RU2549974C2 - Device for compensation of capacitor currents of single-phase short circuits to earth in electric networks with insulated neutral line - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention is used in the field of electric engineering and power engineering. The device contains three windings, each is placed in a separate rod from magnetic material, "star" or "zigzag" connected the inputs each of which is connected to the respective phase conductor of the electric network, and the neutral point is connected to the input of the fourth winding with alternating inductance placed on the fourth rod from magnetic material with air gaps. The output of the fourth winding is connected to the earth, all four rods are connected by yokes from one and from another side. Yokes, connecting the rods of the first three windings are joined as two symmetric three-beam stars at an angle 120 degrees with reference to each other, and the fourth rod connects joining places of yokes. Parallel to the fourth coil the variable active and reactive resistance (inductive or capacitive) is connected. The fourth coil is designed with branches, and variable active and reactive resistance through the switching device is connected parallel to a part of turns of the fourth coil. On the fourth rod the additional fifth coil is placed and to leads of this coil in parallel with it the second variable active and reactive resistance is connected.

EFFECT: improvement of accuracy of compensation of capacitor currents of single-phase short circuits to earth and expansion of range of change of the device parameters.

4 cl, 5 dwg

Description

The technical field to which the invention relates, and the preferred area of its use

The invention relates to the field of electrical engineering and the electric power industry, in particular, to means for compensating capacitive currents in case of single-phase earth faults in electric networks with isolated neutral.

Characterization of analogues of the invention

Electrical networks with isolated and compensated neutrals have undeniable advantages in terms of the ability to transfer electrical energy to consumers even when one phase is shorted to ground. However, with a large length and with a large capacitance of the phases of this network relative to earth, the currents of single-phase earth faults reach several tens and even hundreds of amperes and pose a danger to life and can lead to intensive development of an emergency in the electric power system. An electric arc arises at the location of the damage, which is dangerous due to the thermal effect on the environment and due to the non-linear current-voltage characteristic of the electric network. In order to prevent the negative effect of single-phase faults on the earth, the capacitive currents arising from this are compensated by switching on the inductance between the neutral point of the network and the ground [1]. However, in many distribution electric networks of voltage classes from 6 to 35 kV there is no neutral point in physical form and it is not possible to connect a grounding inductance (an extinguishing coil or an extinguishing reactor).

A device is known for compensating capacitive currents in case of single-phase earth faults, in which a neutral point is created specially in an electrical network with an isolated neutral using a neutralizing transformer, and an arc suppression coil is connected between this neutral point and ground [2].

This device has disadvantages. For its implementation, it is required to install two separate elements in the electric network at the substation (a neutral-forming transformer and an extinguishing reactor), each of which has a large mass and overall dimensions. Connecting cables or busbars, switching devices and separate foundations are required. All this creates inconvenience during installation and operation.

Description of the prototype selected by the applicant

The closest technical solution is a device for compensating capacitive currents during single-phase earth faults in electrical networks with an isolated neutral, containing three windings, each of which is placed on a separate rod of magnetic material, connected by a star or zigzag circuit, the inputs of which each is connected to its corresponding phase conductor of the electrical network, and the neutral point is connected to the input of the fourth winding with a variable inductance, located on the fourth rod of itnogo material with air gaps, the output of the fourth winding is connected to ground, all four yokes are connected by a rod on one and three on the other side [3]. In this case, the rods are connected in yokes in series: the first with the second, the second with the third, the third with the fourth from both ends of the rods. Such a connection forms a single flat four-core magnetic circuit, on which are placed the first three coils of a neutral-forming transformer and the fourth arcing coil with a variable inductance.

Prototype criticism

A disadvantage of the known construction is the asymmetry of the magnetic system, which leads to an uneven phase distribution of magnetic fluxes and, consequently, to a displacement of the potential of the artificially created neutral point of the network relative to the actual neutral potential. This, in turn, causes errors in the compensation of capacitive currents with single-phase earth faults, and the compensation is not fully implemented.

The purpose of the invention

The aim of the invention is to increase the accuracy of compensation of capacitive currents with single-phase earth faults and expanding the range of variation of the device parameters.

SUMMARY OF THE INVENTION

This goal is achieved by the fact that in the known device containing three windings, each of which is placed on a separate rod of magnetic material, connected according to the "star" or "zigzag" circuit, the inputs of which are each connected to their respective phase conductor of the electrical network, and neutral the point is connected to the input of the fourth winding with variable inductance located on the fourth rod of magnetic material with air gaps, the output of the fourth winding is connected to the ground, all four rods are connected On one and the other hand, the order of joining the rods with yokes has been changed. In the proposed device, the yokes connecting the rods of the first three windings are docked in the form of two symmetrical three-beam stars at an angle of 120 degrees relative to each other, and the fourth rod connects the junction of the yokes. In this connection order, each end of the first three rods is connected by a separate yoke to the fourth rod, and, as a result, a symmetrical magnetic system is formed.

Additionally, to expand the regulation capabilities, a variable active-reactive (inductive or capacitive) resistance is connected parallel to the fourth coil. Connecting an external active-inductive or active-capacitive resistance parallel to the suppression coil allows you to significantly expand the range of changes in the equivalent resistance of the capacitive current compensation device.

Also, in order to expand the regulation capabilities, the fourth coil is made with taps, and the variable active-reactive resistance is connected through a switching device in parallel with part of the turns of the fourth coil.

In addition, a device for compensating capacitive currents during single-phase earth faults in electrical networks with isolated neutral is performed so that an additional fifth coil is placed on the fourth rod, and an alternating active-reactive resistance is connected to the terminals of this coil in parallel with it.

A comparative analysis of the proposed solution with the prototype showed that the claimed device differs from the known one in that it contains new connections between the individual elements of the device and new elements with new connections.

The new device is symmetrical and has a wide control range due to additional external elements (active-reactive resistances), the parameters of which can vary in a much larger range than the coil inductance. The equivalent resistance of the claimed device can be not only inductive in nature, as in the prototype, but also capacitive. Thus, the claimed device exhibits new properties that do not match the properties of known solutions, and meets the criteria of "novelty" and "significant differences".

List of figures of graphic images

Figure 1 presents a top view of the electromagnetic part of the device for compensating capacitive currents with single-phase earth faults in electrical networks with isolated neutral. The following designations are accepted: 1, 3, 5 - the first three coils of the device connected to the electrical network; 2, 4, 6 - core rods of the first three coils; 7 - the fourth coil with variable inductance; 8 - the rod of the fourth coil; 9 - yokes (6 in total, 3 on each side of the rods) connecting the ends of the rods of all coils.

Figure 2 shows a side view of the core rod, coil and two yokes. Designations of the elements correspond to those shown in figure 1.

Figure 3 shows the electrical diagram of the device as a first example implementation. Dashed lines show the magnetic circuit of the device. Here, each end of all the rods of the first three coils is connected by a corresponding yoke to the corresponding end of the rod of the fourth coil. To the conclusions of the fourth coil with variable inductance L, an active-reactive (active-capacitive and active-inductive) resistance Z is connected in parallel.

Figure 4 shows in an electrical diagram an example implementation of a device with a fourth coil made with soldering, where the external active-reactance is connected to part of the turns of the fourth coil.

Figure 5 shows in an electrical diagram another example implementation of the device, where the second external active-reactive variable resistance Z2 is connected to the terminals of the additional fifth coil.

Case Studies

The device is connected with the phase (first) terminals of the first three coils to phases A, B, C of the electric network. Each coil consists of two sections. Here, the coils are connected in a zigzag pattern. The second leads of the first three coils are connected to each other and form a neutral point. The first terminal of the fourth coil is connected to the neutral point, and the second terminal of the fourth coil is connected to ground.

In the normal symmetric mode of the electric network, the potential of the neutral point is zero and the current in the fourth arc suppression coil is practically zero.

When one phase is shorted to ground, symmetry is broken, a non-zero potential of the neutral point of the network appears, and a current appears in the fourth coil.

By changing the inductance L of the fourth coil and the parameters of the active reactance Z, a resonant tuning of the network zero sequence circuit is achieved, which includes the parameters of the network elements and the capacitive current compensation device. In this case, the current at the point of earth fault is almost zero. Thus, the most complete degree of compensation of capacitive currents is achieved using the proposed device.

Feasibility or other effectiveness of the invention

Due to the symmetry of the electromagnetic part of the device and the ability to change parameters over a wide range due to external active-reactance resistances, an increase in the accuracy of compensation of capacitive currents during single-phase earth faults is achieved in a wide range of parameters of the electrical network in which the proposed device operates.

In addition, due to the unified design of the electromagnetic part of the device, the mass-dimensional parameters of the device are improved, the conditions of design, installation and operation are improved.

Improving the technical perfection of the device allows to obtain and increase the economic indicators of the use of the device, including by increasing the reliability of power supply in general.

Information sources:

1. Likhachev F.A. Earth faults in networks with isolated neutral and capacitive current compensation. - M.: Energy, 1971, 152 p.

2. Chernikov A.A. Compensation of capacitive currents in networks with non-grounded neutral. - M .: Energy, 1974, 96 p.

3. William R. and Waters A. Grounding neutral in high-voltage systems. - M.: Gosenergoizdat, 1959, 416 p.

Claims (4)

1. A device for compensating capacitive currents during single-phase earth faults in electrical networks with insulated neutral, containing three windings, each of which is placed on a separate rod of magnetic material, connected by a star or zigzag circuit, the inputs of which are connected each to corresponding to its phase conductor of the electrical network, and the neutral point is connected to the input of the fourth winding with variable inductance, located on the fourth rod of magnetic material with air gaps, output the fourth winding is connected to the ground, all four rods are connected by yokes on one and the other side, characterized in that the yokes connecting the rods of the first three windings are docked in the form of two symmetric three-beam stars at an angle of 120 degrees relative to each other, and the fourth rod connects the places dock yokes. 2. A device for compensating capacitive currents for single-phase earth faults in electrical networks with an isolated neutral according to claim 1, characterized in that a variable active-reactive (inductive or capacitive) resistance is connected in parallel with the fourth coil. 3. A device for compensating capacitive currents during single-phase earth faults in electric networks with isolated neutral according to claim 2, characterized in that the fourth coil is made with taps, and the variable active-reactive resistance is connected through a switching device in parallel with part of the turns of the fourth coil. 4. A device for compensating capacitive currents during single-phase earth faults in electric networks with isolated neutral according to claim 2, characterized in that an additional fifth coil is placed on the fourth rod, and a second alternating active-reactive resistance is connected to the terminals of this coil in parallel with it .

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