KR101191331B1 - Vacuum interrupter - Google Patents

Abstract

PURPOSE: A vacuum circuit breaker is provided to prevent a housing forming failure by insulating the outside of an insulation container using a housing composed of a tube to which silicon rubber is attached. CONSTITUTION: A load side terminal(13) formed between a power side terminal(11) and an insulation rod(12) is embedded in an insulation housing(10). A vacuum interrupter(20) is fixed in the insulation housing. A connection unit(30) is composed of an electrode bracket(32) and a bracket fixing bolt(33). A current detecting unit(60) is installed on the outer circumference of the insulation housing. A top support(70) fixes and supports a power side terminal(11). A bottom support(40) fixes the insulation housing to a link frame.

Description

Vacuum interrupter

The present invention relates to a vacuum circuit breaker, and more particularly, an FRP tube in which silicone rubber is adhered to the inner and outer surfaces without filling an insulating material such as epoxy between the insulating container and the housing for the external insulation of the insulating container keeping the inside in a vacuum state. It relates to a vacuum circuit breaker which constitutes a furnace housing to achieve external insulation of an insulation container.

In general, a circuit breaker is a protection device for an electric device that serves to protect a load device and a line from a large current caused by a possible short-circuit or ground fault in an electric circuit, and automatically cuts off a line when an accident current occurs. It will serve to separate.

The vacuum circuit breaker, which is one of the circuit breakers as described above, is capable of quickly disconnecting a circuit by extinguishing arcs generated during normal load switching and breaking of an accident current in a vacuum container. Therefore, the valve body of the vacuum circuit breaker is similarly used for the fixed electrode fixed to the end surface of the conducting conductor in the insulating container such as ceramics to maintain the vacuum state, and similarly to the end surface of the conducting conductor. The fixed movable electrodes are opposed to each other.

The valve body is provided as a vacuum circuit breaker with a manipulator for driving a movable electrode under the valve body.

The manipulator used in the vacuum circuit breaker makes the rotation of the rotary shaft linearly by means of a device such as a lever, and moves the movable electrode linearly to cause contact with the fixed electrode. That is, the manipulator performs a shut-off operation by removing the movable electrode from the fixed electrode based on the shutoff command from the control device, and performs a shut-off operation of bringing the movable electrode into contact with the fixed electrode based on the shut-off command. A spring called a wipe spring is installed.

The pressure contact spring, etc., facilitates the blocking and closing operation of the movable electrode, and applies a predetermined contact pressure when the operation of the movable and fixed electrode is completed, and when the movable electrode is put into the fixed electrode, It is used to prevent chattering which damages the contact surface.

Recently, vacuum breakers, which are the most used among medium voltage class breakers, have been commercialized in the 1960s by using the advantages of high dielectric strength under vacuum of 10-3 Torr or less, and have made significant progress in high voltage, high current and miniaturization. .

The vacuum interrupter, which is a key component of the vacuum circuit breaker, includes a movable electrode and a fixed electrode, each having a well-closed insulated container and contacts which are in contact with each other in the insulated container to maintain a vacuum state.

In more detail, in these vacuum circuit breakers, load switching and fault current blocking are performed in a vacuum state in the vacuum interrupter, but external insulation of the vacuum interrupter is performed in various media. Vacuum Interrupter can be insulated in air like VB (Vacuum Circuit Breaker), or vacuum interrupter can be insulated in oil like OBC (Oil Circuit Breaker) and SF6 gas is used like high pressure switch. Insulation may be achieved. However, these insulation methods have various problems.

Air insulation such as VCC cannot be used where high impact voltage is required because of the low dielectric strength of air. In addition, the use of oil insulation such as OCB has rarely been used recently because of the risk of oil explosion. Lastly, diesel fuel using SF6 gas, such as high pressure switch, is used where high impact voltage is required and there is no explosion risk, but it is increasingly regulated in the environmental aspects of ozone layer destruction.

In addition, in the conventional "vacuum breaker", a ceramic pipe is used as an insulating housing, but the ceramic pipe is heavy, which is not easy to handle during transportation and installation, and is expensive and causes flashover. There was a problem that often the pipes are broken.

Therefore, in recent years, an epoxy is used as the insulating housing, and an integrated solid insulating method for inserting a vacuum interrupter during epoxy molding is used, and a description thereof is as follows.

As shown in FIG. 1, a vacuum circuit breaker having a conventional insulation structure is inserted in molding an epoxy housing 2 in which a vacuum interrupter 1, in which load switching and fault current blocking are performed, serves to insulate and support the vacuum interrupter 1. And molded. The fixed contact point 6 of the vacuum interrupter 1 is fastened to the upper terminal 7 of the epoxy housing 2 and inserted into a mold having a cavity having the same shape as the epoxy housing 2 and then molded.

At this time, the epoxy 8 constituting the epoxy housing 2 and the ceramic 9 constituting the outer circumferential surface of the vacuum interrupter 1 have different thermal expansion coefficients, and thus pressure due to shrinkage of the epoxy 8 during cooling after molding. In order to alleviate the pressure, the outer circumferential surface of the ceramic 9 is wrapped in the silicon tube 5 to relieve pressure to prevent breakage of the ceramic 9 due to shrinkage of the epoxy 8.

The movable contact 6 'of the vacuum interrupter 1 and the lower terminal 7' of the epoxy housing 2, which are mounted on the vacuum circuit breaker formed of integral solid insulation, are connected by a flexible shunt (3). And energization is possible, and a driving rod 4 having one end connected to the movable contact 12 of the vacuum interrupter 1 by a driving mechanism is connected to vertically move the movable contact 12 of the vacuum interrupter 1. To help.

In the vacuum circuit breaker configured as described above, when the driving mechanism is operated to move the up and down direction, the movable contact 12 of the vacuum interrupter 1 connected to the driving rod 4 moves up and down while opening and closing the load. Alternatively, the fault current is interrupted in the vacuum interrupter 1. At this time, the opening and closing of the load or the blocking of the fault current are inherent in the vacuum interrupter 1, but phase-to-phase and earth-to-earth insulation are important factors that determine the performance, and the fixed contact 11 and the movable contact 12 to the outside The insulation of the vacuum interrupter 1 constituted by the integrated solid insulation method, whose performance is determined by the medium surrounding the vacuum interrupter 1, is insulated by the epoxy 21.

However, the vacuum circuit breaker configured as described above covers the silicon tube 5 for relieving the pressure due to the shrinkage of the epoxy 21 on the outside of the ceramic 13, which is the outer circumferential surface of the vacuum interrupter 1, and the cooling of the epoxy 21 is performed. It is difficult to match the correct molding conditions because the shrinkage ratio is not constant according to the conditions or shapes, and if a defect occurs during molding, there is a problem that the vacuum interrupter 1 cannot be used again.

In addition, when a failure occurs in the vacuum interrupter 1 to which the integrated solid insulation method is applied and repair or replacement is required, the epoxy housing 2 and the peripheral parts as well as the vacuum interrupter 1 must be replaced as a whole. There is a problem that a lot of costs are used.

As developed to solve these problems, Patent No. 0492755, "Isolating device of a vacuum circuit breaker" is disclosed in the registered patent publication.

As described with reference to Fig. 2, the " insulating device for vacuum circuit breaker " includes an epoxy housing 102 having an upper terminal 122 and a lower terminal 123 connected to the outside and having a predetermined inner space as shown in FIG. It is mounted in the inner space of the epoxy housing 102, and has a fixed contact 111 and a movable contact 112 electrically connected to the upper terminal 122 and the lower terminal 123, the epoxy housing 102 A vacuum interrupter 101 fixedly or decomposably installed at a); Fastening means for fixing or disassembling the vacuum interrupter (101) to the epoxy housing (102); An insulating filler (107) filled therebetween to insulate the epoxy housing (102) from the vacuum interrupter (101); The fastening means includes a movable clamp 106 assembled with the vacuum interrupter 101, a bolt 109 for fixing or disassembling the movable clamp 106 to the epoxy housing 102, and the upper terminal 122. ) And a mounting bracket 108 for electrically connecting the fixed contact 111 to one side of the vacuum interrupter 101, the movable contact 112 having a driving rod 104 coupled thereto is formed. .

Therefore, when the vacuum interrupter is desired to be repaired and replaced, only the vacuum interrupter can be disassembled and worked in the inner space of the epoxy housing, thereby reducing the maintenance cost.

However, in the vacuum circuit breakers described above, the epoxy constituting the epoxy housings 2 and 102 has no problem in a room where there is little change in the external environment, but when it is used outdoors as a vacuum circuit breaker, a crack occurs in the external environment according to the season. In other words, there was a problem in that the durability against the change in temperature and humidity, as well as the durability of the ultraviolet rays of sunlight is weak.

In addition, since the epoxy constituting the epoxy housing (2, 102) is expensive in terms of price, there is also a problem that it is uneconomical to increase the price of the product.

The present invention has been invented to solve various defects and problems caused by the conventional vacuum circuit breaker in view of the above situation, the object of which is to form the housing by FRP tube bonded to the silicone rubber on the inner and outer surfaces to the outside of the insulating container It is to provide a vacuum circuit breaker that does not cause a molding failure during the molding of the housing by insulating.

Another object of the present invention is to form a housing with FRP tube bonded to the silicone rubber on the inner and outer surfaces to insulate the outside of the insulated container, even when used outdoors, durability against changes in the external environment according to the season, that is, temperature and humidity changes In addition, the excellent durability against ultraviolet rays, etc. to provide a vacuum circuit breaker without the risk of cracks and damage.

Another object of the present invention is to form a housing with an FRP tube bonded to the silicone rubber on the inner and outer surfaces to insulate the outside of the insulating container, thereby reducing the cost of the external insulating of the insulating container to reduce the price of the product economical It is to provide this excellent vacuum circuit breaker.

It is still another object of the present invention to provide a vacuum circuit breaker which does not have a risk of breakage due to flashover phenomenon.

The vacuum circuit breaker of the present invention for achieving the above object is provided with a power supply side terminal 11 connected to the outside formed in the upper end portion, the insulating rod 12 for operation of the movable electrode formed on the lower side with an insulating bracket 12a at one end, and the An insulating housing 10 in which a load side terminal 13 formed between the power supply side terminal 11 and the insulating rod 12 is embedded; The insulating housing 10 includes a fixed electrode 21 and a movable electrode 22 mounted inside the upper portion of the insulating housing 10 and electrically connected to the power supply terminal 11 and the load terminal 13. A vacuum interrupter 20 fixedly installed; An electrode connecting the load side terminal 13 and the multi-electrode 31 by surrounding the multi-electrode 31 while the multi-electrode 31 connected to the lower end of the movable electrode 22 and the load-side terminal 13 are connected. Connecting means (30) comprising a bracket (32) and a bracket fixing bolt (33); Current detecting means (60) installed at an outer circumference of the insulating housing (10) for receiving a load-side terminal (13) adjacent to the connecting means (30); An upper supporter 70 installed between the power supply terminal 11 and the insulating housing 10 to fix and support the power supply terminal 11; Characterized in that it consists of a lower support 40 for fixing the insulating housing 10 to the link frame on which the operating system of the insulating rod 12 is mounted.

The present invention forms a housing with an FRP tube bonded to silicone rubber on the inner and outer surfaces to insulate the outside of the insulating container, so that molding failure does not occur when the housing is molded, and even when used outdoors, the external environment changes according to the season. Not only is it resistant to temperature and humidity changes, but also has excellent durability against ultraviolet rays of sunlight, so there is no fear of cracks or damages. There is a special advantage that is excellent and there is no fear of damage due to flashover phenomenon.

1 is a longitudinal sectional view of an embodiment showing the internal structure of a conventional vacuum circuit breaker;
Figure 2 is a longitudinal cross-sectional view of another embodiment showing the internal structure of a conventional vacuum circuit breaker,
Figure 3 is a longitudinal sectional view showing the internal structure of the vacuum circuit breaker of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the vacuum circuit breaker of the present invention.

3 is a longitudinal cross-sectional view showing the internal structure of the vacuum circuit breaker of the present invention. The vacuum circuit breaker of the present invention includes a power supply terminal 11 connected to an outer side formed at an upper end portion, and an insulating bracket 12a at one end thereof. An insulating housing (10) having an operation insulating rod (12) and a load side terminal (13) formed between the power supply terminal (11) and the insulating rod (12); The insulating housing 10 includes a fixed electrode 21 and a movable electrode 22 mounted inside the upper portion of the insulating housing 10 and electrically connected to the power supply terminal 11 and the load terminal 13. A vacuum interrupter 20 fixedly installed; An electrode connecting the load side terminal 13 and the multi-electrode 31 by surrounding the multi-electrode 31 while the multi-electrode 31 connected to the lower end of the movable electrode 22 and the load-side terminal 13 are connected. Connecting means (30) comprising a bracket (32) and a bracket fixing bolt (33); Current detecting means (60) installed at an outer circumference of the insulating housing (10) for receiving a load-side terminal (13) adjacent to the connecting means (30); An upper supporter 70 installed between the power supply terminal 11 and the insulating housing 10 to fix and support the power supply terminal 11; It is composed of a lower support (40) for fixing the insulating housing 10 to a link frame on which the operating system of the insulating rod 12 is mounted.

The insulating housing 10 is formed by molding to accommodate the housing in the housing, the FRP tube (10a), the inner silicone rubber (10b) is molded in a state attached to the inner surface of the FRP tube (10a) and It consists of an outer silicone rubber (10c) is molded in a state attached to the outer peripheral surface of the FRP tube (10a).

 The inner silicon rubber (10b) is further formed with an insulating distance separation means 50 to form a plurality of circular wings inwardly to separate the insulating distance.

If the insulating housing 10 is formed only with the silicone rubbers 10b and 10c, the silicone rubber is soft, so that it is difficult to maintain the shape of the insulating housing 10. Therefore, the internal silicon having good insulating performance on the inner and outer surfaces of the rigid FRP tube 10a is provided. The rubber 10b and the outer silicone rubber 10c are integrally molded.

In addition, it is preferable that a circular ring-shaped voltage detector 10d is inserted into the upper end of the insulating housing 10 so as to check whether the voltage is activated.

In addition, the insulating rod 12 is composed of an insulating bracket 12a, a switch operating FRP insulating rod 12b, and a silicone rubber 12c protruding at regular intervals from the FRP insulating rod 12b to reinforce insulation. It is desirable to.

Next, the operation of the vacuum circuit breaker of the present invention configured as described above will be described in detail.

The vacuum circuit breaker of the present invention includes an insulating rod 12 and a load side terminal 13 having a power supply side terminal 11 and an insulating bracket 12a at one end of the mold having the same cavity as the shape of the insulating housing 10. And, insert the vacuum interrupter 20, the connecting means 30, the lower support 40, the insulating distance separation means 50, the upper support 70 and the lower support 40, It is made by integrally molding the insulating housing 10 consisting of the FRP tube 10a, the inner silicone rubber 10b, and the outer silicone rubber 10c, and the reversing link in the link frame (not shown) installed at the bottom is an insulating rod ( 12) will be lifted up and down.

When the direction change link raises the insulating rod 12, the insulating bracket 12a of the insulating rod 12 rises and the movable electrode 22 in the vacuum interrupter 20 is raised to move the movable electrode 22 to the fixed electrode ( Power supplied to the power supply terminal 11 by being connected to the power supply 21 is supplied to the load terminal 13 through the fixed electrode 21, the movable electrode 22, and the multi-electrode 31.

On the other hand, when the direction change link lowers the insulating rod 12, the insulating bracket 12a of the insulating rod 12 descends while lowering the movable electrode 22 in the vacuum interrupter 20 to move the movable electrode 22. By being separated from the fixed electrode 21, the power supplied to the power supply terminal 11 is interrupted from being supplied to the load terminal 13.

In this way, the opening and closing of the load or the interruption of the fault current are made in the vacuum interrupter 20, and at this time, the phase insulation, the ground insulation, and the insulation of the fixed electrode 21 and the movable electrode 22 to the outside are FRP. High-performance insulation is achieved by the insulating housing 10 composed of the tube 10a, the inner silicone rubber 10b, and the outer silicone rubber 10c.

While the present invention has been described as a preferred embodiment, the present invention is not limited thereto, and various modifications can be made without departing from the gist of the invention.

10: insulated housing 10a: FRP tube
10b: internal silicone rubber 10c: external silicone rubber
10d: circular ring 11: power supply terminal
12: insulated rod 12a: insulated bracket
12b: FRP insulation rod 12c: silicone rubber
13: load side terminal 20: vacuum interrupter
21: fixed electrode 22: movable electrode
30: connecting means 31: multi-electrode
32: electrode bracket 33: bracket fixing bolt
40: lower support 50: insulation distance separation means
60: current detection means 70: upper support

Claims (5)

A power supply terminal 11 connected to the outer side formed at the upper end, an insulating bracket 12a at one end thereof, and an insulating rod 12 for operating a movable electrode formed at a lower portion thereof, and between the power supply terminal 11 and the insulating rod 12. An insulating housing 10 in which the formed load side terminals 13 are embedded; The insulating housing 10 includes a fixed electrode 21 and a movable electrode 22 mounted inside the upper portion of the insulating housing 10 and electrically connected to the power supply terminal 11 and the load terminal 13. A vacuum interrupter 20 fixedly installed; An electrode connecting the load side terminal 13 and the multi-electrode 31 by surrounding the multi-electrode 31 while the multi-electrode 31 connected to the lower end of the movable electrode 22 and the load-side terminal 13 are connected. Connecting means (30) comprising a bracket (32) and a bracket fixing bolt (33); Current detecting means (60) installed at an outer circumference of the insulating housing (10) for receiving a load-side terminal (13) adjacent to the connecting means (30); An upper supporter 70 installed between the power supply terminal 11 and the insulating housing 10 to fix and support the power supply terminal 11; Vacuum breaker consisting of a lower support (40) for fixing the insulating housing (10) to the link frame on which the operating system of the insulating rod (12) is mounted. The method of claim 1, wherein the insulating housing 10 is formed by molding to accommodate the interior of the housing, the interior formed in the state attached to the FRP tube (10a) and the inner surface of the FRP tube (10a) And a silicone rubber (10b) and an external silicone rubber (10c) molded in a state attached to the outer circumferential surface of the FRP tube (10a). The method of claim 2, wherein the inner silicon rubber (10b) is formed with an insulating distance separating means 50 to form a plurality of circular wings inwardly to separate the insulating distance Vacuum breaker characterized in that. The vacuum circuit breaker according to claim 1 or 2, wherein a voltage detection unit having a circular ring (10d) shape is inserted into an upper end of the insulating housing (10) to check whether the voltage is active. According to claim 1 or 2, wherein the insulating rod 12 is a silicone rubber protruding at regular intervals to the insulating bracket (12a), the switch operating FRP insulating rod 12b and the FRP insulating rod 12b ( 12c) vacuum breaker, characterized in that consisting of.

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