KR20190002819U - Bypass switch - Google Patents

Abstract

The bypass switch according to an embodiment of the present invention, the vacuum interrupter is movable movable contact is fixed to the fixed contact; A moving pusher connected to the movable contact and having a locking groove formed therein; A driving source for pushing a moving pusher to a position where the movable contact and the fixed contact are in contact; A latch elastic member caught in the locking groove; And a latch mounter formed with a latch mounting groove to which the latch elastic member is mounted and surrounding at least a portion of an outer circumference of the moving pusher.

Description

Bypass Switch {BYPASS SWITCH}

The present invention relates to a bypass switch, and more particularly, to a bypass switch having a vacuum interrupter in which the movable contact is moved to contact with the fixed contact.

When the bypass switch is installed in an electric device such as a converter and senses an abnormality such as a failure, the bypass switch may be short-circuited to minimize the propagation of the effect of the failure to other parts installed in the electric device such as a converter.

The bypass switch is provided in a converter used for high voltage direct current (HVDC), or in a STATCOM / Static Synchronous Compensator or Static Var Compensator (SVC). It can be used as a high speed short circuit bypass switch which is shorted at high speed.

High Voltage Direct Current (HVDC) is a power transmission facility in which a power station converts AC power produced in a power plant into DC power to transmit power, and then converts it into AC in a power station to supply power.

In addition, the static synchronous compensator is used as a compensating device for reactive power and active power in the power system when transmitting and distributing electricity, and is a facility to improve the stability by supplementing the loss voltage.

When the bypass switch is provided in a converter composed of a plurality of sub-module combinations, when an abnormality such as a failure of the sub-module is detected, the bypass switch shorts the sub-detected sub-modules to prevent the influence of the failure from propagating to other sub-modules. can do.

The self failure of the submodule may be when there is no feedback signal from the submodule, when a voltage higher than a design value is applied to the submodule, when a communication function of the submodule is abnormal, when a driver failure of the submodule occurs, and the like.

The bypass switch may include a movable contact and a fixed contact. The bypass switch may further include a first bus bar connected to the fixed contact point and a second bus bar connected to the movable contact point, and when an external force is applied to the movable contact point, the movable contact point may be moved to the fixed contact point to contact the fixed contact point.

The bypass switch may further include a driving source generating a driving force for moving the movable contact, and the driving contact of the driving source may be moved to the fixed contact to be in contact with the fixed contact.

When contacting the movable contact and the fixed contact by the driving of the drive source as described above, the current may flow to the first fixed busbar, the fixed contact, the movable contact, and the second busbar, the bypass switch may be short-circuited.

The bypass switch disclosed in the prior document JP 5791847B1 uses a mechanical latch to keep the fixed and movable contacts of the vacuum interrupter open. However, these mechanical latches have a disadvantage in that the structure is complicated and the number of parts is high, and thus the probability of failure and the manufacturing cost are high.

Prior art documents JP 5241820B2, KR 10-2014-0084795A, KR 10-1613812B1 and KR 10-2017-0096539A use magnets (permanent magnets) to keep the fixed and movable contacts of the vacuum interrupter open. However, the latch using the magnet may be damaged by an operation shock during open / close, and the magnetic force may be weakened by deterioration when the bypass switch is used at a high temperature.

JP 5791847B1 (registered August 14, 2015) JP 5241820B2 (registered April 12, 2013) KR 10-2014-0084795A (released July 7, 2014) KR 10-1613812B1 (registered April 12, 2016) KR 10-2017-0096539A (released August 24, 2017)

One problem to be solved by the present invention is to provide a bypass switch having a relatively simple configuration.

Another object of the present invention is to provide a bypass switch having a latch resistant to high temperature and impact, unlike a magnet.

The bypass switch according to an embodiment of the present invention, the vacuum interrupter is movable movable contact is fixed to the fixed contact; A moving pusher connected to the movable contact and having a locking groove formed therein; A driving source for pushing the moving pusher to a position where the movable contact point and the fixed contact point contact; A latch elastic member caught in the locking groove; And a latch mounter formed with a latch mounting groove to which the latch elastic member is mounted and surrounding at least a portion of an outer circumference of the moving pusher.

The locking groove may be formed at an outer circumference of the moving pusher, and the latch mounting groove may be formed at an inner circumference of the latch mounter.

The moving pusher includes: a pushing body connected to the movable contact; And a latching body connected to the pushing body and having the latching groove formed therein.

A play is formed between the pushing body and the latching body, and the play may be located at an outer circumference of the moving pusher.

The moving pusher may further include a gapper disposed at the play.

The gapper may have a metal material.

The latching body, the latching groove is formed on the outer circumference and the hollow hollow formed therein; And a first fastening part protruding from the latching part toward the pushing body and fastened to the pushing body.

The pushing body may include a pushing unit connected to the movable contact; An extension part extending from the pushing part toward the latching body and having a hollow formed therein; A second fastening part protruding toward the latching body from the extension part and fastened to the latching body may be formed.

A female screw portion may be formed at an inner circumference of one of the first and second fastening portions, and a male screw portion may be formed at the other outer circumference to engage the female screw portion.

The moving pusher may include: an inner body connecting the pushing body and the driving source and at least a part of which is located inside the latching body; And an inner spring elastically supporting the inner body in a direction in which the movable contact and the fixed contact are in contact with each other.

The latch elastic member may be caught in the locking groove when the fixed contact and the movable contact are spaced apart from each other, and may be separated from the locking groove when the movable shaft moves in a direction in contact with the fixed shaft.

The locking groove may include a first surface formed obliquely with an outer circumference of the moving pusher; A second surface spaced apart from the first surface and formed obliquely in a direction opposite to the first surface at an outer circumference of the moving pusher; And a third surface parallel to the longitudinal direction of the moving pusher and connecting the first surface and the second surface.

The locking groove may include a first surface formed obliquely with an outer circumference of the moving pusher; The second surface may include a second surface connected to the first surface and formed obliquely in a direction opposite to the first surface at an outer circumference of the moving pusher.

The locking groove may be formed to be round.

According to a preferred embodiment of the present invention, by using the latch elastic member in place of the magnet weak to high temperature and impact, there is an advantage that the damage caused by the impact and deterioration due to the high temperature does not occur.

In addition, the configuration of the bypass switch can be simplified, and manufacturing cost can be reduced.

In addition, the pushing body and the latching body constituting the moving pusher can be adjusted in clearance, the gap may be equipped with a gapper. That is, even if damage and clearance between the contact points of the vacuum interrupter due to the operation shock of the bypass switch occurs, if the moving pusher is assembled by mounting the gapper corresponding to the clearance, the bypass switch can be reused.

Figure 1 is a longitudinal cross-sectional view before operation of the bypass switch according to an embodiment of the present invention.
FIG. 2 is an enlarged view of the periphery of the moving pusher shown in FIG. 1.
Figure 3 is a longitudinal cross-sectional view after the operation of the bypass switch according to an embodiment of the present invention.
4 is an enlarged view of the periphery of the moving pusher shown in FIG. 3.
5 is a view for explaining the coupling relationship between the pushing body, the latching body and the gapper.
6 is a view showing an example of the locking groove.
7 is a view showing another example of the locking groove.
8 is a view showing another example of the locking groove.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, which are intended to be described in detail so that those skilled in the art to which the present invention pertains can easily implement the present invention. It does not mean that the technical spirit and scope of the invention is limited.

Figure 1 is a longitudinal cross-sectional view before operation of the bypass switch according to an embodiment of the present invention, Figure 2 is an enlarged view of the moving pusher shown in Figure 1, Figure 3 according to an embodiment of the present invention The longitudinal cross-sectional view after operation of the bypass switch, Figure 4 is an enlarged view of the periphery of the moving pusher shown in FIG.

The bypass switch according to the exemplary embodiment of the present invention includes a vacuum interrupter 2 in which the movable contact 22 is movable to the fixed contact 21; A moving pusher 3 connected to the movable contact 22 and having a locking groove 41 formed therein; A driving source 5 for pushing the moving pusher 3 to a position where the movable contact 22 and the fixed contact 11 are in contact; A latch elastic member 6 which is caught by the locking groove 41; And a latch mounter 10 formed with a latch mounting groove 10A on which the latch elastic member 6 is mounted and surrounding at least a portion of an outer circumference of the moving pusher 3. This will be described in more detail below.

Bypass switch according to an embodiment of the present invention may include a casing (1).

The casing 1 may form the appearance of the bypass switch. The casing 1 may be composed of a combination of a plurality of members. The casing 1 may include a current carrying casing having a current carrying material such as aluminum and an insulating casing having an insulating material such as a composite member. The casing 1 may be composed of a combination of at least one energizing casing and at least one insulating casing. The casing 1 may include a plurality of energizing casings. The insulating casing may be disposed between the plurality of energizing casings.

The casing 1 may have a space in which the vacuum interrupter 2 is disposed.

The vacuum interrupter 2 may be arranged such that the movable contact 21 is movable to the fixed contact 21. In the open state of the bypass switch, the movable contact 22 may be spaced apart from the fixed contact 21, and in the closed state of the bypass switch, the movable contact 22 is in contact with the fixed contact 21. Can be.

A fastening member insertion groove 21A may be formed in the fixed contact 21, and a fastening member such as a screw may be fastened to the fastening member insertion groove 21A by passing through a busbar. As a result, the fixed contact 21 and the busbar may be energized.

The vacuum interrupter 2 may be arranged inside the casing 1. The vacuum interrupter 2 can be arranged in the space 11 of the casing 1 and can be protected by the casing 1. The outer circumference of the vacuum interrupter 2 can face the outer circumference of the casing 1.

The vacuum interrupter 2 may comprise an inner housing 23. The inner housing 23 may form the appearance of the vacuum interrupter 2. The inner housing 23 may be a vacuum housing in which an inner space 24 is formed.

The movable contact 22 may be movably disposed in the inner housing 23. The inner housing 23 may have a movable contact through hole through which the movable contact 22 is movably penetrated.

The fixed contact 21 may be installed to be fixed to the inner housing 23. The inner housing 23 may be formed with a fixed contact through hole through which the fixed contact 21 is disposed. The fixed contact through hole may be formed at a position facing the movable contact through hole.

The inner housing 23 may be disposed in the casing 1 in the longitudinal direction of the casing 1. The outer circumferential surface of the inner housing 23 may constitute the outer circumferential surface of the vacuum interrupter 2, and the outer circumferential surface of the inner housing 23 may face the inner circumference of the casing 1.

The moving pusher 3 may be connected to the movable contact 22 to move the movable contact 22. The movable contact 22 may contact or be separated from the fixed contact 21 when the moving pusher 3 is moving. The moving pusher 3 may move the movable contact 22 in one direction (for example, the left direction) such that the movable contact 22 is in contact with the fixed contact 21. The moving pusher 3 may move the movable contact 21 in another direction (for example, to the right) such that the movable contact 22 is spaced apart from the fixed contact 21.

The moving pusher 3 is disposed between the driving source 5 and the movable contact 22 to push the movable contact 22 so that the movable contact 22 contacts the fixed contact 21 when the driving source 5 is driven. Can be. The moving pusher 3 may be a movable contact connector connected to the movable contact 22. The moving pusher 3 together with the movable contact 21 can constitute a moving assembly.

The moving pusher mounter 13 may be disposed inside the casing 1, and the moving pusher 3 may move inside the moving pusher mounter 13.

The moving pusher mounter 13 may have a hollow cylinder shape, and may be provided to surround the outer circumference of the moving pusher 3. That is, the moving pusher 3 may move inside the moving pusher mounter 13, and the moving pusher mounter 13 may serve as a moving guide for guiding the moving direction of the moving pusher 3.

The moving pusher mounter 13 may be located at least partially outside the vacuum interrupter 2.

The moving pusher 3 may be composed of a combination of a plurality of members. More specifically, the moving pusher 3 may include a pushing body 31 connected to the movable contact 22 and a latching body 32 connected to the pushing body 31 and having a locking groove 41 formed therein.

The pushing body 31 may be connected to the movable contact 22 to move the movable contact 22. The pushing body 31 may be at least partially located outside the vacuum interrupter 2 and connected to the movable contact 22.

The pushing body 31 may be formed integrally with the movable contact 22, or may be formed as a separate member from the movable contact 22 and connected to the movable contact 22. When the pushing body 31 is connected to the movable contact 22, the protrusion 31A formed on the pushing body 31 may be inserted into and fixed to the protrusion insertion groove 22A formed on the movable contact 22, and the pushing body The 31 and the movable contact 22 can be integrally moved. On the contrary, of course, the protrusion formed in the movable contact 22 may be fitted into the protrusion insertion groove formed in the pushing body 31.

The pushing body 31 may include a pushing part 36, an extension part 37, and a fastening part 38.

The pushing unit 36 may be connected to the movable contact 22. A protruding portion 31A may be formed at an end portion of the pushing portion 36. The pushing portion 36 may be formed in a substantially cylindrical shape.

The connection part insertion groove part 36A may be formed in the pushing part 36. The connection part insertion groove 36A may be formed at opposite ends of one end connected to the movable contact 22 among both ends of the pushing part 36. The connection part insertion groove part 36A may be inserted by inserting the connection part 41A formed in the inner body 33 to be described later.

The extension 37 may extend from the pushing portion 36 toward the latching body 32. In more detail, the extension 37 may extend toward the latching body 32 at the opposite end of one of the ends of the pushing portion 36 connected to the movable contact 22.

A hollow may be formed in the extension part 37, and a part of the inner body 33 to be described later may be inserted into the hollow. The hollow may be in communication with the connection portion insertion groove portion 36A formed in the pushing portion 36.

The fastening part 38 may protrude toward the latching body 32 from the extension part 37 and may be fastened with the latching body 32. The fastening portion 38 may have a hollow cylinder shape.

Meanwhile, the latching body 32 may be connected to the pushing body 31 to move together with the pushing body 31. A locking groove 41 is formed at an outer circumference of the latching body 32, and the latch elastic member 6 to be described later is caught by the locking groove 41 to maintain the open state of the bypass switch. Detailed configuration of the locking groove 41 will be described later.

The latching body 32 may include a latching portion 39 and a fastening portion 40.

The latching part 39 may have a hollow cylinder shape and a hollow may be formed therein. At the outer circumference of the latching portion 39, a latching groove 41 for catching the latch elastic member 6 may be formed. The locking groove 41 may be formed by recessing in the radially inner direction of the latching portion 39 at the outer circumference of the latching portion 39.

In the open state of the bypass switch before the driving source 5 is operated, the latching elastic member 6 may be caught in the locking groove 41. This makes it possible to prevent the moving pusher 3 and the movable contact 22 from moving toward the stationary contact 21 in spite of the elastic force of the inner spring 8 to be described later.

The fastening part 40 may extend from the latching part 39 to the pushing body side and may be fastened to the pushing body 31. In more detail, the fastening portion 40 of the latching body 32 may be fastened to the fastening portion 38 of the pushing body 31. For convenience of description, the fastening portion 40 of the latching body 32 is named as the first fastening portion, the fastening portion 38 of the pushing body 31 as the second fastening portion, and the first fastening portion 40 and The fastening method of the second fastening portion 38 will be described later in detail.

Meanwhile, the moving pusher 3 may further include a gapper 7.

A play may be formed between the pushing body 31 and the latching body 32, and the play may be located at an outer circumference of the moving pusher 3. As the distance of the clearance increases, the overall length of the moving pusher 3 may be longer. That is, it is possible to adjust the length of the moving pusher (3) by adjusting the play.

The gapper 7 may be disposed at the clearance and may be in contact with the pushing body 31 and the latching body 32, respectively. That is, the gapper 7 can be fitted between the pushing body and the latching body. Since the play is located at the outer circumference of the moving pusher 3, the operator can easily fit the gapper 7 to the play.

The gapper 7 may be formed in a ring shape. In addition, the gapper 7 may be formed of a metal material in order to secure sufficient rigidity, and may withstand the shock during operation of the bypass switch.

Meanwhile, the moving pusher 3 may further include an inner body 33 and an inner spring 8.

The inner body 33 may connect the pushing body 31 and the driving source 5. In addition, at least a portion of the inner body 33 may be located inside the latching body 32.

The inner body 33 may be connected to the driving source 5 to transmit the driving force of the driving source 5 to the pushing body 31. The inner body 33 may move together with the pushing body 31 and the latching body 32.

The inner body 33 may be composed of a single member and may be composed of a plurality of members.

When the inner body 33 is composed of a plurality of members, the inner body 33 includes a movable part extending member 34 connected to the pushing body 31 and a movable pin 35 connected to the movable part extending member 34. can do.

The movable pin 35 may be exerted by an external force by the piston 53, which will be described later, of the driving source 5. At the end of the movable pin 35, the fitting portion 35A may be inserted into and fixed to the fitting insertion groove portion 42A formed in the movable portion extending member 34, and the movable pin 35 and the movable portion extending member 34 may be fixed. You can move it integrally.

One end of the movable portion extending member 34 may be connected to the movable pin 35, and the other end may be connected to the pushing body 31, more specifically, the pushing unit 36.

The movable part extending member 34 may include a flange part 41 and a rod part 42 protruding toward the driving source 5 from one surface of the flange part 41 and connected to the movable pin 42.

The diameter of the flange portion 41 may be larger than the diameter of the rod portion 62. The flange portion 41 may have a substantially disc shape.

The flange portion 41 may be disposed in a hollow formed in the extension 37 of the pushing body 31. The outer circumference of the flange portion 41 may be in contact with the inner circumference of the extension portion 37. The connection part 41A formed on one surface of the flange part 41 may be inserted into and fixed to the connection part insertion groove part 36A formed in the pushing part 36.

The rod part 42 may protrude from the other surface of the flange part 41 to be formed long. The fitting portion insertion groove portion 42A formed in the rod portion 42 may be inserted into and fixed to the fitting portion 35A formed on the movable pin 35.

At least a portion of the rod portion 42 may be located in a hollow formed inside the latching body 32. That is, the movable portion extending member 34 may be connected to the pushing body 31 by passing through the latching body 32.

The inner spring 8 may be provided to be wound around the outer circumference of the rod portion 42.

In more detail, with respect to the radial direction of the inner body 33, the inner spring 8 has a respective inner circumference of the latching body 32 and the extension 37 of the pushing body 31, and of the rod portion 42. It can be arranged between the outer circumference.

In addition, with respect to the longitudinal direction of the inner body 33, the inner spring 8 may be disposed between the flange portion 41 and the sub casing 11 to be described later. The inner spring 8 can be pressed or tensioned between the flange portion 41 and the sub casing 11.

In the open state of the bypass switch, the inner spring 8 may be more compressed than its original length, and the inner spring 8 may be in the direction in which the movable contact 22 and the fixed contact 21 are in contact with each other. ) Can be elastically supported. However, since the latch elastic member 6 is caught in the locking groove 41, the moving pusher 3 may not be moved and the open contact 22 and the fixed contact 21 may be kept open. That is, the friction force between the latch elastic member 6 and the locking groove 41 may be greater than the elastic force by the inner spring 8.

When the piston 53 of the drive source 5 pushes the movable pin 35 and the latch elastic member 6 detaches from the engaging groove 41, the movable pusher 3 has the movable contact 22 having the fixed contact 21. It can move in the direction of contact with the movable contact 22 can contact the fixed contact 21, the bypass switch can be closed. In the closed state of the bypass switch, the inner spring 8 can maintain the contact between the movable contact 22 and the fixed contact 21.

Meanwhile, the latch mounter 10 may be provided to surround at least a part of the outer circumference of the moving pusher 3. In more detail, the latch mounter 10 may be provided to surround the outer circumference of the latching body 32. The latch mounter 10 may be integrally formed with the casing 1 or may be a separate member from the casing 1.

The latch mounter 10 may have a hollow cylinder shape, and the latching body 32 may be disposed in the latch mounter 10 to be movable. The inner circumference of the latch mounter 10 may face the outer circumference of the latching body 32.

A latch mounting groove 10A may be formed in the latch mounter 10. The latch mounting groove 10A may be recessed in the inner circumference of the latch mounter 10, and the latch elastic member 6 may be mounted.

The latch elastic member 6 may be formed of a material having at least a portion of the elasticity. In one example, the latch elastic member 6 may include a spring.

The latch elastic member 6 may have a substantially ring shape.

The latch elastic member 6 may be mounted in the latch mounting groove 10A formed in the latch mounter 10. At least a part of the latch elastic member 6 is provided to protrude into the latch mounter 10, and may be caught or separated from the latching groove 41 of the latching body 32.

In more detail, the latch elastic member 6 may be caught by the locking groove 41 when the fixed contact 21 and the movable contact 22 are in an open state.

On the other hand, when the movable blade 22 moves in the direction of contact with the fixed blade 21, the latch elastic member 6 may be separated from the locking groove 41. When the latch elastic member 6 is separated from the locking groove 41, the latch elastic member 6 may be compressed in the radial direction of the moving pusher 3. As a result, the latch elastic member 6 may elastically support the moving pusher 3 in the radial direction of the moving pusher 3.

On the other hand, the bypass switch according to the present embodiment may further include a sub casing (11). The sub casing 11 may be fastened to the casing 1 or the latch mounter 10.

When the sub casing 11 is fastened to the latch mounter 10, the latch mounter 10 may have a sub casing insertion hole 10B penetrated in the length direction of the bypass switch. The sub casing 11 may be inserted into and fastened to the sub casing insertion hole 10B.

In addition, the sub casing 11 may be coupled with a bus bar (not shown), and may energize the movable contact 22 and the bus bar through the moving pusher 3. In this case, the sub casing 11 may be formed of a current carrying material, and may be referred to as a current carrying casing.

A first hollow 18 into which the housing 52, which will be described later, of the driving source 5 is inserted, and a second hollow 19 in which the movable pin 35 is movable are formed in the sub casing 11. Can be.

The first hollow 18 and the second hollow 19 may communicate with each other, and may pass through the sub casing 11 together in the longitudinal direction of the bypass switch.

The inner diameter of the first hollow 18 may be larger than the inner diameter of the second hollow 19, and the length of the first hollow 18 may correspond to the length of the housing 52. The first hollow 18 may be a housing mounting hole. In addition, the second hollow 19 may guide the movement of the movable pin 35. That is, the sub casing 11 may simultaneously perform the roles of the movable pin guide and the driving source mounting unit.

In more detail, the sub casing 11 may include a body portion 14, a cover mounting portion 15, a mounter mounting portion 16, and a guide portion 17.

The body portion 14 may be fastened to cover the end of the latch mounter 10.

The cover mounting part 15 may protrude from one surface of the body part 14 toward the driving source cover 12 to be described later. The cover mounting portion 15 may be covered by the drive source cover 12. In addition, at least a portion of the first hollow 18 described above may be formed in the cover mounting part 15.

The diameter of the cover mounting portion 15 is preferably smaller than the diameter of the body portion 14.

The mounter mounting portion 16 may be inserted into and mounted in the sub casing insertion hole 10B formed in the latch mounter 10. The mounter mounting portion 16 may be formed to protrude toward the moving pusher 3 from the other surface of the body portion 14.

It is preferable that the diameter of the mounter mounting portion 16 is smaller than the diameter of the body portion 14.

The guide part 17 may protrude from the mount mounting part 16 to the moving pusher side. At least a portion of the second hollow 19 described above may be formed in the guide part 17. That is, the movable pin 35 is disposed to be movable in the guide portion 17, and the guide portion 17 may guide the movement of the movable pin 35.

At least a portion of the guide portion 17 may be drawn into the latching body 32. At least some of the outer circumference of the guide portion 17 may face the latching body 32, more specifically, the inner circumference of the latching portion 39.

The inner spring 8 may be in contact with the end of the guide portion 17. The guide portion 17 supports the inner spring 8 so that the inner spring 8 can be compressed or tensioned between the guide portion 17 and the flange portion 41 of the movable portion extending member 34.

On the other hand, the drive source 5 is installed in the casing 1 and can push the moving pusher 3 to the position where the movable contact 21 and the fixed contact 22 contact. The drive source 5 preferably moves the moving pusher 3 at high speed. The driving source 5 may be inserted into and mounted in the first hollow 18 of the sub casing 11.

The drive source 5 may comprise an explosive actuator. In one example, the drive source 5 may comprise a Pyrotechnic actuator.

When the explosive actuator is driven, the piston 53 may exert an external force greater than the friction force between the latch elastic member 6 and the locking groove 41.

Hereinafter, the same reference numerals are used for the drive source 5 and the explosive actuator 5 for convenience.

The explosive actuator 5 has a single operation characteristic, and the bypass switch may be in an open state in which the movable contact and the fixed contact are spaced apart before the operation of the explosive actuator. When the explosive actuator 5 is operated, the moving assembly composed of the moving pusher 3 and the movable contact 22 can move in the direction in which the movable contact 22 is in contact with the fixed contact 21.

The explosive actuator 5 may be installed in the sub casing 11. The explosive actuator 5 may push the inner body 33, more specifically the movable pin 35 so that the movable contact 21 is in contact with the fixed contact 22.

The explosive actuator 5 may include a piston 53 and an inflator 51 which blows gas into the piston 53 to operate the piston 53.

The inflator 51 may include a housing 52 in which a space 54 for ejecting gas is formed, and a gas ejector for ejecting gas into the space 54 of the housing 52.

The piston 53 is movably disposed in the space 54 of the housing 52 and can be moved at a high speed by the gas blown into the space 54.

When the inflator 51 is operated, the piston 53 may be advanced and advanced to the second hollow 19 of the sub casing 11 to push the movable pin 35 toward the vacuum interrupter 2.

The inflator 51 may eject gas into the space 54 when power is applied from the outside, and the piston 53 is pushed by the gas ejected into the space 54 to operate the inner body 33, and more specifically, to move the gas. The pin 35 can be pushed in the direction in which the vacuum interrupter 2 is located. In this case, the pushing body 31 may be pushed by the inner body 33 to bring the movable contact 22 into contact with the fixed contact 21. When the high pressure gas is blown out into the space 54 of the housing 52, the piston 53 can be quickly moved by this high pressure gas.

The housing 52 may be inserted into the first hollow 18 formed in the sub casing 11. The outer circumference of the housing 52 may face the inner circumference of the first hollow 18.

The inflator 51 may be located outside the sub casing 11, and the drive source cover 12 may cover at least a portion of the inflator 51.

The drive source cover 12 may be fastened to the sub casing 11 by surrounding at least a portion of the inflator 51. In more detail, the cover mounting portion 15 of the sub casing 11 may be inserted into the sub casing 11 and fixed.

An open hole may be formed in the drive source cover 12, and a part of the inflator 51 may pass through the open hole and be exposed to the outside of the drive source cover 12. A portion of the inflator 51 exposed to the outside of the driving source cover 12 may be connected to a wire (not shown) for applying power to the explosive actuator 5.

Hereinafter, the operation of the bypass switch according to the present embodiment will be described.

First, when a firing signal is applied to the drive source 5 from the outside, the drive source 5 can push the piston 53 in the direction in which the vacuum interrupter 2 is located. Upon application of the firing signal, the inflator 51 may eject a high pressure gas into the space 54 of the housing 52, and the piston 53 may eject the high pressure gas into the space 54 of the housing 52. It can be advanced in the direction in which the vacuum interrupter 2 is located.

Upon advancing the piston 53, the piston 53 can push the moving pusher 3 in the direction in which the vacuum interrupter 2 is located.

The piston 53 may apply an external force greater than the friction force between the latch elastic member 6 and the locking groove 41 to the inner body 33, and the latch elastic member 6 may be separated from the locking groove 41 and may be in the inner body 33. The body 33 may be close to the vacuum interrupter 2 while moving away from the sub casing 11. The inner body 33, which is moved by the piston 53, can push the pushing body 31.

The latch elastic member 6 detached from the engaging groove 41 may contact the outer periphery of the moving pusher 3, and more particularly, the latching body 32 to exert an elastic force in the radial direction of the latching body 32. By the elastic force of the latch elastic member 6, the center position of the latching body 32 can be fixed.

The pushing body 31 is slid inside the moving pusher mounter 13 and can be moved in the direction in which the vacuum interrupter 2 is located, and the movable contact 22 connected to the pushing body 31 is a fixed contact 21. Can be advanced, the movable contact 22 can be in contact with the fixed contact 21. That is, the bypass switch can be shorted and current can flow through the bypass switch.

When the moving pusher 3 moves as described above, the inner spring 8 may be elastically restored to push the movable part extending member 34 of the inner body 33 in the direction in which the vacuum interrupter 2 is located. The moving pusher 3 and the movable contact 22 do not return to their original positions due to the force of the inner spring 8 pushing the flange portion 41 of the movable portion extension member 34, and the movable contact 22 is a fixed contact ( 21) can be kept in contact with it.

If the inner spring 8 does not press the movable portion extending member 34 in the direction in which the vacuum interrupter 2 is located, the explosive actuator 5 detonates, and then the piston 53 vibrates the inflator 51 by vibration or the like. Can be retracted in this direction, in which case gas in the housing 52 can leak, and the movable contact 22 can be separated from the fixed contact 21 by the retraction of the piston 51 and the gas leakage.

However, when the inner spring 8 presses the movable portion extending member 34 in the direction in which the vacuum interrupter 2 is located as described above, the piston 53 is minimized to be retracted in the direction of the inflator 51 by vibration or the like. Gas leakage in the housing 52 can be minimized, and the contact holding reliability of the movable contact 22 and the fixed contact 21 can be improved.

5 is a view for explaining the coupling relationship between the pushing body, the latching body and the gapper.

Due to the one-time operation characteristic of the explosive actuator 5, the bypass switch must be reused by replacing the explosive actuator 5 after one operation.

However, contact damage may occur due to the impact of the fixed contact 21 and the movable contact 22 when the explosive actuator 5 is operated, and the fixed contact 21 may be replaced when the explosive actuator 5 is replaced and reused. There is a fear that a gap occurs between the movable contact 22 and a contact failure phenomenon. As described above, the pushing body 31 and the latching body 32 may be formed as separate members to be fastened to alleviate this concern.

The first fastening portion 40 of the latching body 32 and the second fastening portion 38 of the pushing body 31 may be fastened to each other.

One of the first fastening part 40 and the second fastening part 38 may have a female thread part formed at the inner circumference and a male thread part fastened to the female thread part at the other outer circumference. Hereinafter, for convenience of description, a case where the male screw portion 40A is formed on the outer circumference of the first fastening portion 40 and the female screw portion 38A is formed on the inner circumference of the second fastening portion 38 will be described as an example. .

The operator may rotate the latching body 32 with respect to the pushing body 31 to fasten the male screw portion 40A of the first fastening portion 40 to the female screw portion 38A of the second fastening portion 38. The male screw portion 40A and the female screw portion 38A are fastened to each other, and the first fastening portion 40 may be slowly introduced into the second fastening portion 38, and the first fastening portion 40 of the latching body 32 may be formed. ) And the outer play g formed between the extension portion 37 of the pushing body 32 and the latching portion 39 of the latching body 32 and the second fastening portion 38 of the pushing body 31. The play may slowly decrease. The outer play may mean a portion in which the gapper 7 is mounted in FIG. 5.

The operator may adjust the distance of the outer play by adjusting the fastening degree of the first fastening portion 40 and the second fastening portion 38, and adjust the overall length of the pushing body 31 and the latching body 32 assembly. Can be. Therefore, even if a play occurs between the movable contact 22 and the fixed contact 21 by the operation of the explosive actuator 5, the length of the pushing body 31 and the latching body 32 assembly is increased by the play. The movable contact 22 and the fixed contact 21 can be reliably contacted.

Thereafter, the worker may insert the gapper 7 corresponding to the length of the outer clearance into the outer clearance between the pushing body 31 and the latching body 32. The pushing body 31 and the latching body 32 may be firmly fastened by the gapper 7, and the outer play, which may be damaged by impact during operation of the explosive actuator 5, may be reinforced.

In addition, a separate gapper (not shown) may be provided in the inner clearance g as well as the outer clearance.

6 is a view showing an example of the locking groove, Figure 7 is a view showing another example of the locking groove, Figure 8 is a view showing another example of the locking groove.

The friction force between the latch elastic member 6 and the locking member may vary depending on the shape of the locking groove 41.

For example, the locking groove 41 is connected to the first surface 42 formed obliquely with the outer circumference of the moving pusher 3, and is connected to the first surface 42, and at the outer circumference of the moving pusher 3. It may include a second surface 43 formed obliquely in the opposite direction to the first surface 42. In more detail, the first surface 42 and the second surface 43 may be formed obliquely at the outer circumference of the latching portion 39 of the latching body 32.

When the latch elastic member 6 having a circular cross section is caught in the locking groove 41 according to the present example, the latch elastic member 6 is in line contact with the first surface 42 and the second surface 43, respectively. Can be. The locking groove 41 ′ according to the present example may be employed when a small friction force is required for the latching elastic member 6.

As another example, the locking groove 41 ′ is spaced apart from the first surface 44 formed obliquely with the outer circumference of the moving pusher 3, and the outer circumference of the moving pusher 3. The first surface 44 and the second surface 45 in parallel with the longitudinal direction of the moving pusher 3 and the second surface 45 formed obliquely in the opposite direction to the first surface 44 It may include a third surface 46 for connecting. In more detail, the first surface 44 and the second surface 45 may be formed obliquely at the outer circumference of the latching portion 39 of the latching body 32, and the third surface 46 may be formed. It may be formed flat with respect to the direction parallel to the longitudinal direction of the portion 39.

When the latch elastic member 6 having a circular cross section is caught in the engaging groove 41 ′ according to the present example, the latch elastic member 6 has the first surface 44, the second surface 45, and the third surface. Line contact with 46 is possible. Accordingly, since the engaging groove 41 ′ according to the present example has more portions in line contact with the latch elastic member 6 than the engaging groove 41 according to the example described above, the frictional force with the latching elastic member 6 is increased. Can be larger. The locking groove 41 ′ according to the present example may be employed when a moderate friction force is required for the latching elastic member 6.

As another example, the locking groove 41 "may be rounded. That is, the locking groove 41" may be in surface contact with the outer circumference of the latch elastic member 6 having a circular cross section. Therefore, the locking groove 41 "according to the present example may have a greater frictional force with the latching elastic member 6 than the locking groove 41 according to the above-described example and the mounting groove 41` according to another example. The catching groove 41 "according to this example can be employed when a large friction force is required for the latching elastic member 6.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and variations without departing from the essential characteristics of the present invention.

Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments.

The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas falling within the scope of the present invention should be interpreted as being included in the scope of the present invention.

1: casing 10: latch mounter
11: sub casing 12: drive source cover
13: Moving Pusher Mounter 2: Vacuum Interrupter
21: fixed contact 22: movable contact
3: moving pusher 31: moving body
32: latching body 33: inner body
34: movable part extension member 35: movable pin
36: pushing part 37: extension part
38: Fastening part 38A: Female thread part
39: latching part 40: fastening part
40A: Male thread portion 41: Hanging groove
5: drive source 51: inflator
52: housing 53: piston
6: latch elastic member 7: gapper
8: inner spring

Claims (14)

A vacuum interrupter in which the movable contact is movable to the fixed contact;
A moving pusher connected to the movable contact and having a locking groove formed therein;
A driving source for pushing the moving pusher to a position where the movable contact point and the fixed contact point contact;
A latch elastic member caught in the locking groove; And
And a latch mounter formed with a latch mounting groove to which the latch elastic member is mounted and surrounding at least a portion of an outer circumference of the moving pusher. The method of claim 1,
The locking groove is formed in the outer circumference of the moving pusher, the latch mounting groove is a bypass switch formed in the inner circumference of the latch mounter. The method of claim 1,
The moving pusher is,
A pushing body connected to the movable contact; And
And a latching body connected to the pushing body and having a latching groove formed therein. The method of claim 3, wherein
A play is formed between the pushing body and the latching body,
The play is a bypass switch located at the outer circumference of the moving pusher. The method of claim 4, wherein
The moving pusher is,
The bypass switch further comprises a gapper disposed in the play. The method of claim 5,
The gap switch is a bypass switch having a metal material. The method of claim 4, wherein
The latching body,
A latching portion in which the engaging groove is formed at the outer circumference and a hollow is formed therein; And
A bypass switch protruding from the latching part toward the pushing body and including a first fastening part fastened to the pushing body. The method of claim 7, wherein
The pushing body,
A pushing unit connected to the movable contact;
An extension part extending from the pushing part toward the latching body and having a hollow formed therein;
A bypass switch protruding from the extension part toward the latching body and having a second fastening part engaged with the latching body. The method of claim 8,
A bypass switch having a female screw portion formed at an inner circumference of one of the first fastening portion and the second fastening portion, and a male screw portion fastened to the female screw portion at another outer circumference. The method of claim 3, wherein
The moving pusher is,
An inner body connecting the pushing body and the driving source and at least a portion of which is located inside the latching body; And
And an inner spring elastically supporting the inner body in a direction in which the movable contact and the fixed contact are in contact with each other. The method of claim 1,
The latch elastic member,
When the fixed contact and the movable contact is in the open state spaced in the engaging groove,
And a bypass switch deviating from the locking groove when the movable shaft moves in a direction in contact with the fixed shaft. The method of claim 1,
The locking groove,
A first surface formed obliquely with an outer circumference of the moving pusher;
A second surface spaced apart from the first surface and formed obliquely in a direction opposite to the first surface at an outer circumference of the moving pusher; And
And a third surface parallel to a longitudinal direction of the moving pusher and connecting the first surface and the second surface. The method of claim 1,
The locking groove,
A first surface formed obliquely with an outer circumference of the moving pusher;
And a second surface connected to the first surface and including a second surface obliquely opposite to the first surface at an outer circumference of the moving pusher. The method of claim 1,
The locking groove is rounded bypass switch formed.

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