KR101280288B1 - Circuit breaker - Google Patents

Abstract

PURPOSE: A circuit breaker is provided to improve breaking speed by including a restitution plate between a first restitution coil and a second restitution coil. CONSTITUTION: A contact part comprises a movable contact. A driving part (120) contacts and separates the movable contact from a fixed contact. A first restitution coil (121) is arranged on one side of the movable contact. A second restitution coil (131) is separated from the first restitution coil. A restitution plate is arranged between the first restitution coil and the second restitution coil.

Description

Circuit breaker {CIRCUIT BREAKER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to circuit breakers, and more particularly, to circuit breakers that enable high speed interruption and high speed input.

As is well known, a circuit breaker, a switch or a circuit breaker may cut off a fault current, an accident current, or an abnormal current (hereinafter, referred to as “abnormal current”) in the event of a short circuit or ground fault in the power system. And a device capable of protecting the load device.

Such switchgear and / or breaker (hereinafter referred to as "circuit breaker"), depending on the arc or insulation medium, the vacuum breaker (VCB: VACUUM CIRCUIT BREAKER), oil breaker (OCB: OIL CIRCUIT BREAKER), gas breaker ( GCB: GAS CIRCUIT BREAKER).

On the other hand, the circuit breaker may be provided with a driving mechanism for performing a switching action.

The driving mechanism may be configured to use a spring force, hydraulic pressure, pneumatic pressure, electromagnetic suction (repulsion) force as the main power.

As the circuit breaker increases in delay in response speed, accidents may spread and damage may increase.

1 is a view showing an example of a conventional circuit breaker.

As shown in FIG. 1, the circuit breaker may include a contact part 10 and a driving part 20 that opens and closes the contact part 10.

The contact portion 10 may be configured, for example, with a vacuum interrupter.

The contact portion 10 includes a vacuum container 11, a fixed contactor 13 fixedly disposed inside the vacuum container 11, and the fixed contactor 13 inside the vacuum container 11. It may be configured with a movable contact (15) to contact and disconnect.

For example, the fixed contact 13 and the movable contact 15 may be disposed along the vertical direction, and the movable contact 15 may be configured to be movable in the vertical direction.

One of the fixed contactor 13 and the movable contactor 15 may be connected to the bus bar 14, and the other may be connected to the load 16.

On one side of the movable contactor 15 is between the closing position (or tripping position), the movable contact 15 is in contact with the fixed contactor 13 and energized, and separated and spaced apart from the fixed contactor 13 The driving unit 20 for driving the may be provided.

The drive unit 20 may include, for example, a rebound coil 21 and a rebound plate 25 that is approached and spaced apart from the rebound coil 21 on one side of the rebound coil 21. Can be.

The rebound coil 21 may be composed of, for example, a so-called Thomson coil. The reaction coil 21 may be provided with a driving circuit 22 for driving the reaction coil 21.

As is well known, the rebound coil 21 and the rebound plate 25 have a so-called eddy current (eddy current or eddy current) in the rebound plate 25 when power is applied to the rebound coil 21. The magnetic force generated by the eddy current and the magnetic force of the rebound coil 21 may be repulsed to operate.

The rebound plate 25 may be integrally connected with the movable contact 15. As a result, the movable contact 15 may be separated from the fixed contact 13 when the reaction plate 25 moves.

The drive unit 20 may include an actuator 30 to drive the movable contact 15 to a so-called closing position in contact with the fixed contact 13.

Although not specifically illustrated in the drawings, the actuator 30 may include a coil for generating a magnetic force, a frame for forming a magnetic path around the coil, and the movable contact 15 and the coil. It can be configured to have a core moved by.

By such a configuration, when the accidental current or abnormal current is interrupted, the reaction plate 25 can be quickly moved in a direction away from the reaction coil 21 by the current applied to the reaction coil 21. As a result, the movable contact 15 is quickly disconnected from the fixed contact 13, so that the accident current can be cut off quickly.

On the other hand, when the current is applied to the coil of the actuator 30 and the core may be moved by the magnetic force generated by the coil. As a result, the movable contact 15 may be in contact with the fixed contact 13 so that the bus bar 14 and the load 16 may be electrically connected to each other.

By the way, in such a conventional circuit breaker, when the accident current is interrupted, the movable contact 15 is blocked at a relatively high speed by the interaction of the reaction coil 21 and the reaction plate 25 (a trip position). Although it can be moved to block the fault current, there is a problem that the input speed is relatively poor.

More specifically, for example, a consumer (e.g., a computer center, a water purification plant, a water intake station, a military facility, etc.) that may be heavily damaged in the event of a power outage may be called an automatic load transfer switch (ALTS). Load switching switch is provided so that backup power can be input immediately in case of main power accident. In this case, the damage can spread enormously if input speed is insufficient, so automatic load switching switch or circuit breaker with faster input speed May be required.

Accordingly, an object of the present invention is to provide a circuit breaker capable of increasing the breaking speed and the closing speed.

Another object of the present invention is to provide a circuit breaker whose structure is simple and which can increase the breaking and closing speed.

The present invention, in order to achieve the above object, a contact portion having a fixed contactor and a movable contactor disposed to be in contact and detachable with respect to the fixed contactor; And a driving unit driving the movable contactor to be in contact with and separated from the fixed contactor, wherein the driving unit comprises: a first rebound coil disposed at one side in a moving direction of the movable contactor; A second rebound coil spaced apart from the first rebound coil in a moving direction of the movable contact; The first and second rebound coils are disposed between the first and second rebound coils so as to interact with the first and second rebound coils, and are connected to the movable contacts to move the movable contacts in contact with and separated from the fixed contacts. Letting footboards; And a driving rod connecting the movable contactor and the reaction plate.

Here, the position fixing unit, yoke; A permanent magnet disposed in the yoke; And a movable core connected to the driving rod to form a magnetic circuit with the yoke and the permanent magnet.

The yoke may include a vertical portion, a first horizontal portion and a second horizontal portion bent at both ends of the vertical portion, and the permanent magnet may be disposed at the center of the vertical portion.

The movable core may be configured to be fixed by forming a closed circuit with any one of the first horizontal portion and the second horizontal portion.

A first recoil coil driving circuit for applying a driving power to the first recoil coil; A second rebound coil driving circuit for applying a driving power to the second rebound coil; And a control unit which controls any one of the first rebound coil driving circuit and the second rebound coil driving circuit when a signal is input.

As described above, according to an embodiment of the present invention, the first rebound coil and the second rebound coil disposed to be spaced apart from each other, and the rebound plate disposed to interact with the first rebound coil and the second rebound coil By providing a, it is possible to increase both the blocking speed and the closing speed.

In addition, by having a position fixing unit for fixing the movable contactor in the closing position and the blocking position, respectively, by configuring the position fixing unit having a yoke, a permanent magnet and a movable core, it is possible to increase both the closing speed and the blocking speed. However, the configuration can be simple and easy to manufacture.

1 is a view showing an example of a conventional circuit breaker;
2 is a schematic configuration diagram of a circuit breaker according to an embodiment of the present invention;
3 is a view for explaining the operation of the circuit breaker of FIG.
4 is a control block diagram of the circuit breaker of FIG. 2.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 2, a circuit breaker according to an embodiment of the present invention includes a contact having a fixed contactor 113 and a movable contactor 115 disposed to be in contact with and detachable from the fixed contactor 113. Unit 110; And a driving unit 120 driving the movable contactor 115 to be in contact with and separated from the fixed contactor 113, wherein the driving unit 120 is on one side along the moving direction of the movable contactor 115. A first rebound coil 121 disposed in the; A second rebound coil 131 spaced apart from the first rebound coil 121 in a moving direction of the movable contact 115; And between the first rebound coil 121 and the second rebound coil 131 so as to interact with the first rebound coil 121 and the second rebound coil 131, respectively, and with the movable contact 115. And a rebound plate 141 connected to move the movable contact 115 to be in contact and separated with respect to the fixed contact 113.

For example, the contact unit 110 may be configured to connect and disconnect the bus line 114 and the load 116 by connecting one side to the bus line 114 and the other side to the load 116.

More specifically, the contact portion 110 may be configured to include a fixed contact 113, and a movable contact 115 is disposed to be in contact with and detachable from the fixed contact 113.

The fixed contact 113 may be connected to one of the bus line 114 and the load 116, for example.

The movable contact 115 may be connected to the other of the bus line 114 or the load 116, for example.

The contact unit 110 may be configured to include, for example, a vacuum container 111 for accommodating the fixed contact 113 and the movable contact 115 therein and maintaining a vacuum. In this embodiment, the case in which the contact portion 110 is configured as a vacuum interrupter (vacuum interrupter) provided with the vacuum container 111, but the contact portion (not shown) does not have a vacuum container 111 May be configured.

One side of the contact unit 110 may be provided with a driving unit 120 for driving the movable contact 115.

The movable contact 115 is an injection position in which the driving unit 120 is in electrical contact with the fixed contact 113, and a blocking position that separates and spaces apart from the fixed contact 113 to block a current. (Or trip position) can be configured to be movable.

A first rebound coil 121 may be provided at one side of the movable contact 115 along the moving direction of the movable contact 115.

One side of the first recoil coil 121 may be connected to a first recoil coil driving circuit 122 for driving the first recoil coil 121.

A second rebound coil 131 may be provided at one side of the first rebound coil 121 along the moving direction of the movable contact 115.

A second rebound coil driving circuit 132 for driving the second rebound coil 131 may be connected to one side of the second rebound coil 131.

A rebound plate 141 may be provided between the first rebound coil 121 and the second rebound coil 131 to interact with the first rebound coil 121 and the second rebound coil 131. .

The first rebound coil 121 and the second rebound coil 131 may be configured of a so-called Thomson coil that generates a magnetic force when power is applied.

The rebound plate 141 is quickly moved away from the first rebound coil 121 and the second rebound coil 131 when power is applied to the first rebound coil 121 and the second rebound coil 131, respectively. It may be configured to be moved.

The rebound plate 141 may be integrally connected with the movable contact 115.

The driving rod 152 may be connected between the rebound plate 141 and the movable contact 115.

One end of the driving rod 152 may be connected to the movable contact 115, and the other end thereof may be connected to the rebound plate 141.

The driving rod 152 may be formed of a plurality of parts so as to extend to the other side of the reaction plate 141. The movable core 181 of the position fixing unit 160 to be described later may be connected to the driving rod 152 extending to the other side (lower side in the drawing) of the repelling plate 141.

On the other hand, the circuit breaker of the present embodiment may be provided with a position fixing unit 160 for fixing the movable contact 115 to the closing position or the blocking position, respectively.

The position fixing unit 160, for example, yoke (161); A permanent magnet 171 disposed inside the yoke 161; And a movable core 181 connected to the driving rod 152 and forming a magnetic circuit with the yoke 161 and the permanent magnet 171. As a result, since a separate driving coil is not provided, the configuration is simple and the production can be easily performed. In addition, since little failure occurs, it can be used as a semi-permanent magnet with little need for maintenance and inspection.

The yoke 161 may be made of a magnetic material. As a result, a magnetic path can be formed.

The yoke 161 may include, for example, a vertical portion 162 and a first horizontal portion 163 and a second horizontal portion 164 that are bent at both ends of the vertical portion 162. Can be.

The yoke 161 may be configured, for example, in a cylindrical shape.

The yoke 161 may be formed by, for example, insulating lamination of a disk-shaped electrical steel sheet.

A permanent magnet 171 may be provided inside the yoke 161.

The permanent magnet 171 may be disposed at the center along the longitudinal direction of the vertical portion 162, for example. That is, the permanent magnet 171 may be configured such that the distance d1 between the first horizontal portion 163 and the distance d2 between the second horizontal portion 164 are the same (d1 = d2). .

A movable core 181 may be disposed inside the yoke 161 and the permanent magnet 171.

The movable core 181 may be connected to the rebound plate 141. As a result, the rebound plate 141 and the movable core 181 may be integrally moved. More specifically, the driving rod 152 may be connected to the center of the rebound plate 141 to extend downward. The movable core 181 may be integrally connected to the lower end of the driving rod 152 to be movable.

The movable core 181 may be configured to be fixed in position by forming a closed circuit with any one of the first horizontal portion 163 and the second horizontal portion 164.

More specifically, the movable core 181, one end is located on one side of the permanent magnet 171 and the other end coincides with the outer surface of the first horizontal portion 163 or the second horizontal portion 164. It can be configured as long as possible.

The moving distance between the closing position and the closing position of the movable contactor 115, the moving distance between the first and second rebound coils 121 and 131 of the rebound plate 141, and the movable core The moving distance of 181 may be configured in the same manner.

On the other hand, the circuit breaker of the present embodiment may be configured to include a control unit 190, which is implemented as a microprocessor with a control program.

For example, the controller 190 may receive a detection signal upon detecting a short circuit, ground fault, or an accident current to control the first rebound coil 121 to quickly move the movable contact 115 to a blocking position to cause an accident. It can be configured to cut off the current.

In addition, the controller 190 controls the first rebound coil 121 or the second rebound coil 131 when the input signal or the shutoff signal is input, for example, so that the movable contact 115 is closed or closed. It can be configured to be driven quickly into position.

As shown in FIG. 4, the control unit 190 includes a detection unit 191 for detecting an abnormal current such as a short circuit, a ground fault, and / or an accident current, and a signal input unit for inputting an input signal or a blocking signal ( 193 may be connected to enable signal input (transmission), respectively.

The control unit 190 has a first reaction coil driving circuit 122 and a second reaction coil driving circuit 132 to drive the first reaction coil 121 and the second reaction coil 131 at the time of signal input, respectively It can be connected controllably.

By such a configuration, when the blocking signal is input from the sensing unit 191 or the signal input unit 193, the controller 190 controls the first rebound coil driving circuit 122 to control the first rebound coil. The driving power can be applied to the 121.

When driving power is applied to the first rebound coil 121, the rebound plate 141 may be quickly moved away from the first rebound coil 121. As a result, the movable contact 115 can be quickly separated from the fixed contact 113 and moved to the blocking position.

When the movable contact 115, the reaction plate 141 and the driving rod 152 are moved, the movable core 181 may be moved. As shown in FIG. 3, the movable core 181 may be moved toward the second horizontal portion 164. At this time, the magnetic flux of the permanent magnet 171 flows in a closed circuit along the vertical portion 162 and the second horizontal portion 164, so that the movable core 181, the repulsive plate 141 and the movable contactor. 115 may be fixed to the blocking position.

On the other hand, when the input signal is input, the control unit 190 may control the second rebound coil driving circuit 132 so that driving power is applied to the second rebound coil 131. When driving power is applied to the second rebound coil 131, the rebound plate 141 may be quickly moved in a direction away from the second rebound coil 131. As a result, the movable contact 115 can be quickly moved to the input position in contact with the fixed contact 113.

The rebound plate 141, the movable contact 115, and the driving rod 152 may be moved to the feeding position and the movable core 181 may be moved to the feeding position at the side of the first horizontal portion 163. At this time, the magnetic flux of the permanent magnet 171 flows in a closed circuit along the yoke 161 and the first horizontal portion 163, whereby the movable core 181, the repellent plate 141, and the movable The contactor 115 may be fixed at the closing position.

The foregoing has been shown and described with respect to specific embodiments of the invention. However, the present invention may be embodied in various forms without departing from the spirit or essential characteristics thereof, so that the above-described embodiments should not be limited by the details of the detailed description.

Further, even when the embodiments not listed in the detailed description have been described, it should be interpreted broadly within the scope of the technical idea defined in the appended claims. It is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

110: contact portion 113: fixed contact
115: movable contact 120: drive unit
121: first rebound coil 122: first rebound coil driving circuit
131: second rebound coil 132: second rebound coil driving circuit
141: foot plate 151: driving rod
160: position fixing unit 161: yoke
162: vertical portion 163: first horizontal portion
164: second horizontal portion 171: permanent magnet
181: movable core 190: control unit
191: detection unit 193: signal input unit

Claims (5)

A contact portion having a fixed contactor and a movable contactor disposed to be in contact with and detachable from the fixed contactor;
A driving unit driving the movable contactor to be in contact with and separated from the fixed contactor; And
And a position fixing unit configured to fix the movable contactor to a contact position contacting the fixed contactor or to a blocking position separated from the fixed contactor.
The driving unit includes:
A first rebound coil disposed at one side in a moving direction of the movable contact;
A second rebound coil spaced apart from the first rebound coil in a moving direction of the movable contact;
The first and second rebound coils are disposed between the first and second rebound coils so as to interact with the first and second rebound coils, and are connected to the movable contacts to move the movable contacts in contact with and separated from the fixed contacts. Lethal repellent; And
And a driving rod connecting the movable contactor and the rebound plate.
The position fixing unit, yoke; A permanent magnet disposed in the yoke; And a movable core connected to the driving rod to form a magnetic circuit with the yoke and the permanent magnet.
The yoke has a vertical portion and a first horizontal portion and a second horizontal portion bent at both ends of the vertical portion, and the permanent magnet includes a distance between the distance d1 between the first horizontal portion and the second horizontal portion. Disposed at the center of the vertical portion such that the distance d2 is equal (d1 = d2),
The movable core is spaced apart from the second horizontal portion without forming a magnetic circuit in the contact position to form the first horizontal portion and the magnetic circuit, and does not form the first horizontal portion and the magnetic circuit in the blocking position. The circuit breaker, characterized in that spaced apart so as to form a magnetic circuit with the second horizontal portion. The method of claim 1,
The length of the movable core is one end of the movable core is located on one side of the permanent magnet and the other end of the movable core is configured to have a length that can match the outer surface of the first horizontal portion or the second horizontal portion Circuit breaker characterized in that. delete delete The method according to claim 1 or 2,
A first recoil coil driving circuit for applying a driving power to the first recoil coil;
A second rebound coil driving circuit for applying a driving power to the second rebound coil; And
And a control unit for controlling any one of the first rebound coil driving circuit and the second rebound coil driving circuit when a signal is input.

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