KR19990030861U - Ground fault detection system of power system - Google Patents

Abstract

The present invention was made in order to improve the problems of the existing ground fault detection system to obtain cost reduction, convenience and reliability of installation operation, by forming and connecting the neutral wire current transformer (3) to the neutral wire of the current transformer (2), By providing a connection in which the other end of the neutral current meter current transformer 3 is connected to the output side of the ground fault detection unit 4, it is possible to prevent the problem of installation in the van due to the increase of the existing volume, and the malfunction at high cost and unbalanced load. have.

Description

Ground fault detection system of power system

The present invention relates to the ground fault detection, and more particularly to the ground fault detection system of the power system for the effective ground detection of the three-phase four-wire power system.

The detection method of the conventional ground fault detection system is demonstrated using FIG.1 and FIG.2.

1 illustrates a ground fault detection method using an image current transformer (9; ZCT). First, each phase (R, S, T) of the power bus (1) is connected to a current transformer (2; CT) for each phase. Each phase (R, S, T) and neutral wire (O) of the power bus (1) pass through the image current transformer (9; ZCT), and the neutral wire of the instrument current transformer (2) is a current test. It is connected to the AS (7; AMPERE SELECT SWITCH) via the terminal (5; CTT), and each phase (R, S, T) of the current transformer (2) for this instrument is respectively a meter / relay (6; W, PF). , VA, WH, OCR, ... are connected to the AS 7, and an ammeter 8 is connected to the AS 7.

In addition, each phase (R, S, T) and the neutral line (O) of the power bus (1) is provided so as to pass through the mode image current transformer (9 (ZCT)), both ends of the image current transformer (9) is a ground fault detector ( It is connected to input part of 4).

Therefore, if a current flows through the load line passing through the image transformer 9, this current generates a secondary induced current in the image transformer 9, and there is no ground fault, that is, each phase (R) under a three-phase balanced load. , S, T), and the sum of the currents induced by the neutral line O is zero. If a ground fault occurs, the ground current flows through the ground, so that the secondary current induced in the image current transformer 9 is unbalanced at zero, so that a current proportional to the amount of ground current flows in the image current transformer 9. The ground detection unit senses this current to detect the ground fault.

However, the method using the current transformer 9 has to pass through each of the phases (R, S, T) and the neutral line (O) of the power bus (1), so that the thickness of the power bus (1) The thicker (large-capacity), the larger the diameter of the image transformer 9 should be. Therefore, the cost of the current transformer 9 itself is not only expensive, but also has a disadvantage in that installation is difficult because of its large volume even when installed in the van.

2 shows a ground fault detection method using the current transformer 2 for the instrument, and the basic structure is the same as that of FIG. 1, except that the current transformer for each phase (R, S, T) except the neutral line of the power bus 1 is used. (2) is provided, the Y-wire is connected, and the neutral wire is connected to the input of the ground fault detection unit 4.

Therefore, when load current flows in each phase (R, S, T), a secondary organic current will generate | occur | produce in the current transformer 2 installed in each phase (R, S, T). The neutral wire of the instrument current transformer 2 has a sum of zero at three-phase balanced loads as in FIG. If a ground fault occurs, the ground current flows through the ground, so the flat state is broken in the neutral wire, and the current flows in proportion to the amount of the ground current in the neutral wire. Is to detect the ground fault.

However, since the three-phase type is a theoretical value, even if it is not actually a ground fault, the three-phase equilibrium may not be achieved by the loads placed on the power bus 1, that is, an unbalance may occur. Since a current of about a minute flows through the neutral line of the current transformer 2 of the instrument, there is a disadvantage in that the ground fault detector may operate even in the case of a ground fault.

The present invention has been made to solve the above problems, cost saving and easy installation operation by improving the difficulty of installation in the class and the high cost, especially the large volume during installation, which is a problem of the ground fault detection system using the image current transformer The purpose of the present invention is to provide a ground fault detection system of a power system that improves reliability by improving the malfunction under unbalanced load, which is a problem of the ground fault detection method using a neutral wire of an instrument current transformer.

1 is a connection diagram of a ground fault detection system using a conventional image current transformer.

2 is a connection diagram of a ground fault detection system using a neutral wire connected to a current transformer of a conventional instrument;

3 is a connection diagram of a ground fault detection system according to the present invention.

(Explanation of symbols for the main parts of the drawing)

1-tension bus, 2-current transformer (CT),

3-instrument current transformer (CT), 4-ground fault detector,

5-Current Test Terminal (CTT), 6-Instrument / Relay

7-AS (AMPERE SELECT SWITCH), 8-ammeter,

9-current transformer (ZCT).

In order to solve the above problems, the present invention adopts the following configuration.

Instrument current transformer 2 is Y-connected to each phase R, S, and T of the power bus 1, and its neutral is connected to the input of the ground fault detector 4, and its output is connected to the current test terminal 5 Is connected to one end of the ammeter 8 through one end of the AS 7 and each of the phases R, S, and T of the current transformer 2 for the instrument. In the ground fault detection system connected to the other end (8) of the ammeter through the other end of (7), a neutral wire current transformer (3) is molded and connected to the neutral wire of the current transformer (2). It is characterized by including the connection which connected the other end of (3) to the output side of the ground fault detection part 4. It is characterized by the above-mentioned.

(Example)

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIG. 3.

First, each phase (R, S, T) of the power bus 1 is Y-connected with a current transformer (2; CT) for each phase, and each phase (R, S, T) of this power bus (1) And the neutral wire (O) are to pass through the image current transformer (9; ZCT), the neutral current of the current transformer (2) for instrument current transformer (3) for the neutral current sensing of the power bus (1) is installed, One end thereof is commonly connected to one end of the current transformer 2 for the instrument and the input side of the ground detection unit 4, and the other end is common to the output side of the ground detection unit 4 and the input side of the current test terminal 5. The output side of the current test terminal 5 is connected to the AS 7 (AMPERE SELECT SWITCH) via the current test terminal 5 (CTT). In addition, each phase R, S, and T of this current transformer 2 of this instrument is connected to AS7 through the meter / relay part 6, and the ammeter 8 is connected to this AS7. Connected.

Therefore, when a current flows through the power bus 1, secondary currents proportional to the current transformer 2 and the neutral current meter current transformer 3 installed in each line are generated. Is transmitted to the AS (7) through the various instruments and relays of the meter / relay unit (6). The AS 7 sends only one of the currents to the ammeter 8 and the other two currents flow to the common line C42 of the AS 7. In addition, the current sent to the ammeter 8 by the AS 7 also flows through the ammeter 8 to the common line C42 of the AS 7 in the same manner.

The current I _{C42 at} this time becomes the vector sum of the secondary currents of the respective phases R, S, and T held by the current transformer 2 for the instrument.

That is, I _C42 = I _C10 + I _C20 + I _C30 .

If an unbalanced load occurs and a current flows through the neutral line O of the power bus 1, a secondary current is generated in proportion to the current transformer 3 of the neutral wire. The current I _C42 , which is the vector sum of the secondary currents for T), flows to the input terminal of the ground fault detection unit 4. At this time, the current L _G flowing through the input terminal of the ground fault relay is a vector sum of the currents generated in the instrument current transformer 2 and the neutral current transformer current transformer 3.

That is, I _G = I _C42 + I _C41 = I _C10 + I _C20 + I _C30 + I _C41 .

Therefore, since the vector sum of the current I _G flowing through the input of the ground fault detection unit becomes zero even under unbalanced loads, the ground fault current flows through the earth when a ground fault occurs in the power bus 1. Therefore, the current flows in proportion to the ground fault current through the input of the ground fault detector, thereby detecting the ground fault.

On the other hand, the reference numerals in the drawings written in the constituent requirements of the utility model registration claims of the present application to facilitate the understanding of the present invention, and the intention to limit the technical scope of the present invention to the embodiment shown in the drawings It is not.

According to the present invention, it is possible to obtain cost saving and convenience of installation operation by improving the difficulty of installation due to the increase of volume and the increase of cost according to the installation of the current transformer, which is a problem of ground fault detection using the image transformer. As a result, it is possible to improve the reliability of the fault in the unbalanced load, which is a problem of the ground fault detection using the neutral wire of the current transformer of the instrument.

Claims (1)

Instrument current transformer 2 is Y-connected to each phase R, S, and T of the power bus 1, and its neutral is connected to the input of the ground fault detector 4, and its output is connected to the current test terminal 5 Is connected to one end of the ammeter 8 through one end of the AS 7 and each of the phases R, S, and T of the current transformer 2 for the instrument. In the ground fault detection system connected to the other end 8 of the ammeter through the other end of (7), Formed connection of the neutral wire gauge current transformer (3) to the neutral line of the instrument current transformer (2), and the other end of the neutral wire gauge current transformer (3) connected to the output side of the ground fault detection unit (4) Ground fault detection system of power system.