KR20090073785A - Spring operation device of circuit breaker in gas insulated switchgear - Google Patents

Abstract

A spring operator of a breaker of a gas insulated switchgear is provided to reduce a control current and an operation time by reducing a size of a solenoid. A spring operator of a gas insulated switchgear includes a lever(100), a main latch(200), a solenoid(300), and a restrainer(400). The lever rotates with a driving shaft(110). The main latch releases or restrains the lever. The solenoid provides an operation force for releasing the lever. The restrainer is movably coupled with the lever. The restrainer maintains the restraining state of the lever in an interrupting operation of a breaker. The restrainer returns the lever to an original position in an opening operation of the breaker. The restrainer includes a restraining block(410) and an elastic member(420). The restraining block contacts with the main latch to restrain the lever. The elastic member provides the restoring force for the rotation of the restraining block.

Description

Spring operation device of circuit breaker in Gas insulated switchgear

The present invention relates to a gas insulated circuit breaker, and more particularly to a spring manipulator for selective closing and opening operation of the circuit breaker.

In general, a gas insulated switchgear (GIS) uses an insulating gas (SF6) having excellent insulation performance and extinguishing function in a metal sealed container (tank) as an insulating medium to accommodate conductors and various protective devices, thereby improving reliability. As a facility, various components such as a circuit breaker, a disconnector, and a grounding switch are formed in a complex manner.

The circuit breaker is a series of configurations to protect the power system by cutting off the system fault current even in abnormal conditions such as ground fault, short circuit and accident, as well as the normal opening and closing of the gas insulated switchgear. .

The breaker as described above should be able to cut off the power quickly when an abnormal state occurs, and the conventional breaker is configured to allow the selective closing operation and opening operation of the breaker by a spring manipulator using a plurality of springs.

1 is a schematic diagram showing a brief structure of a relationship between a conventional spring manipulator and a breaker.

As can be seen through this, the existing breaker spring manipulator is configured to charge the open spring 10 to perform the open operation during the closing operation, the closing operation is the cam 20 pushes the lever 30 while passing the lever It is made by rotating the drive shaft 31 which is operated together with the 30.

In addition, Figures 2 and 3 attached are shown in a simplified state of the structure of the open latch portion of the conventional spring manipulator.

The open latch unit 2 is a series of configurations in which the open spring 10 is maintained by the driving of the drive shaft 31 or the breaker performs an open operation. It is configured to include a plurality of latches (32, 33, 34) and the open solenoid (35) interlocked with).

At this time, the latches 32, 33, 34 are operated in sequence by the operation of the lever 30 to maintain the restraint state of the lever 30, as well as of the open solenoid 35 It performs a role of releasing restraint of the lever 30 by a selective operation.

That is, when the closing operation is started by the closing command in the open state as shown in FIG. 2, the lever 30 is rotated clockwise, and the latch 30 is interlocked with the lever 30 by the rotation of the lever 30. (Hereinafter referred to as “first latch”) 32 performs some rotational movement in the counterclockwise direction.

At this time, since the roller 36 is rollably installed at the tip of the lever 30, even if the first latch 32 is pressed by the lever 30, smooth rotation of the lever 30 is possible. .

In addition, in the state in which the lever 30 is completely rotated as shown in FIG. 3 attached by the above process, the roller 36 installed at the tip of the lever 30 is positioned below the left end of the first latch 32. do.

In this case, the first latch 32 is rotated along the clockwise direction with respect to the hinge axis 32b by the restoring force of the restoring spring 32a, and other adjacent latches (hereinafter referred to as “second latches”) ( When the roller 32c of the first latch 32 is positioned below the left end of the second latch 33 and the roller 32c of the first latch 32 is rotated counterclockwise, the second latch 33 is a recovery spring 33a. By rotating the clockwise direction with respect to the hinge axis (33c) by the restoring force of the) will be sequentially performed to rotate another adjacent latch (hereinafter referred to as "third latch") 34.

Therefore, the latches 32, 33, and 34 are kept in a state in which rotation in the reverse direction (counterclockwise) is prevented by the above-described series of processes, and thus the lever 30 also rotates in the reverse direction. By making this prevented state, the input state is maintained.

If the control for the open operation is made in the above state, the third latch 34 is forcibly rotated counterclockwise by the operation of the open solenoid 35 to release the restraint of the second latch 33. The second latch 33 is also rotated counterclockwise to release the restraint of the first latch 32, and the first latch 32 is also rotated counterclockwise to rotate the lever 30. By releasing the restraint, the lever 30 eventually opens the breaker 1 while being returned by the restoring force of the open spring 10 connected thereto.

The spring manipulator according to the related art configured as described above takes about 150 ms while the cam 20 installed on the charging shaft 21 flips off the lever 30 of the driving shaft 31 while the double lever The time 30 remains on the underside of the first latch 32 is only a few ms.

Accordingly, since the latches 32, 33, and 34 are all returned as shown in FIG. 3 attached during the extremely short time, the restoring springs 32a, 33a, which return the latches 32, 33, and 34, 34a) had to be strong enough.

However, as the restoring force of each of the restoring springs 32a, 33a, and 34a is stronger, the size of the open solenoid 35 forcibly manipulating the latches 32, 33, and 34 is required, and the open solenoid 35 is required. Increasing the inductance to increase the force of) increases the operating time of the open solenoid 35, making it difficult to meet the operation time required by the standard or specification.

In addition, in order to reduce the operation time of the open solenoid 35, it is necessary to increase the current flowing to the open solenoid 35 by reducing the resistance of the coil, but this is not only a reason for increasing the size of the open solenoid 35 again. This may cause the bolt and amperage values beyond the specifications or specifications to be exceeded.

In addition, the stoppers 32d provided to prevent excessive return of the latches 32, 33, 34 in the process of returning the latches 32, 33, 34 by the respective restoring springs 32a, 33a, 34a, 33d, 34d) will cause some chattering. As a result, the latches of the latches 32, 33, and 34 are unstable due to the chattering, and thus there is a problem in that the release of the latches occurs undesirably and the open operation occurs.

SUMMARY OF THE INVENTION The present invention has been made to solve the various problems of the prior art described above, and an object of the present invention is to secure the latching of each latch by eliminating the need for each latch to return for a short time while performing the restraining operation. It is possible to reduce the size of the solenoid, thereby reducing the control current and operating time, thereby providing a new type of spring manipulator for gas insulated circuit breakers that can easily meet the requirements of specifications and specifications. It is.

According to the spring manipulator for gas insulated circuit breaker of the present invention for achieving the above object is a rotationally coupled with the drive shaft in a state coupled to the drive shaft, the lever is elastically installed to return to its original position when the restraint is released; A main latch rotatably installed so as to maintain the constrained state and to be restrained when the lever is provided with an operating force; A solenoid for providing a manipulation force to the main latch to release the lever; In addition, the lever is movably coupled to the lever, and during the blocking operation of the breaker, the main latch is constrained to the main latch while the main latch does not flow to maintain the restrained state, and the open operation of the breaker. And a restraining part for restoring the lever to its original position while being restrained from the main latch by the operation of the main latch.

Here, the lower end is hinged to the end of the lever is in contact with the main latch by the rotation operation of the lever when the lever is rotated by a predetermined distance so that the lever is restrained with the latch on the upper surface Constraining block and one end is fixed to the lever, the other end is fixed to the rear of the restraining block is configured to include an elastic member for providing a restoring force so that the upper end of the restraining block is rotated forward with respect to the hinge It features.

In this case, a locking hole is formed at an upper end of the restraining block, and the lever further includes a locking pin that protrudes into the locking hole and prevents excessive rotation of the restraining block while having a smaller diameter than the locking hole. Characterized in that configured.

In addition, between the main latch and the solenoid is characterized in that it further comprises a plurality of auxiliary latches interlocked with each other to receive the operating force by the solenoid to operate the main latch.

In addition, the roller is provided to be rolled on the portion of the main latch in contact with the restraining portion provided with the rotational force is characterized in that it is further configured.

The spring manipulator for gas insulated circuit breaker according to the present invention as described above, since the return operation of each latch proceeds on its own when the breaker is opened, the restoring force of the restoring spring for the operation of each latch or the solenoid during the operation of the breaker. The increase in output has the effect of becoming unnecessary.

In particular, since the latch is not operated during the blocking operation of the circuit breaker as described above, unwanted release of the lever due to chattering of the latch does not occur, thereby improving the operation reliability.

Hereinafter, a preferred embodiment of a spring manipulator for a gas insulated circuit breaker of the present invention will be described with reference to FIGS. 4 to 6.

The spring manipulator for a gas insulated circuit breaker according to the preferred embodiment of the present invention is largely proposed to include a lever 100, a main latch 200, a solenoid 300, and a restraining part 400.

This will be described in more detail for each component as follows.

First, the lever 100 will be described.

The lever 100 is a series of components that are rotatably operated together with the drive shaft 110 in a state of being installed integrally with the drive shaft 110, and a cam installed on the charging shaft 21 (see FIG. 1 attached). 20) (see FIG. 1 attached).

At this time, the drive shaft 110 is connected to the circuit breaker 1 (see FIG. 1 attached), and is a series of configurations for performing the opening operation of the circuit breaker 1 by rotation, and the charging shaft 21 ) Is the portion that is operated for charging the breaker 10.

That is, the lever 100 is selectively rotated by the eccentric rotation of the cam 20 by the rotation operation of the charging shaft 21, and the drive shaft 110 is in the rotational direction of the lever 100. Accordingly, it is operated to maintain the charging state of the breaker 1, or to open the breaker (1).

In particular, the lever 100 is forcibly returned to the lever 100 so as to open the breaker 1 while providing a restoring force in a direction opposite to the rotational direction driven by the cam 20. Open spring 120 is installed.

Next, the main latch 200 will be described.

The main latch 200 maintains the lever in a restrained state when the breaker 1 is blocked, and the lever 100 according to the rotation operation of the lever 100 when the breaker 1 is opened. ) Is a series of constructs that allow the release of).

The main latch 200 is rotatably coupled in a clockwise or counterclockwise direction with reference to the hinge axis 210, and the main latch 200 is connected to any one portion of the main latch 200. Restoration spring 220 for providing a restoring force to be rotated in a direction opposite to the direction rotated by the lever 100 is connected is installed.

In addition, a stopper 230 protruding from the main latch 200 to prevent excessive rotation of the main latch 200 is formed on the path rotated by the restoring force of the restoring spring 220 among the rotation paths of the main latch 200.

Next, the solenoid 300 will be described.

The solenoid 300 is a series of components operated to release the restraint of the lever 100 by the main latch 200 by forcibly manipulating the main latch 200.

In the embodiment of the present invention, the configuration for releasing the restraint of the lever by the operating force by the solenoid 300 as described above may be simply configured by only one main latch 200, in the embodiment of the present invention described above the main latch 200 And a plurality of auxiliary latches 310 and 320 are further included between the solenoid 300 and the solenoid 300.

This is because when the main latch 200 is composed of only one, the operation force of the solenoid 300 for operating the main latch 200 must be considerably large, as described above, the plurality of auxiliary latches 310 and 320 may be replaced by the main latch. Further provided between the 200 and the solenoid 300 is to enable the operation of the main latch 200 even if the operation force by the solenoid 300 is provided small.

In this case, the plurality of auxiliary latches 310 and 320 are provided to be interlocked sequentially between the main latch 200 and the solenoid 300 to receive the restraining force by the solenoid 300 to receive the main latch 200. And a second auxiliary latch 310 interlocked with the main latch 200 and a second auxiliary latch interlocked with the first auxiliary latch 310 while being provided with a manipulation force by the solenoid 300. It is shown that the latch 320 is configured.

In particular, the second auxiliary latch 320 of each of the auxiliary latches 310 and 320 is configured to be selectively rotated by the plunger 301 of the solenoid 300.

Next, the restraining part 400 will be described.

In the blocking operation of the circuit breaker 1, the restraining part 400 is self-flowing in a state in which the main latch 200 does not flow and is restrained by the main latch 200 so that the lever 100 is restrained. In the open operation of the breaker 1, a series of the lever 100 may be returned to its original position while being restrained from the main latch 200 by the operation of the main latch 200. Configuration.

In this case, the restraining part 400 is hinged 401 by contact due to the rotational operation of the lever 100 in a state in which the restraint part 400 is elastically installed in a corresponding part with the main latch 200 among the parts of the lever 100. It is rotatably bound based on the binding site with.

The restraint unit 400 as described above includes a restraint block 410 and an elastic member 420.

Here, the restraining block 410 is a block having a lower end coupled to the end of the lever 100 by a hinge shaft 401, when the rotation operation of the lever 100 is in progress (front facing the latch) ( Hereinafter, when the “contact surface” 411 is continuously in contact with the main latch 200 and the upper end performs the retraction operation, and the lever 100 is rotated by a predetermined distance, the upper surface (hereinafter, “restraint” The lever 100 is restrained in a state where the main latch 200 is placed on the 412.

In this case, the restraining surface 412 of the restraining block 410 is not formed to be perpendicular to the contact surface 411, but is gradually inclined downward toward the connection portion with the contact surface 411, thereby providing the main latch 200. In the case where the restraint release force is provided through a), it is preferable that the restraint is smoothly released from the main latch 200 so as to be reversely rotated.

In particular, a locking hole 413 is formed at an upper end of the restraining block 410, and the lever 100 protrudes to be recessed into the locking hole 413 of the restraining block 410 and the locking hole 413. It is configured to further comprise a locking pin 101 having a smaller diameter than the diameter of). The locking hole 413 and the locking pin 101 as described above are a series of components for preventing the restriction block 410 from being excessively rotated when the lever 100 rotates.

In addition, the elastic member 420 is a spring for providing a restoring force so that the upper end of the restraining block 410 is rotated forward based on the portion coupled by the hinge axis 401 of the lower end of the restraining block 410 As such, one end is fixed to the lever 100 and the other end is fixed to the rear surface of the restraint block 410.

On the other hand, in the configuration according to the embodiment of the present invention described above when the direct contact between the main latch 200 and the restraining block 410 may not only cause damage to each other but also smooth operation may be difficult This can be caused.

Accordingly, in the embodiment of the present invention, it is suggested that the roller 500 is installed to be rolled on the part receiving the rotational force while being in contact with the restraining block 410 among the parts of the main latch 200. do.

That is, by allowing the contact between the main latch 200 and the restraining block 410 to be made by the roller 500, not only the rotation operation of the lever 100 can be smoothly performed, but also the main latch 200 or The damage between the restraint block 410 is to be prevented in advance.

Of course, the other end of the main latch 200 and the other side of the roller 500 is installed, the other side of the second auxiliary latch 320 and the portion of the third auxiliary latch 330 in contact with the separate It is preferable that the auxiliary roller (510.520) is further provided.

Hereinafter, an operation process of the spring manipulator for a gas insulated breaker according to the above-described embodiment of the present invention will be described with reference to FIGS. 4 to 6.

First, Fig. 4 attached shows a state in which the breaker is open.

In this case, the main latch 200 and each of the auxiliary latches 310 and 320 remain constrained with each other, and the lever 100 is opened with the open spring 120 in a state in which it is released from the main latch 200. Positioned to maintain state.

If rotation of the charging shaft 21 (see FIG. 1 attached) is performed in order to proceed with the blocking operation of the circuit breaker 1 in the above state, the cam 20 (attached) according to the rotation of the charging shaft 21 is attached. As shown in FIG. 1), the drive shaft 110 is rotated while the lever 100 is rotated.

That is, the lever 100 is rotated in the clockwise direction as shown in FIG. 5 by the rotation of the cam 20, and in this process, the contact surface 411 of the restraining block 410 is connected to the main latch 200. Contact with the installed roller 500 is made.

In this case, since the main latch 200 maintains the restrained state by the other auxiliary latches 310 and 320, the main latch 200 does not flow, and only the restraint block 410 moves the hinge shaft 401. The lever 100 rotates smoothly while the upper end is inclined toward the rear side toward the center. This is the same as in FIG. 5.

In addition, when the lever 100 is completely rotated by the above process, the restraining block 410 is inclined toward the front side with respect to the hinge axis 401 by the restoring force by the elastic member 420. Accordingly, the roller 500 of the main latch 200 is placed on the restraining surface 412 of the restraining block 410. This is as shown in Figure 6 attached.

Accordingly, the reverse rotation (rotation in the counterclockwise direction on the drawing) of the lever 100 is not made and is held in a restrained state, and the open spring 120 is charged and at the same time the breaker 1 is blocked. State is achieved.

On the other hand, if the control system for the open operation of the circuit breaker 1 is generated by the abnormality of the system in the state of the breaker (1) as described above, the solenoid 300 is operated by the control and the solenoid 300 The second auxiliary latch 320 adjacent to the is rotated counterclockwise in the drawing.

In addition, when the second auxiliary latch 320 is rotated as described above, the first auxiliary latch 310 interlocked with the second auxiliary latch 320 is rotated counterclockwise in the drawing according to the release of its restraint and the main latch. 200 is also rotated counterclockwise in the drawing.

Accordingly, the restraining block 410 is released by the main latch 200, in this case, the charged open spring 120 to return the lever 100 to the original position while providing a restoring force and In addition, the drive shaft 110 coupled to the lever 100 also opens the circuit breaker 1 while the reverse rotation is performed.

When the lever 100 is returned to its original position, the main latch 200 is rotated clockwise again by the restoring force of the restoring spring 220 connected thereto, and each of the auxiliary latches 310 and 320 is also restored. It is rotated by the restoring force of the springs 312 and 322 and the interlocking process with the main latch 200 to maintain the restrained state. Its state is as shown in Figure 4 attached.

As a result, the spring manipulator for the gas insulated circuit breaker according to the present invention does not flow in the latches 200, 310, 320 during the blocking operation of the circuit breaker 1 as in the above-described embodiment.

That is, when the open operation is completed, the latches 200, 310, and 320 are restored by the corresponding restoring springs 220, 312, and 322, respectively, to form restrained states.

Accordingly, as soon as the lever 100 is restrained by the main latch 200 during the blocking operation of the breaker 1, the maximum return of each of the auxiliary latches 310 and 320 is not necessary, thereby restoring the restoring force of the restoring springs 220, 312 and 322. Operational reliability can be sufficiently obtained without increasing the size of the solenoid 300 or increasing the size of the solenoid 300, and it is possible to meet the requirements of specifications and specifications.

1 is a schematic conceptual view showing to explain the installation structure for the spring manipulator of the conventional gas insulated breaker

2 and 3 are schematic configuration diagrams for explaining a lever operation structure of a conventional spring manipulator for gas insulated breakers

4 is a configuration diagram illustrating a lever operation structure of a spring manipulator for gas insulated circuit breakers according to a preferred embodiment of the present invention;

5 and 6 are schematic configuration diagrams for explaining the operation of the lever according to FIG.

Claims (5)

A lever which is rotatably operated together with the drive shaft in a state coupled to the drive shaft and is elastically installed to return to its original position when the restraint is released; A main latch rotatably installed so as to maintain the constrained state and to be restrained when the lever is provided with an operating force; A solenoid for providing a manipulation force to the main latch to release the lever; And, It is fluidly coupled to the lever, and during the blocking operation of the breaker, the main latch is bound to the main latch while being self-flowing without flowing the main latch, so that the lever is held in a restrained state. And a restraining unit for restoring the lever to its original position while being restrained from the main latch by the operation of the main latch. The method of claim 1, The restraining part A lower end is hinged to the end of the lever and the restraining block for restraining the lever with the latch on the upper surface when the lever is rotated by a predetermined distance while contacting the main latch by the rotation operation of the lever; One end is fixed to the lever, the other end is fixed to the rear surface of the restraint block, the gas insulation characterized in that it comprises an elastic member for providing a restoring force so that the upper end of the restraint block is rotated forward with respect to the hinge Spring actuator for breakers. The method of claim 2, A locking hole is formed at the upper end of the restriction block, The lever is a spring manipulator for the gas insulated circuit breaker, characterized in that it further comprises a locking pin protruding into the locking hole to prevent excessive rotation of the restraining block while having a smaller diameter than the locking hole. The method of claim 1, And a plurality of auxiliary latches interposed between the main latch and the solenoid so as to receive the operation force by the solenoid to operate the main latch. The method according to any one of claims 1 to 4, A spring manipulator for gas insulated breakers, characterized in that the roller is provided to be rolled on the part of the main latch to receive the rotational force while being in contact with the restraining portion.

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