KR102177358B1 - A high voltage switch with the double insulating structure - Google Patents

Abstract

The present invention relates to a high-voltage switch having a double insulating structure including an auxiliary insulating section in a vacuum switch unit to which a vacuum interrupter (VI) is applied, capable of preventing a negligent accident such as an electric shock. The present invention provides the high-voltage switch having the double insulating structure including the auxiliary insulating section in the vacuum switch unit to which the vacuum interrupter (VI) is applied, in which the high-pressure switch includes a contact unit configured to perform opening (OFF) and closing (ON) of the switch through a contact between a movable electrode and a fixed electrode, a pressure rod configured to move the movable electrode toward the fixed electrode, and a power generation unit configured to generate a power for rectilinearly moving the pressure rod, wherein the contact unit includes a vacuum switch unit; a chamber; and a detachment/attachment device.

Description

A high voltage switch with the double insulating structure with an auxiliary insulating section on the vacuum switch to which VI (Vacuum Interrupter) is applied

The present invention relates to a double-insulated high-voltage switchgear having an auxiliary insulating section on a vacuum switch to which a VI (Vacuum Interrupter) is applied, and more particularly, to prevent a safety accident due to induced voltage between the VI poles. It relates to a double-insulated high-voltage switchgear having an auxiliary insulation section on the vacuum switch to which the VI (Vacuum Interrupter) is applied so that it can be double-insulated by placing a vacuum insulation section between VI poles and an air insulation section in the middle current section.

In general, overhead transmission and distribution facilities have been widely used in which electric poles are erected at regular intervals on the side of a road to supply electric power to electric power consumers in urban areas, and for this reason, a transmission and distribution line is constructed using an insulator and an insulator. However, such an overhead transmission and distribution facility has problems such as a risk of a short circuit or short circuit accident because the overhead transmission and distribution lines are complicatedly entangled, there is a problem that is vulnerable to typhoons or rainfall, and the aesthetics of the downtown area is damaged. Accordingly, in recent years, the underground business of transmission and distribution lines that install transmission and distribution facilities in the underground has been actively progressing. Let's look at the transmission process using underground lines. It is boosted to ultra-high voltage (345kV, 154kV) to be suitable for power transmission in the power plant and transmitted to the primary substation. The primary substation reduces the voltage to 22.9KV and supplies it to the secondary substation or each accommodation. The power supplied from the primary substation is supplied to the power receiving facilities of each receiving site through the distribution system composed of overhead distribution lines, and is supplied to the extra-high voltage receiving site, the high-voltage receiving site, and the low-voltage receiving station supplied through various outdoor transformers.

At this time, in accordance with the increase in electricity consumption and the double track of electricity usage, switchgear for underground/processed distribution lines is installed and used at each location. Switchgear is installed on a line that transmits power from the supply side to the load side by connecting the supply side that supplies power such as a substation and the load side that consumes power such as factories and houses, and opens and closes the line with input (ON) and open (OFF). It is a device that supplies or cuts off power. Switchgear secures the stability of maintenance work by manually opening the line when maintenance of various electric devices connected to the load side is required, and after the instability of the power state is resolved and maintenance is completed, it is automatically or manually inputted to the supply side. Connect the line to the load side.

As shown in FIG. 1, the switch is electrically connected to a case 10 for receiving an insulating gas, a power input terminal 20 for inputting current, a power output terminal 80 for outputting power, and the power input terminal 20. And a movable electrode 31 extending in one direction, and at least a part of a fixed electrode 32 extending along an extension line of the movable electrode 31 and facing each other with the movable electrode 31, and the The length of the movable electrode 31 to contact or block the vacuum opening/closing part 30 arranged to be spaced apart from a plurality of the movable electrode 31 and the end of the fixed electrode 32 in a direction perpendicular to one direction A pressure rod 40 movable along a direction, a moving piece 50 coupled with the pressure rod 40, and an input cam portion 60 for reciprocating the moving piece 50, and the input cam portion 60 It is connected to and includes a manipulation unit 70 for reciprocating the moving piece 50 and the pressure rod 40 through the input cam unit 60.

In the vacuum opening and closing part 30 of the switch, the fixed electrode 32 and the movable electrode 31 are disposed opposite to each other in the vacuum container, and the pressure rod 40 is connected to the bus-side conductor and the fixed electrode is connected to the load-side conductor. The vacuum switch 30 must pressurize the movable electrode 31 with a constant force in consideration of the electron repulsion force due to the characteristics of the short-circuit current upon input. Therefore, it is necessary to consider the concentration of the mechanical load on the pressure rod 40 connecting the vacuum opening/closing unit 30 and the operation unit to be blocked. In addition, since the pressure rod 40 connects the electric conduction unit and the operation unit, insulation characteristics must be considered.

In the open/closer having this configuration, the operation unit 70 is connected to the input cam unit 60 to rapidly rotate the input cam unit 60 in the direction of the surface of the case 10, so that the inclined surface 51 and the cam unit inclined surface 61 ) Through the contact between the moving piece 50 and the pressure rod 40 reciprocate, the movable electrode 31 may be connected to the fixed electrode 32 or blocked.

The above-described conventional switch having a vacuum switch has the following problems.

First, since the contact distance between the movable electrode 31 and the fixed electrode 32 of a conventional switch having a vacuum switch is insulated by vacuum, the insulation distance is short. In other words, since the contact distance is short, there is a problem in that an induced voltage is caused even when the line is opened (OFF), which may cause a safety accident such as an electric shock to the worker.

Second, when the movable electrode 31 and the fixed electrode 32 contact each other, fusion occurs between the electrodes, and when the line is opened (OFF), only the pressure rod 40 may be separated from the movable electrode 32. In this case, there is a problem that may cause an explosion.

Republic of Korea registration number 10-1051230

The present invention was conceived to solve the above problems, and an object of the present invention is to secure a sufficient insulation distance by additionally installing an air interruption study between the movable electrode of the vacuum switch and the applied current Safety accidents for workers are prevented, and an explosion accident due to incomplete operation is prevented and the track is opened by providing a detachment means between the pressure rod and the movable electrode so that the pressure rod can be detached only when the movable electrode is completely separated from the fixed electrode. And by making the action of the pressure rod for input proceed in two steps, it is a double insulation structure with an auxiliary insulation section applied to the vacuum switch to which the VI (Vacuum Interrupter) minimizes deformation by reducing the amount of impact of the movable electrode during input. It was intended to provide a switchgear.

In order to achieve the above object, the present invention is provided to move the movable electrode toward the fixed electrode and a contact part in which the switch is opened (OFF) and closed (ON) through the contact between the movable electrode and the fixed electrode. A high-pressure switch comprising: a pressurizing rod and a power generating unit generating power to move the pressurizing rod in a straight line, wherein the contact unit comprises: a vacuum opening and closing unit providing a space in a vacuum state in which a contact between the fixed electrode and the movable electrode is formed; A chamber which encloses and protects the vacuum opening/closing part, and providing a straight path toward the vacuum opening/closing part above the vacuum opening/closing part, but having a stepped portion formed on the inner circumferential surface of the straight path due to an inner diameter difference between the lower part and the upper part of the straight path; And the pressure rod is provided to be detachable, and is provided so as to interlock the movement of the movable electrode while moving straight on the straight path of the chamber by the straight movement of the pressure rod, and the pressure rod and the pressure rod according to the position on the straight path Including: a first step in which the pressure rod is coupled to the desorption means, and the pressure rod coupled to the desorption means moves to fix the movable electrode. It is configured to perform a two-step action of contacting the electrode, and the detachment means has a detachable hole corresponding to the diameter of the pressing rod so that the pressing rod can be detached, and the straight path and the detachable A circumferential hole is formed to allow the start of construction, and the restraining means includes a restraining pin inserted into the periphery and a spring that elastically supports the restraining pin on the peripheral hole.Vacuum Interrupter (VI) applied It provides a double-insulated high-voltage switchgear having an auxiliary insulated section on the switch.

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In addition, the power generation unit, a rotating plate shaft-coupled to one side of the switch; An interlocking linker coupled to the rotational radius of the rotational plate and installed to be pushed by a rotational distance according to the rotational radius when the rotational plate is rotated; A straight linker coupled to the interlocking linker and moving straight by a distance pushed by the interlocking linker; A direction changing linker connected between the straight linker and the pressure rod, and transmitting the straight linker to the pressure rod by vertically changing a straight direction of the straight linker; One end is connected to the end of the straight linker, the other end is connected to the shaft of the rotating plate, the rotating linker rotates about the axis of the rotating plate when the straight linker moves; And a tension spring installed between the rotational linker and the rotational plate and installed between the rotational linker and the rotational plate in a state of being stretched and contracted between the rotational linker and the rotational plate when the rotational plate is rotated.

At this time, when the tension spring tension distance between the rotating linker and the rotating plate is the maximum due to the rotation of the rotating plate, the straight linker moves to engage the pressure rod with the detachment means, and the rotating plate continues to rotate. When the straight linker moves again and the tensioned spring is restored by rotating the rotary linker, the pressure rod coupled to the detachment means proceeds again, and the second step of contacting the movable electrode with the fixed electrode is preferably performed. Do.

In addition, in the chamber, an applied conductive part that is energized with the contact of the vacuum switch is installed in a vertical direction of the chamber, and a ground linker is installed above the applied conductive part so as to be in contact with the applied conductive part while rotating toward the applied conductive part. It is desirable.

A high voltage switch having a double insulation structure having an auxiliary insulation section in a vacuum switch to which a VI (Vacuum Interrupter) according to the present invention is applied has the following effects.

First, since the switch of the present invention can sufficiently secure the insulation distance between the pressurizing rod and the fixed electrode, there is an effect of preventing safety accidents such as electric shock during work by eliminating the generation of induced voltage.

Second, in the switch of the present invention, a detachment means is installed between the pressurizing rod and the movable electrode, and the pressurizing rod can be completely opened (OFF) through the detachment means only when the movable electrode is separated from the fixed electrode. There is an effect that can prevent such problems. That is, when the movable electrode is inserted (ON) to the fixed electrode, the pressure rod is fixed to the detachment means through the restraining means. Since the pressure rod cannot be separated from the movable electrode in the line input state, only the pressure rod is separated. It is possible to prevent problems such as explosion caused by malfunction.

Third, in the switchgear of the present invention, since the line input and opening action can be performed in two stages, such as the connection of the detachment means of the pressure rod-the contact of the fixed electrode of the movable electrode through the detachment means, the pressure rod is first coupled to the detachment means at low speed The pressure rod and the movable electrode, which are combined after being achieved, are in close contact with the fixed electrode at high speed, thereby reducing the amount of impact caused by high-speed movement, thereby minimizing deformation of the electrode.

1 is a view showing a switch according to the prior art.
2 is a view showing a vacuum switch of the switch according to the prior art.
3 is a plan view showing an open/closer for an underground track capable of double opening and closing according to a preferred embodiment of the present invention.
4 is a front view showing an open/closer for an underground track capable of double opening and closing according to a preferred embodiment of the present invention, and is a view showing an open state.
5 is a front view showing an open/closer for an underground track capable of performing a double opening and closing operation according to a preferred embodiment of the present invention, and is a view showing a state in which input is made in the open.
6 is a front view showing an open/closer for an underground track capable of double opening and closing according to a preferred embodiment of the present invention, and is a view showing an input state.
7 is a front view showing an open/closer for an underground track capable of performing a double opening and closing operation according to a preferred embodiment of the present invention, and is a view showing a state in which opening is made in the input.
8 is a view showing a main part of an open/closer for an underground track capable of performing a double opening and closing action according to a preferred embodiment of the present invention, and is a view showing an open state.
9 is a view showing a main part of an open/closer for an underground line capable of performing a double opening and closing action according to a preferred embodiment of the present invention, and is a view showing a state in which input is made in an open state.
10 is a view showing a main part of an open/closer for an underground track capable of performing a double opening and closing action according to a preferred embodiment of the present invention, and is a view showing an input state.
11 is a view showing a main part of an open/closer for an underground line capable of performing a double opening and closing action according to a preferred embodiment of the present invention, and is a view showing a state in which the opening is made in the input.
12 is a view showing an open/closer for an underground line capable of performing a double opening/closing action according to a preferred embodiment of the present invention, and is a view showing a state in which a ground linker is in contact with an applied conductive part.

Terms and words used in the present specification and claims are not limited to the usual or dictionary meanings, and the inventor is based on the principle that the concept of terms can be appropriately defined in order to explain his or her invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention.

Hereinafter, with reference to the accompanying FIGS. 3 to 12, a double-insulated high-voltage switch (hereinafter referred to as a switch) having an auxiliary insulating section to a vacuum switch to which a vacuum interrupter (VI) according to a preferred embodiment of the present invention is applied. Let me explain.

Switchgear prevents operator safety accidents due to induced voltage by increasing the insulation distance, and increases the buffering efficiency between electrodes by securing the insulation distance by making the action for opening and closing the line take place in two stages. By making the input and opening action interlock with the detachment and detachment of the pressure rod, accidents such as explosions that may occur when only the pressure rod is removed from the electrode can be prevented.

As shown in Figs. 3 and 4, the switch includes a frame 100, a contact unit 200, a pressure rod 300, and a power generation unit 400.

The frame 100 constitutes the exterior of the switch and is provided so that each of the components constituting the switch may be installed.

The contact part 200 is configured to make a line input (ON) and open (OFF) by the operation of the pressure rod 300, and is installed under the frame 100. The contact part 200 includes a vacuum interrupter 210, a chamber 220, and a detachment means 230. The vacuum opening/closing unit 210 provides a space in which electrodes are formed in a vacuum state, and includes a movable electrode 211 and a fixed electrode 212 as shown in FIG. 8. The chamber 220 protects the vacuum opening and closing part 210 and a space for accommodating the vacuum opening and closing part 210 is provided inside the chamber 220. The chamber 220 is preferably formed in a cylindrical shape, and the height of the chamber 220 is formed larger than the height of the vacuum opening and closing part 210. Accordingly, the upper portion of the chamber 220 forms a straight path 221 toward the vacuum opening/closing unit 210 as shown in FIG. 8. The straight path 221 is formed through the inner diameter of the chamber 220, and is a passage through which the pressure rod 300 and the detachment means to be described later are elevated. Due to the formation of the straight path 221, a contact distance (insulation distance) between the electrodes 211 and 212 of the vacuum switch 210 can be sufficiently secured, so that an electric shock accident due to an induced voltage can be prevented. At this time, the lower inner diameter of the straight path 221 is formed smaller than the upper inner diameter of the straight path 221. Accordingly, a locking protrusion 221a formed due to an inner diameter difference is provided on the inner circumferential surface of the chamber 220 constituting the straight path 221. In the upper part of the chamber 220, an input part 222 is installed in which an input hole 222a for guiding the pressure rod 300 to the inside of the chamber 220, that is, a straight path 221 is formed, and the input part 222 is Provided as a conductor. The input part 222 is connected to an applied electric current part L connected to the load side. It is preferable that the chamber 220 is made of an insulating material.

Detachment means 230 of the contact unit 200 is configured to be detachable from the pressure rod 300, and can contact the movable electrode 211 with the fixed electrode 212 by pressing the pressure rod 300. It is an intermediary. At this time, the pressure of the pressure rod 300 means the lowering of the pressure rod 300 in the drawing. Desorption means 230 prevents only the pressure rod 300 from being removed from the contact part 200 by restraining the pressure rod 300 when the line is input (ON), and the pressure rod only when the line is opened (OFF) By separating the 300 naturally, a complete line opening (OFF) can be made, thereby preventing a safety accident. The detachment means 230 is coupled to the rod of the movable electrode 211 and includes a restraint means 231. The detachment means 230 is provided in a form that can be lifted along the straight path 221, and forms a detachable hole 232 for detachment with the pressure rod 300. Desorption hole 232 is formed from the top to the bottom of the detachment means (230). A circumferential hole 233 is formed around the detachable means 230, and the circumferential hole 233 is formed to communicate with the detachable hole 232. The circumferential hole 233 is a configuration for the installation of the restraining means 231 to be described later, and is preferably formed in plural on the circumferential surface of the detachable means 230. The restraint means 231 serves to restrain or release the pressure rod 300 inserted into the desorption hole 232 of the desorption means 230. The restraint means 231 is composed of a restraint pin 231a and a spring 231b. The restraint pin (231a) is a configuration to restrain the end of the pressure rod 300 inserted into the detachable hole 232 while entering the detachable hole 232 from the circumferential hole 233, is installed for each circumferential hole 233 . The length of the restraint pin 231a is formed larger than the length of the circumferential hole 233, but when the detachment means 230 is positioned above the straight path 221, the restraint pin 231a does not protrude into the detachment hole 232. It is provided in a length that is not enough. A detailed description of this will be described later when explaining the line input and opening action. The spring 231b serves to elastically support the restraining pin 231a in the circumferential hole. The spring 231b is preferably a coil spring, and is installed to provide an elastic force to push the restraining pin 231a from the circumferential hole 233 toward the straight path 221 outside the detachment means 230. Meanwhile, a buffer spring 240 is preferably interposed between the detachable means 230 and the vacuum opening/closing part 210. When the desorption means 230 descends according to the descending of the pressure rod 300, the buffer spring 240 serves to buffer the shock transmitted to the vacuum opening and closing part 210. That is, the buffer spring 240 is to be able to buffer the force transmitted to the upper surface of the vacuum opening and closing part 210 while contracting when the detachment means 230 descends. In addition, the buffer spring 240 serves to help the detachment means 230 ascending by providing a restoring force for the opening of the line (2300). The buffer spring 240 is preferably a conical coil spring.

The pressure rod 300 serves to open (OFF) or input (ON) the track while lifting the upper and lower parts of the frame by receiving power from the power generating unit 400. The pressure rod 300 is provided in the form of a bar and is formed to be coupled to the detachable hole 232 of the detachable means 230 through the input hole 222a of the input unit 222. The upper end of the pressure rod 300 is connected to the power generating unit 400 as shown in FIG. 4, and the lower end of the pressure rod 300 can be attached to and detached from the detachment means 230 through the input unit 222. Provided. It is preferable that the restraining jaw 310 is formed at the lower end of the pressure rod 300. The restraint jaw 310 is to increase the coupling force between the pressure rod 300 and the detachment means 230 by allowing the end of the restraining pin 231a to be seated. The restraint jaw 310 is formed to be stepped at the lower end of the pressure rod 300 so that the end of the restraint pin 231a can be seated. The restraining jaws 310 are extended to both sides of the pressure rod 300 and provide a surface on which the restraining pins 231a can be seated.

The power generation unit 400 generates power to lift the pressure rod 300 and is installed on one side of the frame 100. As shown in Figure 4, the power generation unit 400 includes a rotating plate 410, an interlocking linker 420, a straight linker 430, a direction change linker 440, a rotating linker 450, and tension Includes a spring 460.

The rotating plate 410 of the power generating unit 400 is axially coupled to one side of the frame 100, and serves to push or pull the interlocking linker 420 while rotating clockwise and counterclockwise in the drawing. The power source for rotating the rotating plate 410 is preferably electric, and the rotating plate 410 is preferably installed to be rotated through a driving mechanism of the bevel gear 400a as shown in FIG. 3. It is preferable that the rotating plate 410 has a triangular shape. One of the three sides of the rotating plate 410 is axially coupled to a rotating shaft through a driving mechanism of the bevel gear 400a.

The interlocking linker 420 of the power generating unit 400 serves to push or pull the straight linker 430 while being interlocked with the rotational action of the rotating plate 410. The interlocking linker 420 is installed in the rotation radius range of the rotating plate 410, and is provided in the form of a bar. One side of the interlocking linker 420 is connected to the two sides of the rotating plate 410, and one side of the interlocking linker 420 has a long guide hole to guide the movement of the two sides when the rotating plate 410 is rotated. 421 is formed. With this configuration, when the rotating plate 410 rotates around the first side, the second side of the rotating plate 410 is raised or lowered in the guide hole 421 of the interlocking linker 420 along the rotation radius of the rotating plate 410. As the interlocking linker 420 is pushed or pulled.

The straight linker 430 of the power generating unit 400 is configured to perform a reciprocating straight motion toward the pressing rod 300 by a force pushed or pulled by the interlocking linker 420. The straight linker 430 is provided as a straight bar, and one end of the straight linker 430 is located on the pressure rod 300 side, and the other end of the straight linker 430 is coupled to the interlocking linker 420. . A long-hole connecting hole 431 formed in the length direction of the straight linker 430 is formed at the other end of the straight linker 430. The connecting hole 431 is formed in two at the other end of the straight linker 420, and the connecting hole 431 formed so that the action of the interlocking linker 420 can be transmitted is referred to as a first connecting hole 431a, which will be described later. A connection hole 431 that can be coupled to the rotating linker 450 is referred to as a second connection hole 431b.

The direction changing linker 440 of the power generating unit 400 is configured to change the direction of the straight movement of the straight linker 430 in a vertical direction, that is, in an up-down direction. The direction change linker 440 is installed between one end of the straight linker 430 and the upper end of the pressure rod 300 in the drawing. The direction change linker 440 is configured to convert a straight direction of the straight linker 430 into an up/down elevation direction while a plurality of linkers composed of three axes are connected and rotated. The direction change linker 440 may be configured to change the moving direction of the straight linker 430, and a known technique may be applied.

The rotating linker 450 of the power generating unit 400 is provided for the stretching and contracting action of the tension spring 460 to be described later, and is connected between the rotating plate 410 and the other end of the straight linker 430. One end of the rotary linker 450 is connected to one side to which the rotary plate 410 is axially coupled, and the other end of the rotary linker 450 is connected to the second connection hole 431b of the straight linker 430. The rotary linker 450 is rotated toward both sides around one side of the rotating plate 410 to maximize the tension distance of the tension spring 460 or restore the tension distance of the tension spring 460. At this time, the frame 100 is formed with an arc hole 451 in the form of an arc for guiding the rotation of the rotary linker 450.

The tension spring 460 of the power generating unit 400 is configured so that the line opening (OFF) and input (ON) actions, that is, the lifting action of the pressure rod 30) can be performed over two steps, and the rotary linker ( 450) and is installed between the three sides of the rotating plate 410. The tension spring 460 is maximally tensioned during the rotational action of the rotating plate 410 for driving the straight linker 430 and then restored (step 2 action) while performing the pressure rod 300. It was made to work double. That is, while the tension spring 460 is elongated, the pressure rod 300 is inserted into the detachment hole 232 of the detachment means 230, and when the tension spring 460 is restored, the pressure rod 300 is detachable means It descends together with 230 to contact the movable electrode 211 with the fixed electrode 212. A detailed description of this will be described later.

Meanwhile, a ground linker 500 is provided in the switch. The ground linker 500 is installed above the applied conductive part (L) and installed so as to be rotated toward the applied conductive part (L). The ground linker 500 is also installed to be rotated through a driving mechanism of the ground bevel gear 400b as shown in FIG. 3. That is, the first linker 510 moves in a straight line by the driving of the ground bevel gear 400b, and the second linker 520 is rotated by the straight movement of the first linker 510, thereby forming the ground bar 530. It is configured to be able to rotate. The ground bar 530 is rotated and is brought into contact with the applied conduction unit L below to be grounded to the ground.

Hereinafter, the operation of the switch configured as described above will be described.

4 and 8 are views in which the track is opened (OFF), and the pressure rod 300 is raised and completely separated from the detachment means 230. In addition, since the movable electrode 211 is separated from the fixed electrode 212, the contact distance between the electrodes 211 and 212 is increased due to the securing of a straight path 221 in the chamber 220. The contact gap, that is, the insulation distance, can sufficiently secure the insulation distance by adding an air-interruption study period to the conventional vacuum insulation unit. This can prevent safety accidents such as electric shock due to induced voltage.

In this state, the operator operates the power generation unit 400 to operate the line from open (OFF) to input (ON). By driving the bevel gear 400a, the rotating plate 410 is rotated in a clockwise direction as shown in FIG. 5 around one side. Due to the rotating operation of the rotating plate 410, the two side portions of the rotating plate 410 are raised along the guide hole 421 of the interlocking linker 420 and push the interlocking linker 420 to the left side in the drawing. At this time, it can be seen that the tension spring 460 extends to the maximum while being rotated along the three sides of the rotating plate 410. In addition, the straight linker 430 can be seen that the interlocking linker 420 is moved to the left as shown through FIGS. 4 and 5 by the action of pushing along the first connection hole (431a), and the direction is changed. It can be seen that the linker 440 is in a state in which the pressure rod 300 is lowered. At this time, the pressure rod 300 descends as shown in FIG. 9 and is inserted into the detachment hole 232 of the detachment means 230 through the input hole 222a of the input part 222. This series of actions can be referred to as a one-step action for line input (ON).

The bevel gear 400a is continuously rotated to rotate the rotating plate 410, and as the interlocking linker 420 continuously pushes the straight linker 430, the second connection hole 431b of the straight linker 430 The rotary linker 450 coupled to is rotated along the arc hole 451 in a counterclockwise direction as can be seen through FIGS. 5 and 6. At this time, it can be seen that the tension spring 460 that has been elongated while the tension distance of the tension spring 460 is restored by the rotation of the rotary linker 450 is restored as shown in FIG. 6.

The straight linker 430 rotates the direction change linker 440 as it continues to move to the left in the drawing, and the direction change linker 440 lowers the pressure rod 300 again. As can be seen through FIGS. 9 and 10 by the descending of the pressure rod 300, the detachment means 230 also descends along the straight path 221. At this time, as the inner diameter of the straight path 221 decreases, the restraint pin 231a interferes with the inner circumferential surface of the straight path 221 as shown in FIG. 10 and is inserted into the peripheral hole 233 while contracting the spring 231b. In this way, by compressing the pressure rod 300 on the detachable hole 232, the binding force of the pressure rod 300 in the detachment means 230 can be increased. As the detachment means 230 descends, the movable electrode 211 is brought into contact with the fixed electrode 212, and at this time, the buffer spring 240 interposed between the detachment unit 230 and the vacuum opening/closing unit 210 contracts while the detachment unit ( 230) buffers the descending force. As a result, the contact between the electrodes 211 and 212 in the vacuum opening/closing unit 210 is completed and the line is turned ON. At this time, since the pressure rod 300 is constrained by the detachment means 230, the pressure rod 300 does not separate from the detachment means 230 while the electrodes 211 and 212 are in contact.

Thereafter, in order to open (OFF) the line that has been turned on for maintenance, the above-described series of processes is reversed. The driving of the bevel gear 400a is reversed, and the rotation of the rotating plate 410 is performed in a counterclockwise direction by the action of the bevel gear 400a. The interlocking linker 420 moves the straight linker 430 to the right as it can be seen through FIGS. 6 and 7 while descending along the guide hole 421. In this process, the detachment means 230 is raised along the straight path 221 at the point where the tension spring 460 is maximally elongated, and the rise of the detachment means 230 is effectively made by the restoring force of the buffer spring 240. I can. At this time, when the detachment means 230 reaches a point where the inner diameter of the straight path 221 is wide, the spring of the peripheral hole 233 due to securing a gap due to the difference between the diameter of the detachment means 230 and the inner diameter of the straight path 221 The restraining pin 231a is pushed out from the restraining jaw 310 while being restored. Accordingly, the pressure rod 300 becomes free from the detachment hole 232 of the detachment means 230, which can be understood through FIG. 9. Thereafter, as the straight linker 430 moves to the right by rotation of the rotary plate 410 and raises the pressure rod 300, the pressure rod 300 is a detachable means 230 as shown in FIG. It is completely separated from the desorption hole 232 of, and the line is completely opened (OFF).

This completes the open-close-open action of the line through the switch.

On the other hand, during maintenance work, the operator connects the ground linker 500 to the applied conduction unit L to ground. The operator drives the ground bevel gear 400b shown in FIG. 3, and the first linker 510 moves straight forward by driving the ground bevel gear 400b and rotates the second linker 520, as shown in FIG. As described above, the lifting bar 530 is lowered. At this time, as the ground bar 540 is rotated clockwise due to the lowering of the lifting bar 530 and contacts the applied electric current part L, the grounding of the switch may be made. To release the ground, the ground bevel gear 400b ) Can be driven in reverse.

As described so far, the high voltage switch of the double insulation structure having an auxiliary insulating section in the vacuum switch to which the VI (Vacuum Interrupter) according to the present invention is applied increases the insulation distance between electrodes, and when open (OFF), the pressure rod is completely from the electrode. By separating, it is possible to prevent safety accidents caused by the generation of induced voltage. In addition, the high voltage switch of the double insulation structure, which has an auxiliary insulation section on the vacuum switch to which the VI (Vacuum Interrupter) is applied, allows the opening (OFF) and closing (ON) actions according to the increase of the insulation distance to be performed in two stages When the shock can be alleviated, the opening (OFF) and closing (ON) actions can be made more efficiently.

In the above, the present invention has been described in detail with respect to the described embodiments, but it is obvious to those skilled in the art that various modifications and modifications are possible within the scope of the technical idea of the present invention, and it is natural that such modifications and modifications fall within the scope of the appended claims.

100: frame 200: contact part
210: vacuum switch 211: movable electrode
212: fixed electrode 220: chamber
221: straight path 221a: locking jaw
222: input part 222a: input hole
230: detachment means 231: restraint means
231a: restraint pin 231b: spring
232: detachment hole 233: circumference hole
240: buffer spring 300: pressure rod
310: restraint jaw 400: power generation unit
400a: bevel gear 400b: ground bevel gear
410: rotating plate 420: interlocking linker
421: guide ball 430: straight linker
431: connecting hole 431a: first connecting hole
431b: second connection hole 440: direction change linker
450: rotary linker 451: arc hole
460: tension spring 500: ground linker
510: first linker 520: second linker
530: lifting bar 540: ground bar

Claims (4)

A contact portion in which opening (OFF) and closing (ON) of the switch is made through the contact between the movable electrode and the fixed electrode, a pressure rod provided to move the movable electrode toward the fixed electrode, and a pressure rod to move the pressure rod straight forward. In the high-pressure switch comprising a power generating unit for generating power that can be,
The contact part,
A vacuum opening and closing part providing a space in a vacuum state in which the contact between the fixed electrode and the movable electrode is formed;
A chamber which encloses and protects the vacuum opening/closing part, and providing a straight path toward the vacuum opening/closing part above the vacuum opening/closing part, but having a stepped portion formed on the inner circumferential surface of the straight path due to an inner diameter difference between the lower and upper parts of the straight path; And
It is provided so that the pressure rod can be detached, and is provided so as to interlock the movement of the movable electrode while moving straight on the straight path of the chamber by the straight movement of the pressure rod, and according to the position on the straight path. Detachment means provided with a restraint means to restrain the coupling or separate the pressure rod: including,
It is configured so that the first step in which the pressure rod is coupled to the detachment means and the second step of contacting the movable electrode to the fixed electrode by moving the pressure rod coupled to the detachment means can be achieved,
The detachment means is formed with a detachable hole corresponding to the diameter of the pressure rod so that the pressurizing rod can be detached, a circumferential hole through which the straight path and the detachable hole are formed around the detachment unit, and the restraining unit, A high-voltage switch having a double insulation structure having an auxiliary insulating section in a vacuum switch to which a vacuum interrupter (VI) is applied, comprising a restraining pin inserted into the peripheral hole and a spring elastically supporting the restraining pin on the peripheral hole. delete The method of claim 1,
The power generation unit,
A rotating plate axially coupled to one side of the switch;
An interlocking linker coupled to the rotational radius of the rotational plate and installed to be pushed by a rotational distance according to the rotational radius when the rotational plate is rotated;
A straight linker coupled to the interlocking linker and moving straight by a distance pushed from the interlocking linker;
A direction changing linker connected between the straight linker and the pressure rod, and transmitting the straight linker to the pressure rod by vertically changing a straight direction of the straight linker;
One end is connected to the end of the straight linker, the other end is connected to the shaft of the rotating plate, the rotating linker rotates about the axis of the rotating plate when the straight linker moves; And
VI, characterized in that it comprises a tension spring installed between the rotary linker and the rotary plate, which is installed between the rotary linker and the rotary plate, and is stretched and contracted between the rotary linker and the rotary plate when the rotary plate is rotated. (Vacuum Interrupter) is a double-insulated high-voltage switch with an auxiliary insulating section in the vacuum switch. The method of claim 3,
When the tension spring tension distance between the rotary linker and the rotary plate is the maximum due to the rotation of the rotary plate, the straight linker moves to perform a first step action of coupling the pressure rod to the detachment means,
When the straight linker moves again by the continuous rotation of the rotary plate and the tensioned spring is restored by rotating the rotary linker, the pressing rod coupled to the detachment means proceeds again to contact the movable electrode with the fixed electrode. A high-voltage switch with a double insulation structure having an auxiliary insulation section on a vacuum switch to which a VI (Vacuum Interrupter) is applied, characterized in that the action takes place.

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