Ya, Yb, Yc are the complexes of the total conductivities of the insulation of the phases, A, B, C of the network, respectively, cm; E is the voltage at the terminals of the secondary winding of the additional voltage transformer (the initial phase is assumed to be zero), V; Y0 — complex of full conductivity of the current-limiting element, cm; Ia, Ib, Ic - currents in the secondary winding of an additional voltage transformer, A.

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