KR200149858Y1 - Self-relay - Google Patents

Abstract

The present invention relates to a protection relay used in a power receiving facility, and in particular, in order to protect it in the event of an accident in the equipment or line of the power receiving facility, an electric power is generated by itself without using an external power source (ICS (Indicating Contact Switch)). The present invention relates to a self-regulating relay (SELF) relay, which is designed to reduce the damage to various equipment and to minimize the supply disturbance range. By providing a self-limiting (SELF) relay that prevents accidents from spreading in the normal section and improves the stability of the power meter, the present invention can be operated by an external power source. By rectifying the voltage induced in the car coil and operating the contact ICS, It protects water distribution equipment by preventing malfunction of protection relay.

Description

Self relay

1 is a schematic structural diagram of a conventional protection relay.

2 is a conventional protection relay circuit diagram.

3 is a schematic diagram of the principle of the present invention.

4 is a schematic diagram of a self (SELF) relay circuit of the present invention.

* Explanation of symbols for main parts of the drawings

10: protection relay 20: rectifier

3P3W: 3 Phase Power R.S.T: 3 Phase Power Input

V.C.B: Breaker C.T: Current Transformer

1-COIL, 2-COIL, 3-COIL: 1st, 2nd, 3rd Coil

ICS1, ICS2, ICS3: Contact D1-D4: Rectifier Diode

1-COIL, 2-COIL, Disc: Main Coil

The present invention relates to a protection relay used in a power receiving facility, and in particular, in order to protect it in the event of an accident in the equipment or line of the power receiving facility, an electric power is generated by itself without using an external power source (ICS (Indicating Contact Switch)). It relates to a self (SELF) relay to drive the.

FIG. 1 is a conventional structural diagram of a protective relay. As shown in FIG. 1, a torque is generated on an aluminum disc due to an induction action of a rotating magnetic field or a moving magnetic field, and a magnetic flux Φ 1 is generated by the input of the coil 1, and at the same time, the driving force E2 by the coil 2 Input I2 of phase and magnitude according to impedance flows to coil 2 and magnetic flux Φ2, which is out of phase with Φ1, is generated and operates. In addition, withstand torque depends on hair spring, so if the operation time of disc is long, hair spring and withstand As the torque decreases, the groove is inserted into the disc to compensate for this.

FIG. 2 is a circuit diagram of a conventional protection relay, in which a three-phase power source is connected to a breaker VCB through an RST, and the breaker VCB is connected to a load of the three-phase power source through a current transformer CT. Current transformers CT1 and CT2 are connected to terminals 4 and 5 of the protective relay 10, and terminals 4 and 5 of the current transformer CT2 are connected to the primary coil 1-COIL, and the current transformer CT1 is connected. Connected to terminals 4 and 5, the disc contact (a) is connected to terminal 10 of the contact (ICS1), the main contact (b) is connected to the third contact coil (3-ICS COIL) and the contact (ICS1) The battery power is connected to terminal 10 of the terminal and the contact ICS1 connected to the terminal 9 of the protective relay 10 is connected to the circuit breaker VCB.

The power system is composed of several power plants, substations and transmission and distribution lines connecting them, and supplies power to the load, and a circuit breaker that cuts power to the load in case of a line accident when power (three-phase power: 3P3W Source) is supplied to the distribution line. VCB), when the power system breaks down, the equipment is damaged and the supply and demand balance is broken.

On the other hand, if the fault of the power system is a short-circuit fault, the voltage at the fault point is shorted to almost 0 V, so that a large short-circuit current flows in the line. At this time, a current is generated at the secondary side of the current transformer CT so that 4 of the relay 10 is generated. The current flows through the primary coil (1-COIL: main coil) through terminal 5, and the secondary coil (2-COIL) generates current.

In addition, the role of the secondary coil (2-COIL) is to allow the aluminum disc to rotate normally and adjust the rotation speed of the disc, the disc rotates when the current flows into the primary coil (1-COIL: main coil), At this time, the disc contact (a) and the main contact (b) is short-circuited to send a predetermined signal to the breaker (VCB) using an external power source (battery) to cut off the power supply of the load.

And, in case of the original wave, the disc contact point (a) is short-circuited at 100% or more of the set value current. At this time, the contact point (ICS) relay is turned on, when the contact point (a) is turned off, the contact point (ICS) relay is turned off, and the ESB 80 The disc should return when current equal to% is applied.

In addition, if the primary current of the current transformer (CT) rises in a ground and short-circuit accident in the OCR ICS DC 110V coil, the secondary current of the current transformer (CT) also increases proportionally, which causes the disc contact of the relay (10). When it is on, the battery power outputs the cutoff signal (+ power) to terminal 9 through the disc contact (a), and when the contact (3-ICS) coil is driven using the battery's external power, the external power If the (battery) is lower than the operating voltage (DC 110V), the contact ICS may not be operated, which may cause a large accident, and the contact ICS may not supply DC + power to 9 due to its own burden. Will cause an accident.

As described above, in the conventional protection relay, the contact ICS is driven by an external power supply, so when the external power supply is lower than the reference value of the contact ICS, a malfunction of the protection relay occurs due to a failure of the external power supply. And causing damage to the device.

Therefore, the purpose of the present invention is to prevent damage to various sections by reducing the damage to various devices and minimizing the supply disturbance when an accident occurs in the equipment or track in the faucet facility so that the accident does not spread to the normal section. In addition, to provide a self-regulator (SELF) relay to improve the stability to the power meter.

As a means for realizing the above object, a three-phase power supply, a circuit breaker (VCB), a load, a current transformer (CT), a coil (1-COIL, 2-COIL, 3-COIL), a disc, a rectifier 20, a contact (ICS1 -ICS3), in the self (SELF) relay configured to include a battery, the alarm, the rectifier 20 is rectified by the voltage induced in the tertiary coil when the current more than the set value flows into the primary coil contact (ICS) Is achieved by operating

Hereinafter, with reference to the attached 3 and 4 will be described in detail the operation and effect thereof.

3 is a schematic diagram of the principle of the self relay (SELF) of the present invention. As shown in FIG. 3, the rotational torque and the principle of the reversal torque of the aluminum disc are the same as in the conventional art, and the same direction as the coil 1 is used to avoid the external power source. Coil 3 is added, and the voltage induced by the coil 3 is used as a power source for a contact relay.

4 is a schematic diagram of a self (SELF) relay according to the present invention, in which a three-phase power source is connected to a breaker (VCB) through an RST, and the breaker (VCB) is a load of the three-phase power source through a current transformer (CT). (3) and the current transformers CT1 and CT2 are connected to terminals 4 and 5 of the protection relay 10, and terminals 4 and 5 of the current transformer CT2 are connected to the primary coil 1-COIL. The current transformer CT1 is connected to terminals 4 and 5, and the disc contact point a is connected to one side of the rectifier diodes D1 to D4 through one side of the contact point ICS 3, and the main contact point b is connected to the contact point ( ICS3) is connected to the other side of the third and third coil (3-COIL) and the other side of the third coil (3-COIL) is connected to the other side of the rectifier diode (D1-D4) and the third contact coil (3-ICS) One side of is connected to (+) terminal of rectifier diode (D1-D4) and the other side of tertiary contact coil (3-ICS) is connected to (-) terminal of rectifier diode (D1-D4) and the external power source (battery) Contact point (ICS1) connected to terminal 10 of this relay (10) The other side of the contact (ICS1) connected to one side of the relay 10 and the terminal (ICS1) connected to the breaker (VCB) and the external power (battery) connected to the second terminal of the relay (10) (ICS2) Connected to one side of the alarm is configured to be connected to the other side of the contact (ICS2) connected to the first terminal of the relay 10, the operation and effect thereof will be described in detail as follows.

When power (3-phase power: 3P3W) is supplied to the distribution line, it goes through a breaker (VCB). If a power system breaks down, the equipment is damaged and the supply and demand balance is broken.

On the other hand, if the fault of the power system is a short-circuit fault, the voltage of the fault point is shorted to almost 0 V, so that a large short-circuit current flows in the line. At this time, a current is generated on the secondary side of the current transformer (CT), thereby relay 4 and 5 terminals. Through the current flows in the primary coil (1-COIL: main coil), the secondary coil (2-COIL) generates a current, the third coil (3-COIL) generates a voltage.

In addition, the role of the secondary coil (2-COIL) is to allow the aluminum disc to be rotated normally and to adjust the rotation speed of the disc, the role of the third coil (3-COIL) to generate a voltage by the principle of the transformer contact ( ICS) Supply drive power.

When the current flows into the primary coil 1-COIL, the disc rotates. At this time, the disc contact point a and the main contact point b are attached to each other so that the voltage generated from the tertiary coil 3-COIL is the contact point ( The rectifier diodes D1-D4 are introduced through the disc and the main contact point, and the introduced voltages are alternating current voltages, so when the rectifier diodes D1-D4 pass through the rectification diodes D1-D4, the DC voltages are converted into DC voltages. When the power source drives the third contact coil 3-ICS, the contacts ICS1-ICS3 are shorted.

In addition, the contact point ICS1 outputs a signal to the breaker VCB using an external power source to cut off power supply to the load, and the contact point ICS2 also outputs an alarm signal using an external power source (battery), The contact ICS3 is a contact protecting the disc contact a and the main contact b.

Then, the disc is automatically returned after the disc contact (a) is shorted at 100% -190% of the set value current. At this time, the contact (ICS) relay is turned on.

In addition, when the contact point (ICS) OCR ICS DC 110V coil is ground fault and short-circuit accident of the line, the current transformer (CT) primary current rises, and the current transformer (CT) secondary current also rises proportionally. When the disc contact (a) is short-circuited through the current, the contact (ICS) relay is operated and outputs the external cutoff signal (+ power) through the contact (ICS) to perform the inherent duty of the relay (10). Even when the power supply (battery) is lower than the contact point (ICS) operating voltage (DC 110V), it operates by using the input current itself instead of the external power source. Therefore, there is no effect on the contact point (ICS) operation. As it is used only, it is not affected by the decrease of external power.

Accordingly, the contact ICS is operated by rectifying the voltage induced in the tertiary coil without operating the operating power supply of the relay 10 by an external power supply.

As described in detail above, the present invention operates the contact ICS by rectifying the voltage induced in the tertiary coil without operating the operating power of the protective relay by an external power source, thereby operating the contact relay ICS. It prevents malfunction and protects water distribution equipment.

Claims (2)

A current transformer CT for generating a current on the secondary side when a short circuit failure occurs in the wiring line, and a primary coil for supplying power from the secondary side of the current transformer CT to rotate the disc to contact the disc contact with the main contact. 1-COIL), and a secondary coil (2-COIL) for adjusting the rotational speed of the disc so that the current is generated and the aluminum disc rotates normally according to the current flow of the primary coil (1-COIL), and the primary It operates when the current flow of the coil (1-COIL) is higher than the set value, and contacts the third coil (3-COIL) that generates the voltage by the transformer principle and the voltage generated by the third coil (3-COIL). , Rectifying through the main contact) to short-circuit the contact (ICS1-ICS2) and the short circuit by the operation of the rectifying unit (D1-D4), the signal to the breaker using an external power supply (battery) A first contact point ICS1 for outputting a power to cut off power supply to the load, and the rectifying unit Shorted by the operation of (D1-D4), the second contact (ICS2) for outputting the alarm signal by using an external power supply, and the short circuit by the operation of the rectifier (D1-D4), and the original contact (a) and Self relay comprising a third contact (ICS3) for protecting the main contact (b). 2. The self relay according to claim 1, wherein the disc automatically returns after shorting the disc contact (a) at 100% -190% of the set value current.