KR102190065B1 - Bypass Switch - Google Patents

Abstract

The present invention relates to a bypass switch, and more particularly, to a bypass switch used in a submodule of ultra-high voltage direct current transmission.
The bypass switch according to an embodiment of the present invention includes a case in which a hollow part is formed; A first bus bar coupled to the front end of the case; A second bus bar coupled to the rear end of the case; A fixed contact installed in the hollow part and connected to the first bus bar; A movable contact installed in the hollow part and connected to the second bus bar to contact or separate the fixed contact; An insulating cover coupled to a rear surface of the second bus bar and having a receiving portion therein; And a movable part extension rod installed in the receiving part and coupled to the movable contact. And an actuator installed at a rear portion of the insulating cover and providing power to move the movable portion extension rod.

Description

Bypass Switch

The present invention relates to a bypass switch, and more particularly, to a bypass switch used in a submodule of ultra-high voltage direct current transmission.

In general, High Voltage Direct Current (HVDC) is a transmission facility that converts AC power produced in a power plant into DC power at a power transmission station and transmits it, then reconverts it to AC at the receiving station to supply power. Applying the DC transmission method has the advantage of significantly reducing transmission loss compared to AC transmission.

In a high-voltage DC transmission system, a converter is required to convert electricity from AC to DC or DC to AC, and these converters are composed of a plurality of sub-modules.

On the other hand, when a failure occurs in some of the plurality of sub-modules, a configuration or apparatus is required to exclude the failed sub-module from the power transmission system for normal transmission.

One of the devices used for this purpose is the bypass switch. The bypass switch is provided in a converter used for high voltage direct current (HVDC), a static synchronous compensator (STATCOM/Static Synchronous Compensator) or a reactive power compensator (Static Var Compensator (SVC)). As a result, it is used as a high-speed short-circuit bypass switch to short-circuit at high speed when some parts fail.

That is, the bypass switch is provided in a converter made of a combination of a plurality of sub-modules, and when an abnormality such as a failure of a sub-module is detected, the sub-module in which the failure has occurred is short-circuited to prevent the influence of the failure from spreading to other adjacent sub-modules It is a device to prevent. (For an overview of the operation of sub-modules and bypass switches in ultra-high voltage DC transmission, refer to Korean Patent Registration No. 10-1613812 "Bypass switch for ultra-high voltage DC transmission" filed by the present applicant.)

1 and 2 show the configuration and operation of a bypass switch according to the prior art. Figure 1 shows an open state (open state), Figure 2 shows a closed state (closed state). (FIGS. 1 and 2 show Korean Application No. 10-2016-0018051 "Bypass Switch" filed by the present applicant.)

The bypass switch is a case (1) provided between the first bus bar (6) and the second bus bar (7) spaced apart from each other, and the first bus bar (6) and the second bus bar (7). Is composed. In the case 1, a fixed contact 22 connected to the first bus bar 6 and a movable contact connected to the second bus bar 7 to contact or separate from the fixed contact 22 ( moving contact) (21) is installed. Here, the fixed contact 22 and the movable contact 21 are constituent parts of the vacuum interrupter 2.

An actuator (inflator) 52 is provided as a driving source acting on the movable contact 21. The actuator 52 provides power to move the movable contact 21 while exploding by an electric signal. The actuator 52 is connected to the movable contact 21 via a pin 33, a latch plate 32, and a movable part extension rod 31.

As described above, when an abnormality such as an internal failure of a sub-module is detected in a high-voltage direct current transmission system composed of a series combination of a plurality of sub-modules, the high-speed bypass switch quickly separates the failed sub-modules for continuous normal operation of the system. Its purpose is to maintain and protect the system by preventing the propagation of faults to other sub-modules. Such a high-speed bypass switch maintains an open state in a normal state, and is quickly closed (closed) in case of a sub-module accident to provide a bypass circuit for the sub-module.

In the high-speed bypass switch, the maintenance of the open state is achieved by the magnetic force of the permanent magnet 4. The latch plate 32 is attracted to the permanent magnet 4 by the magnetic force of the permanent magnet 4 installed adjacent to the actuator 52, so that the movable contact 21 maintains an open state separated from the fixed contact 22 Is done. Since the latch plate 32 is coupled to the movable contact 21 via the movable part extension rod 31, when the latch plate 32 is attracted to the permanent magnet 4, the movable contact 21 also moves and the fixed contact 22 ) From

In the event of a failure of the sub-module, the actuator 52 receives an external firing signal (electrical signal) and operates the micro gas generator to release a high-pressure gas, and the high-pressure gas drives the piston 51 mounted inside the actuator. By pushing, the latch plate 32 is separated from the magnet holder 41 to which the permanent magnet 4 is fixed. At this time, the movable extension rod 31 connected to the latch plate 32 and the movable contact 21 of the vacuum interrupter 2 move together, and finally, the movable contact 21 and the fixed contact 22 of the vacuum interrupter 2 ) Contacts to conduct current. Fig. 2 shows a path for conducting current i.

Here, the spring 48 serves to push the movable contact 21 with a constant force while the contact portions 21 and 22 are closed. It serves to provide a contact pressure so that the contact portions 21 and 22 of the vacuum interrupter 2 are not separated due to contact repulsion force generated by the energized current and external vibration.

By the way, in a high-speed bypass switch according to the prior art, an actuator 52, which is a power source for the closing operation, is mounted adjacent to the second bus bar 7 through which a high-voltage current flows. For this reason, an insulation design is additionally required for the part where the actuator 52 is installed and an external device that transmits a firing signal, and noise due to a high voltage firing signal may increase.

Further, a spring 48 for providing a contact pressure to the latch plate 32 is inserted between the latch plate 32 and the magnet holder 41. Therefore, it is difficult to exert sufficient contact pressure due to the limitation of the space in which the spring 48 is installed. Therefore, a spring with a large spring constant must be used to exert the necessary contact pressure. A spring having a large spring constant (k) is difficult to manufacture and incurs a lot of cost. In addition, when a spring having a large spring constant is used, a large change in the contact pressing force (F=k×Δx) occurs even with a small deformation amount (Δx), so that it is not easy to control the stroke of the movable contact point 21 of the bypass switch.

The present invention has been conceived to solve the above-described problem, and an object thereof is to provide a bypass switch with improved insulation performance between an actuator and a bus bar.

Another object is to provide a spring operating space inside the movable extension rod, to facilitate the design or application of the spring.

The bypass switch according to an embodiment of the present invention includes a case in which a hollow part is formed; A first bus bar coupled to the front end of the case; A second bus bar coupled to the rear end of the case; A fixed contact installed in the hollow part and connected to the first bus bar; A movable contact installed in the hollow part and connected to the second bus bar to contact or separate from the fixed contact; An insulating cover coupled to a rear surface of the second bus bar and having a receiving portion therein; And a movable part extension rod installed in the receiving part and coupled to the movable contact. And an actuator installed at a rear portion of the insulating cover and providing power to move the movable portion extension rod.

Here, the second busbar further includes a multi-contactor socket provided with a contactor connecting portion formed through a through hole, inserted into the contactor connecting portion, formed as a tube, and installed to surround and support the movable portion extension rod.

Further, it further includes a multi-contactor disposed in close contact between the multi-contactor socket and the movable portion extension rod.

Further, an end cover coupled to a rear portion of the insulating cover and having a groove-shaped mounting portion in which the actuator is installed is formed.

In addition, a fixing part having a stepped diameter so as to be expanded is provided at the front end of the insulation cover, and by a fastening member fastened to the fixing part, the insulation cover is integrally coupled to the second bus bar and the case.

Further, it further includes a contact spring provided between the movable portion extension rod and the end cover to provide a contact pressure to the movable contact.

In addition, the end cover is inserted into the cover through hole of the insulating cover to form a central tube portion for supporting the contact spring.

In addition, the movable portion extension rod has a groove-shaped operating portion that is opened to the rear, and is provided on the front surface of the operating portion to receive the force of the contact pressure spring; further includes.

In addition, a permanent magnet coupled to the rear surface of the receiving portion; And a latch plate coupled to the movable part extension rod and sucked by the magnet in a normal state to separate the movable contact from the fixed contact.

In addition, it further includes an outer holder and an inner holder for supporting the permanent magnet on both sides of the permanent magnet.

In addition, the outer holder and the inner holder, the insulating cover and the end cover are integrally coupled by a fastening member.

And, the mounting portion is provided with a cap for fixing the actuator.

According to the bypass switch according to an embodiment of the present invention, an insulating cover is applied between the actuator serving as a power source for the closing operation of the movable contact and the second bus bar through which high-voltage current flows, thereby ensuring insulation. That is, the first busbar connected to the power source and the conductive part and the actuator part connected to the second busbar connected to the load are divided by an insulating cover to provide insulation.

This eliminates the need for insulation design for external firing devices connected to the actuator, and the actuator receives a firing signal (electrical signal) based on the ground, reducing the probability of noise occurrence in the firing signal, making the bypass switch accurate and stable operation. Will do.

On the other hand, the movable portion extension rod is formed in a cylindrical shape to provide a space for mounting and operating the contact spring. Therefore, a special spring having a large spring coefficient is not required, and a commercial spring can be applied.

Accordingly, the contact pressure to the movable contact is improved, and the weight of the entire component is reduced.

In addition, by increasing the speed of the bypass switch, the closing time is reduced.

In addition, stroke control for the movable contact is easy.

On the other hand, the latch plate is installed so that a part of the movable part extension rod is inserted so as to be stably operated without shaking.

1 and 2 are operational state diagrams of a bypass switch for a high-voltage power transmission module according to the prior art. 1 shows an open state, and FIG. 2 shows a closed state.
3 is a perspective view of a bypass switch for a high-voltage power transmission module according to an embodiment of the present invention.
4 is an exploded perspective view of FIG. 3.
5 is a perspective view of an insulating cover and an end cover in FIG. 4.
6 and 7 are operational state diagrams of a bypass switch for a high-voltage power transmission module according to an embodiment of the present invention. 6 shows an open state, and FIG. 7 shows a closed state.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, but this is for explaining in detail enough that a person of ordinary skill in the art can easily carry out the invention. It does not mean that the technical spirit and scope of the invention are limited.

3 is a perspective view of a bypass switch for a high-voltage power transmission module according to an embodiment of the present invention, and FIG. 4 is an exploded perspective view of FIG. 3. The bypass switch according to each embodiment of the present invention will be described in detail with reference to the drawings.

In the description of the present invention, the direction in which the first bus bar 110 is disposed is the front (front) based on the length direction of the case 120, and the direction in which the second bus bar 140 is disposed is the rear (rear). I will do it.

The bypass switch according to an embodiment of the present invention includes a case 120 having a hollow portion 128 formed therein; A first bus bar 110 coupled to a front end of the case 120 and connected to a power source; A second bus bar 140 coupled to the rear end of the case 120 and connected to a load; It is installed in the hollow part 128, the fixed contact 132 connected to the first bus bar 110 and the fixed contact 132 connected to or separated from the fixed contact 132 while being connected to the second bus bar 140 A vacuum interrupter 130 including a movable contact 134; An insulating cover 200 coupled to the rear surface of the second bus bar 140 and having a receiving portion 201 therein; And a movable part extension rod 160 installed in the receiving part 201 of the insulating cover 200 and coupled to the movable contact 134. And an actuator 220 installed at a rear portion of the insulating cover 200 and providing power to move the movable portion extension rod 160.

The case 120 forms the exterior of the bypass switch 100. The case 120 may be formed of a cylindrical member. The case 120 may be made of an insulating material.

The case 120 is formed with a hollow portion 128 in which other parts can be accommodated. A vacuum interrupter 130 and a movable part extension rod 160 may be installed in the hollow part 128.

A plurality of ventilation holes 121 may be formed along the outer circumferential surface of the case 120.

The case 120 may be provided with a plurality of fixing parts 123 and 124 along the inner circumferential surface. The fixing parts 123 and 124 are provided at both ends, respectively. Screw holes 125 may be formed in the fixing parts 123 and 124, respectively.

The first bus bar 110 is provided. The first bus bar 110 may be formed as a flat plate. The first bus bar 110 is coupled to the front end of the case 120.

A plurality of first coupling holes 111 are formed in the first bus bar 110 at a position corresponding to the fixing part 123 of the case 120.

A fixed contact hole 112 for fastening the fixed contact 132 to the first bus bar 110 is formed in the center of the first coupling hole 111.

A first mounting hole 113 is formed in the first bus bar 110 to be fixedly connected to other components.

The first bus bar 110 is connected to a power source and becomes a conduction path through which current flows.

The first bus bar 110 is coupled to the case 120 by the first fastening member 115. The first fastening member 115 is fastened to the first coupling hole 111 of the first bus bar 110 and the fixing part 123 of the case 120.

A second bus bar 140 is provided. The second bus bar 140 may be formed as a flat plate. The second bus bar 140 is coupled to the rear end of the case 120.

A plurality of second coupling holes 141 are formed in the second bus bar 140 at a position corresponding to the fixing part 123 of the case 120.

A second mounting hole 143 is formed in the second bus bar 140 to be fixedly connected to other components.

The second bus bar 140 is connected to a load and becomes a current through which current flows.

The second bus bar 140 is provided with a contactor connecting portion 145 formed through a through hole. A multi-contactor 155 and a multi-contactor socket 150 are inserted into the contactor connection part 145.

The vacuum interrupter 130 includes a fixed contact 132 disposed at one end and a movable contact 134 disposed at the other end to contact or separate from the fixed contact 132.

The vacuum interrupter 130 may be installed inside the case 120. The vacuum interrupter 130 is disposed in the hollow portion 128 of the case 120 and is protected and supported by the case 120. The vacuum interrupter 130 is installed so that the outer circumferential surface thereof has a predetermined distance from the case 120 except for both ends on which the fixed contact 132 and the movable contact 134 are installed. That is, the inner diameter of the case 120 is formed larger than the outer diameter of the vacuum interrupter (130). Accordingly, the vacuum interrupter 130 may be cooled by air entering through the ventilation hole 121 of the case 120.

The fixed contact 132 is fixed to the first bus bar 110 by the fixed contact fastening member 116.

The movable contact 134 is coupled to the movable portion extension rod 160. An insertion groove 135 is formed at the rear end of the movable contact 134.

A multi-contactor socket 150 is provided. The multi-contactor socket 150 is inserted and installed in the contactor connection part 145. The multi-contactor socket 150 may be formed in a circular tube shape. The rear end portion of the multi-contactor socket 150 has a large diameter step to form a support portion 151 that is installed in contact with the rear surface of the second bus bar 140. The multi-contactor socket 150 provides a space into which the movable part extension rod 160 is inserted, and supports the movable part extension rod 160 and the movable contact 134.

In the multi-contactor socket 150, a contactor insertion groove 152 into which the multi-contactor 155 can be partially inserted is formed on an inner circumferential surface of the multi-contactor socket 150. The contactor insertion groove 152 may be formed in a ring groove shape.

A multi-contactor 155 is provided. A plurality of multi-contactors 155 may be provided. The multi-contactor 155 is inserted and installed in the multi-contactor socket 150. The multi-contactor 155 is inserted and installed into the contactor insertion groove 152 of the multi-contactor socket 150. The multi-contactor 155 is provided to improve conduction performance between the multi-contactor socket 150 and the movable part extension rod 160. In addition, the multi-contactor 155 closely supports the movable extension rod 160. The multi-contactor 155 may be formed of an elastic conductor in order to stably maintain electrical coupling with the multi-contactor socket 150 even if the movable extension rod 160 moves. Each of the multi-contactors 155 may be arranged as a plurality of leaf spring groups to form an annular shape (though not shown in detail).

The movable extension rod 160 is installed to pass through the multi-contactor socket 150 and is coupled to the movable contact 134. The movable part extension rod 160 pushes the movable contact 134 to contact the fixed contact 132.

An extension rod protrusion 161 is protruded at a front end of the movable extension rod 160 and is inserted into the insertion groove 135 formed in the movable contact 134. Accordingly, the movable portion extension rod 160 and the movable contact 134 move integrally.

The movable part extension rod 160 is formed with a groove that is opened to the rear and an operation part 162 in which a component can be accommodated is formed. That is, the movable portion extension rod 160 is formed in a cylindrical shape. A push rod 170, a contact spring 175, and a latch plate 180 are inserted into the operation unit 162. The operation unit 162 provides a space in which the contact pressure spring 175 and the like can operate.

A push rod fixing groove 163 is formed at the front end of the operation unit 162 so that the coupling protrusion 171 of the push rod 170 is inserted and coupled.

At the rear end of the operation part 162, a latch coupling part 164 having a wide inner diameter stepped is formed. The latch plate 180 is coupled to the latch coupling part 164.

A push rod 170 is provided. The push rod 170 moves according to the power generated by the actuator 220 to move the movable contact 134 through the movable part extension rod 160.

The push rod 170 has a pressing plate 172 for transmitting a force by contacting the front surface of the operation part 162 at the front end and a coupling protrusion 171 inserted into the push rod fixing groove 163 and protruding.

A coupling groove 173 into which the insulating push rod 185 is inserted is formed at the rear end of the push rod 170.

The push rod 170 is installed spaced apart from the magnetic latch 190. That is, the rear end of the push rod 170 is disposed in front of the front end of the magnetic latch 190. Accordingly, interference caused by the attraction of the push rod 170 and the magnetic latch 190 can be avoided.

A contact pressure spring 175 is provided. The contact spring 175 is provided to apply pressure to the push rod 170. The pressure applied by the contact spring 175 to the push rod 170 acts as a contact pressure for pressing the movable contact 134 via the movable extension rod 160. The contact portions 132 and 134 are not separated by the external force generated by the contact portions 132 and 134 in the closed state by this contact pressure.

The contact spring 175 has a front end in contact with the pressing plate 172 of the push rod 170 and a rear end in contact with the central pipe part 211 of the end cover 210. Since the end cover 210 is fixedly installed on the insulating cover 200, the contact pressure spring 175 acts in a direction in which the push rod 170 is pressed.

A latch plate 180 is provided. The latch plate 180 is fixed to the movable part extension rod 160 and sucked by the permanent magnet 195 to maintain the movable contact 134 in an open state separated from the fixed contact 132. It is preferable that the latch plate 180 is formed of a magnetic material.

A first through hole 181 is formed in the central portion of the latch plate 180.

A rod coupling portion 184 in a tubular shape is formed around the first through hole 181 in the latch plate 180. The rod coupling portion 184 is formed to protrude to one surface (to the front) of the latch plate 180.

The rod coupling portion 184 of the latch plate 180 is inserted and coupled to the latch coupling portion 164 of the movable extension rod 160.

A portion of the rear end of the push rod 170 and a portion of the rear end of the contact spring 175 are inserted into the rod coupling portion 184 of the latch plate 180, that is, the first through hole 181.

An insulating push rod 185 is provided. The insulating push rod 185 is coupled to the coupling groove 173 of the push rod 170 to move the push rod 170 by the explosive force of the actuator 220. The insulating push rod 185 is formed of an insulating material to improve insulating performance between the push rod 170 and the magnetic latch 190.

A magnetic latch 190 is provided. The magnetic latch is composed of an outer holder 191, an inner holder 197 and a permanent magnet 195. The magnetic latch serves to suck the latch plate 180. It is preferable that the outer holder 191 and the inner holder 197 are formed of a magnetic material.

The outer holder 191 and the inner holder 197 are coupled to the rear surface of the receiving portion 201 of the insulating cover 200.

The outer holder 191 may be formed in a circular shape, and a square second through hole 192 may be formed in the center portion.

The inner holder 197 may be formed in a square shape, and a circular third through hole 198 may be formed in the center.

The permanent magnet 195 is fixed between the outer holder 191 and the inner holder 197. The permanent magnet 195 may be composed of a flat magnet. A plurality of permanent magnets 195 may be provided, for example, four. One surface of the permanent magnet 195 is installed in contact with one surface of the second through hole 192 of the outer holder 191, and the other surface of the permanent magnet 195 is installed in contact with the outer surface of the inner holder 197, the outer holder 191 ) And the inner holder 197.

The permanent magnet 195 sucks the latch plate 180 in a normal state so that the movable contact 134 is kept in an open state separated from the fixed contact 132.

5 shows a perspective view of the insulating cover and the end cover in different directions. For further reference.

The insulating cover 200 is provided to improve the insulation between the actuator 220 and the conducting portion including the bus bars 110 and 140. The insulating cover 200 is particularly provided for electrical insulation between the actuator 220 and the second bus bar 140. Accordingly, an insulation design for an external firing device is unnecessary, and a firing signal based on the ground is received, thereby reducing the probability of noise generation in the firing signal, thereby enabling an accurate and stable operation of the bypass switch.

The insulating cover 200 is disposed behind the second bus bar 140. Accordingly, the electric current flowing from the power source through the first bus bar 110 to the load through the second bus bar 140 is configured separately from the actuator 220 so that insulation between the electric current part and the actuator unit is sufficiently Is secured.

The insulating cover 200 may be formed in a cylindrical shape with an open front surface. The receiving portion 201 of the insulating cover 200 includes a movable portion other than the movable contact 134, that is, the movable portion extension rod 160, the push rod 170, the contact spring 175, the latch plate 180, and the insulating push rod. (185) is accepted.

The front end 202 of the insulating cover 200 may be stepped so that the diameter is expanded. This is to facilitate assembly of the insulating cover 200 to the second bus bar 140.

A fixing part 203 that can be fixed to the second bus bar 140 is formed at the front end 202 of the insulating cover 200. The insulating cover 200 is fixedly coupled to the second bus bar 140 by the second fastening member 148 fastened to the fixing part 203.

The end cover 210 and the outer holder 191 are fixed to the rear surface 205 of the insulating cover 200. A cover through hole 206 is formed in the center portion of the rear surface 205 of the insulating cover 200. A fixing hole 207 for fixing the end cover 210 and the holders 191 and 197 is formed in the rear surface 205 of the insulating cover 200. The end cover 210 and the holders 191 and 197 are fixedly coupled to the rear surface 205 of the insulating cover 200 by a third fastening member 218.

The end cover 210 is coupled behind the insulating cover 200. The end cover 210 is formed of an insulating material. The end cover 210 serves to insulate between the contact spring 175 and the actuator 220.

The end cover 210 has a central pipe portion 211 protruding. The central pipe part 211 is inserted into the cover through hole 206 of the insulating cover 200 to support the contact spring 175. Here, the front end portion of the central pipe portion 211 protrudes forward from the front end portion of the magnetic latch 190. Accordingly, interference caused by magnetic force between the push rod 170 and the contact spring 175 and the magnetic latch 190 can be avoided.

A groove-shaped mounting portion 215 is formed on the rear surface of the end cover 210. The actuator 220 is installed on the mounting portion 215 from the rear surface of the end cover 210 and partially inserted into the central pipe portion 211.

The actuator 220 is an explosive power source. When an accident current occurs, the actuator 220 explodes by an external firing signal and pushes the insulating push rod 185 to generate power to move the movable contact 134. The actuator 220 is also called an inflator because it generates power by gas pressure.

The actuator 220 is provided with a piston 221 to move forward by gas pressure during an explosion to push the insulating push rod 185.

The cap 230 is coupled to the rear portion of the actuator 220. The cap 230 is inserted and coupled to the actuator mounting portion 215 to support the actuator 52.

The operation of the bypass switch according to an embodiment of the present invention will be described. Mainly, reference will be made to FIGS. 6 and 7. 6 shows an open state, and FIG. 7 shows a closed state.

In a normal state in which each sub-module operates normally, the latch plate 180 is sucked by the magnetic force of the magnetic latch 190 and is placed in contact with the holders 191 and 197. Accordingly, the movable part extension rod 160 connected to the latch plate 180 and the movable contact 134 connected to the movable part extension rod 160 also move to the rear, so that the contact parts 132 and 134 remain open.

Therefore, no current flows through the bypass switch.

When a failure occurs in a sub-module, when such a failure is detected and an electric signal is input from the outside, a gas generator is operated to the actuator 52 to generate gas pressure. The piston 221 pushes the insulating push rod 185 while moving forward by the gas pressure. The push rod 170, the movable part extension rod 160, and the movable contact 134 are interlocked therewith to overcome the attractive force between the latch plate 180 and the permanent magnet 195 and move forward. Accordingly, the movable contact 134 contacts the fixed contact 132 to generate electricity.

That is, a current flows through the bypass switch, creating a current bypass circuit that excludes the sub-module.

On the other hand, the contact pressure spring 175 extends within the operation part 162 of the movable part extension rod 160 to provide a contact pressure to the contact parts 132 and 134.

According to the bypass switch according to an embodiment of the present invention, an insulating cover is applied between the actuator serving as a power source for the closing operation of the movable contact and the second bus bar through which high-voltage current flows, thereby ensuring insulation. That is, the first busbar connected to the power source and the conductive part and the actuator part connected to the second busbar connected to the load are divided by an insulating cover to provide insulation.

This eliminates the need for insulation design for external firing devices connected to the actuator, and the actuator receives a firing signal (electrical signal) based on the ground, reducing the probability of noise occurrence in the firing signal, making the bypass switch accurate and stable operation. Will do.

On the other hand, the movable portion extension rod is formed in a cylindrical shape to provide a space for mounting and operating the contact pressure spring. Therefore, a special spring having a large spring coefficient is not required, and a commercial spring can be applied.

Accordingly, the contact pressure to the movable contact is improved, and the weight of the entire component is reduced.

In addition, by increasing the speed of the bypass switch, the closing time is reduced.

In addition, stroke control for the movable contact is easy.

On the other hand, the latch plate is installed so that a part of the movable part extension rod is inserted so as to be stably operated without shaking.

The embodiments described above are embodiments for implementing the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments. That is, the scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

110 1st bus bar 111 1st coupling hole
112 Fixed contact hole 113 First mounting hole
115 First fastening member 116 Fixed contact fastening member
120 case 121 ventilation hole
123,124 fixing part 125 screw hole
128 Hollow part 130 Vacuum interrupter
132 Fixed contact 134 Moving contact
135 Insertion groove 140 Second busbar
141 Second coupling hole 143 Second mounting hole
145 Contactor connection part 148 Second fastening member
150 Multi-contactor socket 151 Support
152 Contactor insertion groove 155 Multi-contactor
160 Movable part Extension rod 161 Extension rod protrusion
162 Operating part 163 Push rod fixing groove
164 Latch engagement 170 Push rod
171 Engaging protrusion 172 Pressure plate
173 Mating groove 175 Contact spring
180 Latch plate 181 First through hole
184 Rod joint 185 Insulated push rod
190 Magnetic Latch 191 Outer Holder
192 Second through hole 195 Permanent magnet
197 Inner holder 198 3rd through hole
200 Insulation cover 201 Receptacle
202 Front end 203 Fixed part
205 rear 206 cover through hole
207 Fixed hole 210 End cover
211 Central pipe part 215 Mounting part
218 third fastening member 220 actuator
221 piston 230 cap

Claims (12)

Including an electric current part and an actuator part,
The energizing part,
A case in which a hollow part is formed therein;
A first bus bar coupled to the front end of the case;
A second bus bar coupled to the rear end of the case;
A fixed contact installed in the hollow part and connected to the first bus bar;
Includes; a movable contact installed in the hollow part and connected to the second bus bar to contact or separate from the fixed contact,
The actuator unit,
An insulating cover coupled to a rear surface of the second bus bar and having a receiving portion therein;
A movable part extension rod installed in the receiving part and coupled to the movable contact;
An end cover fixedly coupled to a rear surface of the insulating cover and formed of an insulating material; And
Including; an actuator installed through the end cover and providing power to move the movable part extension rod,
The insulating cover,
The front end is stepped so that the diameter is expanded,
A bypass switch having a fixing part coupled to the second bus bar and the case by a fastening member at the front end. The method of claim 1, wherein the second bus bar is provided with a contactor connection portion formed as a through hole,
The bypass switch further comprises a multi-contactor socket inserted into the contactor connection part, formed as a tube, and installed to surround and support the movable part extension rod. The bypass switch of claim 2, further comprising a multi-contactor disposed in close contact between the multi-contactor socket and the movable part extension rod. The bypass switch according to claim 1, wherein a groove-shaped mounting portion in which the actuator is installed is formed on the end cover. delete The bypass switch according to claim 4, further comprising a contact pressure spring provided between the movable part extension rod and the end cover to provide contact pressure to the movable contact. The bypass switch of claim 6, wherein the end cover has a central tube portion inserted into the cover through hole of the insulating cover to support the contact pressure spring. The bypass switch according to claim 7, wherein the movable portion extension rod further comprises a push rod having a groove-shaped operating portion that is opened to the rear and provided on the front surface of the operating portion to receive the force of the contact pressure spring. According to claim 1, A permanent magnet coupled to the rear surface of the receiving portion; And a latch plate coupled to the movable part extension rod and sucked by the permanent magnet in a normal state to separate the movable contact from the fixed contact. The bypass switch of claim 9, further comprising an outer holder and an inner holder supporting the permanent magnet on both sides of the permanent magnet. The bypass switch according to claim 10, wherein the outer holder, the inner holder, the insulating cover, and the end cover are integrally coupled by a fastening member. The bypass switch according to claim 4, wherein a cap for fixing the actuator is provided on the mounting portion.

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