KR101093446B1 - Triphook damper of vacuum interruptor controller - Google Patents

Abstract

The present invention is a trip hook shock absorber for preventing the tripping of the trip hook in the operation unit of the vacuum circuit breaker, and more specifically, to support the rotation of the trip hook and to prevent the rebound phenomenon due to the impact of the trip hook. It relates to a trip hook buffer device of the vacuum circuit breaker operating unit. The present invention is a buffer support rod support provided on one side of the vacuum circuit breaker manipulator portion, a buffer support rod provided through the buffer support rod support and vertical movement, provided on the outer peripheral surface of the buffer support rod is provided with the vacuum circuit breaker manipulator An elastic spring to absorb the shock of the trip hook provided in the spring, the spring cap for supporting the elastic spring is provided on one side end and the other end of the elastic spring, provided on the outer circumferential surface of the buffer support rod and the lower and the spring cam A spring cap support portion interposed between the buffer support rod support, and a lower portion of the buffer support rod is provided to include a nut for supporting the buffer support rod to be fixed to the buffer support rod support.

Vacuum Circuit Breaker, Control Panel, Trip Hook, Interlock, Shock Absorber

Description

Trip hook buffer device of vacuum breaker control unit {TRIPHOOK DAMPER OF VACUUM INTERRUPTOR CONTROLLER}

The present invention is a trip hook shock absorber for preventing the tripping of the trip hook in the operation unit of the vacuum circuit breaker, and more specifically, to support the rotation of the trip hook and to prevent the rebound phenomenon due to the impact of the trip hook. It relates to a trip hook buffer device of the vacuum circuit breaker operating unit.

The vacuum circuit breaker, widely used in the 3.3㎸ to 38㎸ class, is the most widely used vacuum breaker in Korea and the world in the medium and high pressure system field since the late 1970s due to its excellent arc arc extinguishing ability.

The vacuum circuit breaker is largely composed of a circuit breaker and an operation unit, the circuit breaker is a device that serves to cut off electricity, the operation unit is a device to operate by applying a mechanical operation to the breaking end.

As a method of supplying energy to the control unit so that the breaker of the conventional vacuum circuit breaker can be operated, a closing electromagnet coil and a motor spring stored energy are used.

In case of applying coil excitation type, the coil is wrapped in bobbin to apply the voltage to generate the excitation force to generate the moving force of the driving part.The structure of the operation part of the vacuum circuit breaker is very simple, but the current value of the control voltage It is not currently used because the input is sensitive and stable mechanical properties cannot be obtained.

The electric spring operation method, which is another method, is configured to tension or compress the closing spring by using the charging motor and the worm-gear. Although the design of the vacuum circuit breaker's control part is complicated such as capacity, rotational speed, deceleration ratio of worm gears, and durability, it satisfies the characteristics of the vacuum breaker's requirement for operating voltage. Is applied to the vacuum circuit breaker control unit.

The configuration of the vacuum circuit breaker manipulator is largely composed of a charging motor, a worm-gear, an input spring, a camshaft, an operation shaft, a trip hook and an input hook, a switch section, and an interlock device.

The trip hook is configured to be in contact with the interlock device, and the trip hook makes a rapid rotation in a clockwise direction and contacts the interlock device while colliding with the interlock device.

At this time, the trip hook bounces counterclockwise and this bounce phenomenon causes mechanical malfunction in the vacuum circuit breaker.

In order to solve this problem, the present inventors have invented a device for mitigating a collision between the trip hook and the interlock device.

An object of the present invention is to provide a trip hook shock absorber of the vacuum circuit breaker control unit for preventing the above-mentioned trip hook phenomenon.

According to an aspect of the present invention,

A buffer support rod support provided on one side of the vacuum circuit breaker manipulator, a buffer support rod provided through the buffer support rod support and configured to move up and down, and provided on an outer circumferential surface of the buffer support rod to be provided in the vacuum circuit breaker manipulator. An elastic spring for absorbing the impact of the trip hook, a spring cap provided at one end and the other end of the elastic spring to support the elastic spring, and an outer circumferential surface of the buffer support rod, the lower end of the spring cam and the buffer support rod A spring hook support part interposed between the support and a lower portion of the buffer support rod, and a trip hook shock absorber of the vacuum circuit breaker manipulator including a nut supporting the buffer support rod to be fixed to the buffer support rod support. to provide.

The elastic spring is characterized in that at least two or more.

The upper surface of the buffer support rod is characterized in that it is formed flat.

According to the present invention, there is provided a trip hook buffer device of a vacuum circuit breaker manipulator which prevents a tripping phenomenon of the trip hook to eliminate mechanical malfunction.

The present invention disclosed in FIGS. 12 and 13 relates to a trip hook buffer device 800 of a vacuum breaker manipulator part for preventing a tripping phenomenon of the trip hook 510 in the vacuum breaker manipulator part 10. One side of the vacuum circuit breaker manipulator 10 is provided with a trip hook buffer device 800 of the vacuum circuit breaker manipulator of the present invention.

Specifically, when the trip hook 510 is operated by the closing operation, the interlock device of the vacuum circuit breaker manipulator 10 supports the trip hook 510 and rotates the trip hook 510 clockwise. The present invention is provided to prevent a bounce phenomenon due to impact due to a collision with 910 occurs.

First, in order to explain the closing operation, the configuration of the vacuum circuit breaker operating unit 10 and the operation of the vacuum circuit breaker operating unit 10 will be described.

The vacuum circuit breaker operating unit 10 applies mechanical power to the circuit breaker so that the system is not damaged by the abnormal current in the event of an abnormal current, shuts off the abnormal current, and at the same time, supplies emergency power so that the system can be safely operated. Let's do it.

When the phenomenon of abnormal current is stopped while the emergency power is turned on, the emergency power does not need to be turned on. Therefore, the circuit breaker of the vacuum circuit breaker is connected to apply the general current to receive the general current. It is the role of the vacuum circuit breaker operating unit 10.

1 and 2, the configuration of the vacuum circuit breaker manipulator 10 may include a housing 100, a motor 110 provided in the housing 100, and supplied with power from an external power source. The eccentric gear 120 is rotated in the same direction as the rotational direction of the motor 110 and is formed in the other side, the other side is rotatably coupled to the eccentric gear 120, the eccentric gear 120 A shaft arm 130 for converting a rotational movement of the lower and lower movements, provided with a lower portion of the shaft arm 130, and a step car 140 that rotates stepwise in a predetermined direction according to the lower and lower movement of the chain arm 130; It is provided horizontally on the lower side of the housing 100, the door roller 140 is fixed and the cam shaft portion 200, the cam shaft portion 200 is rotated equally by the rotation of the door roller 140, one side end of the cam shaft portion 200 Is provided in and to rotate the camshaft 200 by the elastic force Spring unit 300, the switch unit 400 is provided on one surface of the housing 100 to instruct the operation of the trip operation or closing operation, the switch unit 400 is provided below the switch unit 400 and An elastic member 150 interposed between the axle arms 130 to elastically support the axle arms 130, and a rear surface of the switch part 400 and in contact with the cam shaft part 200 and in contact with the switch part. An operation provided in the lower portion of the hook portion 500 and the housing 100 to receive the trip operation or closing operation from the 400 to the cam shaft 200 and provided in parallel with the cam shaft 200 The shaft part 600 is comprised.

The eccentric gear 120 corresponds to any one of a bevel gear or a gear that operates the same.

Referring to FIG. 3, the door car 140 has a constant engaging surface 141 and a flat surface 143 formed on an outer circumferential surface thereof, and the axle arm 130 moves up and down to be detached from the engaging surface 141. It is characterized in that for rotating the doorcar 140 in a predetermined direction step by step.

Referring to FIG. 4 for a more detailed description, the camshaft 200 is horizontal to the ground and is cam shaft 210 that is rotatably coupled to the housing 100, and is fixedly coupled to the camshaft 210 and the camshaft ( Input hook cam 220 that rotates in the same direction as the 210, the cam cam 210 is fixedly coupled to the cam shaft 210 rotates in the same direction as the cam shaft 210 and the input cam 230 detachable from the operation shaft 600 and The feed hook cam 220 is configured to include a feed hook roller 240 that is rotatably coupled to the other end.

Here, the shape of the input cam 230 is formed so that the outer circumferential surface is formed of an elliptical curved surface and the central axis is located away from the center of the elliptic curved surface.

Referring to Figure 5 for a more detailed description of the spring 300, one side is coupled to the cam shaft 200 is rotated in the same direction as the rotational direction of the cam shaft 210 and the crank is formed on the other side 310, an input spring support rod 320 provided at an upper side of the housing 100 to be horizontal to the ground, an eccentric coupling to the crank 310, and a groove having a predetermined length is formed on the input spring support rod. The contact 320 is provided on the outer circumferential surface of the input spring rod 330 and the input spring rod 330 for converting the rotational movement of the crank 310 to the lifting and lowering movement along the groove and the input spring rod 330 ) And an input spring 340 interposed between the input spring support rod 320 and the input spring support rod 320.

The switch unit 400 is configured to include at least two switches.

Referring to FIG. 6, the hook part 500 is provided at the rear side of the switch part 400, is fixedly coupled to the other end of the cam shaft part 200, and receives a trip operation from the switch part 400. It is configured to include a hook 510, as shown in the drawing, the trip hook 510 is formed with at least three protrusions.

The hook part 500 is provided on the rear surface of the switch part 400 and is provided on the upper surface of the cam shaft part 200, and is rotatably coupled to the housing 100 to be input from the switch part 400. It is configured to include an input hook 520 for receiving the operation to transfer the operation to the cam shaft 200.

Referring to FIG. 7, the operation shaft part 600 is provided at a lower side of the housing 100 and is provided in parallel with the cam shaft part 200, and a cam shaft part from the operation shaft 680. Lever 1 (610) and lever 2 (620) extending in the direction (200), the trip hook roller 630 is rotatably coupled to one side of the lever 1 (610), the lever 2 (620) Input cam roller 640 is rotatably coupled to one side, the blocking spring support bracket 650 is formed to extend from the operating shaft 680, is formed extending from the operating shaft 680 and the operation shaft 680 A blocking spring for providing a resilient force that is provided on the blocking lever 670 and the blocking spring support bracket 650 for one side end of the lifting and lowering movement with the center of the circle and pushing the blocking spring support bracket 650. 660).

Based on the above configuration, the closing spring charging operation, the tripping operation and the closing operation will be described.

The closing operation is an operation for receiving a normal current again when the normal current is cut off by the operation of the vacuum circuit breaker manipulator 10 and the emergency power is turned on, and the input switch provided in the switch unit 400 is manually operated. Activated when pressed or the input command is dropped by electrical signal.

At this time, the closing spring charging operation should be preceded first, and thus the operation of the vacuum circuit breaker manipulator 10 will be described with reference to FIGS. 8 to 9.

When the closing spring charging operation is executed, emergency power is first applied to the motor 110 to rotate the eccentric gear 120. In this case, the eccentric gear 120 is a bevel gear or a gear having a similar operation is sufficient. The axle arm 130 coupled to the eccentric gear 120 eccentrically moves up and down with the path fixed according to the rotation of the eccentric gear 120.

At this time, the elastic member 150 serves as a link supporting the path for the lifting motion of the shaft arm 130.

The door car 140 provided at the other end of the axle arm 130 is a door car 140 disclosed in FIG. 3 described above, and the outer wheel so that the axle arm 130 can rotate the door car 140. A constant locking surface 141 and a flat surface 143 are formed, and the other end of the shaft arm 130 is caught by the locking surface 141 while the shaft arm 130 moves up and down.

At this time, the axle arm 130 pushes the locking surface 141 to rotate the door car 140 stepwise in a predetermined direction, the flat surface formed in the door car 140 while the locking surface 141 is rotated ( When the door 140 rotates toward the side 143 and the door 140 reaches the flat surface 143, the other end portion of the axle arm 130 pushes the door 140 at the other end. ) Will not be able to rotate the doorcar 140 anymore.

On the other hand, while the door car 140 rotates according to the lifting and lowering motion of the axle arm 130, the cam shaft 210 fixedly coupled to the door car 140 is rotated, the other end of the cam shaft 210 The crank 310 is coupled to rotate. The top surface of the crank 310 is provided with the injection spring rod 330, the other end of the injection spring rod 330 is formed with a constant groove (H) to enable the reciprocating movement, the groove is operated vacuum breaker It is in contact with the closing spring support rod 320 provided on the upper portion of the base housing 100.

At this time, when the crank 310 is rotated along the cam shaft 210 with reference to FIGS. 9A and 9B the injection spring rod 330 is moved upward with respect to the other end coupled to the groove (H). The length of the central axis point A of the rotatably coupled point P of the crank 310 and the input spring support rod 320 is shortened.

At this time, the input spring 340 is provided on the outer circumferential surface of the input spring rod 330 and interposed between the input spring rod 330 and the input spring rod 330 so that the input spring rod 330 is the crank ( As the length of the rotatably coupled point P of 310 and the central axis point A of the input spring support rod 320 becomes shorter, it is compressed.

In this case, referring to FIG. 8, the feed post crawler 240 and the feed hook 520 are in contact with each other. At this time, the closing hook 520 is to suppress the elastic force to the compressed closing spring 340 to rotate the crank 310 shaft, so that the crank 310 and the cam shaft 210 connected thereto is in a stopped state Supports the feed post crawler 240 provided in the feed hook cam 220.

The closing command operates in the compressed closing spring 340, which will be described with reference to FIG.

When the input command is operated, first, the moving rod 410 provided on the rear of the switch unit 400 is operated to push the input hook 520 and contact the input hook 520 ( 240 is peeled off, and the compression spring 340, which has been compressed, is released from restraint by the injection hook 520 so that the crank 310 rotates by an elastic force, and the cam shaft 210 fixed thereto is fixed. Will rotate.

As a result, the feeding cam 230 is rotated to rotate the feeding cam roller 640 connected to the operation shaft 680 according to the outer circumferential surface shape of the feeding cam 230 to rotate the feeding cam roller 640. Press down.

The shape of the input cam 230 is formed so that the outer circumferential surface is formed of an elliptical curved surface and the central axis is located away from the center of the elliptic curved surface.

Accordingly, when the input cam 230 rotates, the input cam roller 640 which is in contact with each other according to the shape of the outer circumferential surface of the input cam 230 is pressed, and the input cam roller 640 is based on the cam shaft 210. Will move in the downward direction.

In this case, the lever 2 620 to which the input cam roller 640 is coupled moves in the downward direction with respect to the cam shaft 210, and rotates downwardly around the manipulation shaft 680 while the blocking lever. 670 is moved upward to operate the circuit breaker of the vacuum circuit breaker so that the general current flows.

The breaker part by the blocking lever 670 may be operated by the blocking lever 670 in direct contact with the breaker part or by a link part interposed between the blocking lever 670 and the breaker part. The configuration of the link unit may correspond to a known technology, and thus a detailed description thereof will be omitted.

In addition, the protrusion of any one of at least three protrusions of the trip hook 510 serves as a fixed support for suppressing rotation of the operation shaft 680 for a blocking operation occurring later. You will encounter This completes the closing operation.

The trip operation is to cut off the general power quickly when abnormal current occurs in the general power. It operates when the trip switch is manually pressed or the input command is dropped by an electrical signal.

At this time, the operation of the vacuum circuit breaker operating unit 10 according to the trip operation will be described with reference to FIG. 11.

The trip operation starts when the trip hook 510 is in contact with the trip hook roller 630. In detail, the trip hook roller 630 is configured to be provided on the lever 1 610 extending and formed on the operation shaft 680, and the blocking spring support is formed to extend on the operation shaft 680. The bracket 650 is in contact with the trip hook 510 while compressing the blocking spring 660.

Looking at the execution of the trip operation with reference to Figure 11, the trip hook 510 which was in contact with the trip hook roller 630 is peeled off while rotating and the trip hook 510 to compress the blocking spring 660. The restraint on the trip hook roller 630 is released so that the blocking spring 660 is extended by the elastic force, the blocking spring support bracket is coupled to the blocking spring 660 and extended to the operation shaft 680 650 is rotated, the operation shaft 680 is rotated according to the direction in which the blocking spring support bracket 650 moves.

At this time, the blocking lever 670, which extends to the operation shaft 680, moves downward to operate the breaker unit to operate a trip operation to cut off a general current in which an abnormal current is generated.

The breaker part by the blocking lever 670 may be operated by the blocking lever 670 in direct contact with the breaker part or by a link part interposed between the blocking lever 670 and the breaker part. The configuration of the link unit may correspond to a known technology, and thus a detailed description thereof will be omitted.

In this state, when the phenomenon in which the abnormal current is generated is stopped, it leads to the first closing spring charging operation.

FIG. 12 is a front view of the overall configuration of the vacuum circuit breaker operating unit 10 in which the present invention is installed, and the present invention corresponds to the portion indicated by the dashed line disclosed in FIG. 12.

Looking at the specific configuration of the present invention with reference to Figure 13 and 14, the present invention is provided through the buffer support rod support 870, the buffer support rod support provided on one side of the vacuum circuit breaker manipulator 10, and up and down An elastic spring 820 for absorbing the impact of the tripping hook 510 provided on the buffer support rod 810, the outer peripheral surface of the buffer support rod 810, the vacuum circuit breaker manipulator 10, the movement It is provided on one side end and the other end of the elastic spring 820 to the spring cap 830 for supporting the elastic spring 820, the outer peripheral surface of the buffer support rod 810 and the lower portion of the spring cam and the buffer support Spring cap support portion 840 interposed between the rod support 870, provided on the lower side of the buffer support rod 810 to support the buffer support rod 810 to be fixed to the buffer support rod support 870 With nut 850 It is configured.

The elastic spring 820 is characterized in that at least two or more.

The upper surface 860 of the buffer support rod is characterized in that it is formed flat.

Hereinafter, the operation of the trip hook shock absorber of the vacuum circuit breaker operating unit of the present invention will be described.

The present invention operates when the closing operation is performed. Referring to the operation of the trip hook 510, the interlock device 910, and the trip hook shock absorber shown in FIG. 13, the closing operation is completed when the closing operation is completed. Trip hook 510 is rotated clockwise (forward in Figure 2).

At this time, the interlock device 910 serves as a stopper that prevents the trip hook 510 from rotating further clockwise when the trip hook 510 rotates clockwise.

Specifically, the trip hook 510 rotates in the clockwise direction so that the trip hook bar 512 is formed to extend from the trip hook 510 to the washer 920 provided on the interlock device 910. It is supported to support the trip hook 510 so that the trip hook 510 no longer rotates clockwise.

In this case, the trip hook 510 bounces back in the counterclockwise direction (backward in FIG. 2) due to the rotational inertia of the trip hook 510 and the collision of the washer 920 and the trip hook bar 512. Phenomenon occurs.

After the trip hook 510 rotates only in a clockwise direction, the trip hook bar 512 is supported on the washer 920 to be stably operated, and the closing operation is completed. The hook 510 is operated counterclockwise to cause a mechanical malfunction.

Therefore, the trip hook shock absorber 800 of the vacuum circuit breaker manipulator of the present invention additionally supports the protrusion 514 of the trip hook bar 512 by the elastic spring 820, and the trip hook 510 by the closing operation. When the clockwise rotation rotates the support more firmly, the shock caused by the collision of the trip hook bar 512 and the washer 920 is buffered.

Specifically, the buffer support rod 810 is in contact with the protrusion 514 extending to the trip hook bar 512, at this time, the elastic spring 820 is provided on the outer peripheral surface of the buffer support rod 810 ) Elastically absorbs the impact of the collision.

The elastic spring 820 is the one end and the other end is in contact with the spring cap 830 and the spring caps 830 are interposed between the upper surface 860 and the spring cap support 840 of the buffer support rod. It is.

In addition, the buffer support rod support 870 supports the lower surface of the spring cap support 840, the buffer support rod 810 is formed through the buffer support rod support 870, the buffer support Constrained vertical movement between the rod support 870 is possible.

Therefore, when the protrusion 514 collides with the upper surface 860 of the buffer support rod, the buffer support rod 810 moves finely downward, and the elastic spring 820 is caused by the collision. The shock is elastically absorbed to prevent the tripping of the trip hook 510.

At this time, the upper surface 860 of the buffer support rod may be composed of a flat.

Although the preferred embodiments of the present invention have been described above, the technical idea of the present invention is not limited to the described embodiments, and may be implemented in various forms without departing from the technical idea of the present invention.

1 is a front view of a vacuum circuit breaker operating unit.

2 is a rear view of the vacuum circuit breaker operating unit.

3 is a cross-sectional view of a portion of the vacuum breaker manipulator portion and is an exploded view of the axle arm and a portion of the configuration connected thereto.

4 is a detailed configuration diagram of a cam shaft part corresponding to a part of the vacuum circuit breaker operating part.

5 is a detailed configuration diagram illustrating a spring part corresponding to a part of the vacuum circuit breaker operating part.

6 is a detailed configuration diagram of a hook portion corresponding to a portion of the vacuum circuit breaker operating unit.

7 is a detailed configuration diagram of an operation shaft part corresponding to a part of the vacuum circuit breaker operating part.

8 is an exploded perspective view of the closing spring charging operation of the vacuum circuit breaker operating unit.

9A and 9B are detailed configuration diagrams of the spring unit according to the closing spring charging operation of the vacuum circuit breaker operating unit.

10 is an exploded perspective view according to the closing operation of the vacuum circuit breaker operating unit.

11 is an exploded perspective view illustrating a trip operation of a vacuum circuit breaker operating unit.

12 is a front view illustrating a trip hook shock absorber according to the present invention.

13 is a perspective view of a detailed configuration of the present invention.

14 is an exploded view of the detailed configuration of the present invention.

<Explanation of symbols for the main parts of the drawings>

100 housing 150 elastic member

110: motor 200: camshaft portion

120: eccentric gear 210: camshaft

130: shaft rock 220: input hook cam

140: door car 230: input cam

240: Post-loaded roller 300: Spring part

310: crank 320: closing spring support rod

330: closing spring rod 340: closing spring

400: switch 410: moving rod

500: hook portion 510: trip hook

520: hook hook 600: control shaft

610: Lever 1 620: Lever 2

630: trip hook roller 640: feed cam roller

650: blocking spring support bracket 660: blocking spring

670: blocking lever 680: control shaft

P: Rotationally coupled point P of the crank 310

A: center axis point (A) of the input spring support rod 320

H: Groove formed in the closing spring rod

870: buffer support rod support 810: buffer support rod

820: elastic spring 830: spring cap

840: spring cap support 850: nut

860: upper surface of the buffer support rod 514: protrusion

512: trip hook bar 510: trip hook

910: interlock device 920: washer

10: vacuum breaker control unit

Claims (3)

A buffer support rod support provided on one side of the vacuum circuit breaker operating unit; A buffer support rod which is provided to penetrate the buffer support rod support and has a flat upper surface, and which moves up and down; An elastic spring provided on an outer circumferential surface of the buffer support rod to absorb an impact of a trip hook provided on the vacuum breaker control unit; A spring cap provided at one end and the other end of the elastic spring to support the elastic spring; A spring cap support part provided on an outer circumferential surface of the buffer support rod and interposed between a lower portion of the spring cap and the buffer support rod support; A nut provided at a lower side of the buffer support rod to support the buffer support rod to be fixed to the buffer support rod support; Trip hook shock absorber configured to include a vacuum circuit breaker control unit. The method of claim 1, Trip spring buffer device of the vacuum circuit breaker control unit, characterized in that at least two elastic springs. delete

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