KR100832331B1 - Force transmission apparatus for load break switch - Google Patents

Abstract

A force transmission apparatus for a load break switch is provided to improve stability by collectively opening and closing three phases through the same axis. One end of a force transmission axis(151) is connected to a control device(130). A cam axis(171) is interlocked with the force transmission axis by being arranged on upper parts of a main circuit switch(110) and a ground circuit switch(120) and includes a cam. A first operation axis(181) and a second operation axis(191) are arranged on the upper parts of the two switches respectively. A main circuit contact pressure spring unit is connected to a movable contact unit of the main circuit switch. A ground circuit contact pressure spring unit is connected to a movable contact unit of the ground circuit switch. A main circuit link unit(251) includes a pair of links connected to the first operation axis and the main contact pressure spring unit respectively and the connected portions are in contact with one side of a cam(175). A ground circuit link unit includes a pair of links connected to the second operation axis and the ground circuit contact pressure spring unit respectively and the connected portions are in contact with the other side of the cam.

Description

Power transfer device of high voltage load switch {FORCE TRANSMISSION APPARATUS FOR LOAD BREAK SWITCH}

1 is a side cross-sectional view of a power transmission device of a high voltage load switch according to an embodiment of the present invention;

2 is a perspective view showing a state of use of the power transmission device of FIG.

3 is a perspective view of the power transmission shaft of FIG.

4 is a perspective view of the camshaft of FIG.

5 is a perspective view of a first operation shaft;

6 is a perspective view of the second operation shaft 191,

7 is a perspective view of the connecting rod of FIG.

8 and 9 are respectively a perspective view of the support frame of FIG.

10 is an exploded perspective view of the main circuit contact spring unit of FIG. 2;

11 is a cross-sectional view of the coupled state of FIG.

12 to 14 are views for explaining the operation of the power transmission device of FIG.

Explanation of symbols on the main parts of the drawings

110: main circuit switch 120: ground circuit switch

130: operation mechanism 140: frame

150: power transmission device 151: power transmission shaft

161: connecting rod 171: camshaft

175: cam 181: first axis of motion

191: second operation shaft 221a: main circuit contact spring unit

221b: Ground circuit contact spring unit 251: Main circuit link unit

257,267: roller 261: ground circuit link part

The present invention relates to a power transmission device of a high voltage load switchgear, and more particularly, to a power transmission device of a high voltage load switchgear capable of transmitting power by converting a rotary motion into a linear motion.

In general, electricity generated at a voltage of approximately 20,000 V at a power plant is boosted to a very high voltage suitable for power transmission, and then transmitted to a primary substation. Electric power supplied from the primary substation is supplied to the receiving facility of each customer through distribution system composed of overhead distribution line and underground distribution line, and is supplied to low pressure consumer through special high pressure consumer, high pressure consumer and various outdoor transformers.

At this time, a multi-circuit switch is used for the purpose of branching and branching underground distribution lines, and the multi-circuit switch is equipped with a fire protection part mainly using sulfur hexafluoride (SF ₆ ) gas as an insulating material. However, sulfur hexafluoride gas has a greenhouse effect of 23,900 times higher than that of carbon dioxide (CO ₂ ). Currently, the use of sulfur hexafluoride gas is regulated around the world, and the high voltage load switch that employs a vacuum interrupter as a subdivision. Usage is increasing.

On the other hand, such a high voltage load switch is provided with a mechanism (mechanism) to drive the arc extinguisher in three positions of opening, closing, and ground.

By the way, in the conventional high voltage load switch, the output shaft of the operation mechanism is configured to rotate between the opening and closing and the ground, so that the movable interrupter directly opens and closes the circuit while opening and closing the circuit while the linear contact is fixed to the fixed contact part. There is a problem that it is difficult to connect and use.

Accordingly, an object of the present invention is to provide a power transmission device of a high voltage load switchgear capable of converting a rotational motion into a linear motion and transmitting the same.

In order to achieve the above object, the present invention provides a main circuit switch that opens and closes a main circuit, a ground circuit switch that opens and closes a ground circuit, and a main circuit switch and a ground circuit switch open, close, and ground, respectively. A power transmission device of a high voltage load switch that is disposed between operation mechanisms for operating the power supply to the main circuit switch and the ground circuit switch, the power transmission shaft being connected to the operation mechanism; A cam shaft disposed above the main circuit switch and the ground circuit switch and interlocked with the power transmission shaft and provided with a cam; First and second operating shafts disposed above each of the main circuit switch and the ground circuit switch; A main circuit contact spring unit connected to the movable contact of the main circuit switch; A ground circuit contact spring unit connected to the movable contact portion of the ground circuit switch; A main circuit link portion having a pair of links respectively connected to the first operation shaft and the main circuit contact spring unit, the connecting portion being in contact with one side of the cam; It is provided with a pair of links connected to the second operation shaft and the ground circuit contact spring unit, respectively, to provide a power transmission device for a high voltage load switch including a ground circuit link portion in contact with the other side of the cam. .

Here, one end is preferably configured to further include a connecting rod connected to the power transmission shaft and the other end is connected to the cam shaft.

The power transmission shaft and the cam shaft are effectively spaced vertically spaced apart vertically.

It is preferable to further comprise a support frame for supporting the cam shaft, the first operating shaft and the second operating shaft 191.

It is effective to further comprise a trip spring for applying an elastic force so that the first and second operating shafts are rotated to the trip position.

Preferably, the first operation shaft and the second operation shaft are formed with a spring connection portion to which one end of the trip spring is connected.

It is effective that the main circuit link portion and the ground circuit link portion are provided with a rolling contact portion in rolling contact with the cam.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

1 is a side cross-sectional view of a power transmission device of a high voltage load switch according to an embodiment of the present invention, Figure 2 is a perspective view showing the use of the power transmission device of Figure 1, Figure 3 is a power transmission shaft of Figure 1 4 is a perspective view of the cam shaft of FIG. 1, FIG. 5 is a perspective view of the first operating shaft, FIG. 6 is a perspective view of the second operating shaft 191, FIG. 7 is a perspective view of the connecting rod of FIG. 1, 8 and 9 are respectively a perspective view of the support frame of Figure 1, Figure 10 is an exploded perspective view of the main circuit pressure spring unit of Figure 2, Figure 11 is a cross-sectional view of the coupling state of Figure 10, Figures 12 to 14 1 is a view for explaining the operation of the power transmission device of FIG. As shown in Figures 1 and 2, the high voltage load switch, the main circuit switch 110 and the ground circuit switch 120 for opening and closing the main circuit and the ground circuit, respectively, and the main circuit switch 110 and the ground circuit Frame 140 to which the operation mechanism 130 for opening and closing the switch 120, the main circuit switch 110 and the ground circuit switch 120 and the operation mechanism 130 are respectively coupled Equipped with. The operation mechanism 130 may include a neutral position in which the movable contact portions 112 and 122 of the main circuit switch 110 and the ground circuit switch 120 are spaced apart from the fixed contact points 114 and 124, and the main circuit. An input position at which the movable contact point 112 of the switch 110 contacts the fixed contact point 114 and a ground at which the movable contact point 122 of the ground circuit switch 120 contacts the fixed contact point 124. It is formed so that rotation is possible between positions. Between the main circuit switch 110 and the ground circuit switch 120 and the operation mechanism 130 to transfer the driving force of the operation mechanism 130 to the main circuit switch 110 and the ground circuit switch 120. The power transmission device 150 of the high voltage load switching device according to an embodiment of the present invention is installed.

The power transmission device 150 of the high voltage load switch includes a power transmission shaft 151 having one end connected to the operation mechanism 130; A cam shaft 171 disposed on an upper side of the main circuit switch 110 and the ground circuit switch 120 and interlocked with the power transmission shaft 151 and provided with a cam 175; A first operation shaft 181 and a second operation shaft 191 disposed above each of the main circuit switch 110 and the ground circuit switch 120; A main circuit contact spring unit 221a connected to a movable contact of the main circuit switch 110; A ground circuit contact spring unit 221b connected to the movable contact of the ground circuit switch 120; A first link 253 and a second link 255 connected to the first operation shaft 181 and the main circuit contact spring unit 221a, respectively, have a connection portion at one side of the cam 175. A main circuit link unit 251 in contact; A third link 263 and a fourth link 265 connected to the second operation shaft 191 and the ground circuit contact spring unit 221b, respectively, are provided on the other side of the cam 175. And a ground circuit link portion 261 in contact therewith.

The frame 140 includes a lower plate 141, an upper plate 143 disposed on an upper side of the lower plate 141, and a side plate 145 disposed on one side of the lower plate 141 and the upper plate 143. Equipped. The upper plate 143 is spaced apart from the lower plate 141 by a plurality of support rods 147. The side plate 145 is provided with the operation mechanism 130, the lower plate 141 has a plurality of through-holes so that the upper side of the main circuit switch 110 and the ground circuit switch 120 can be inserted ( 142 is formed.

The rear side of the side plate 145 is provided with a power transmission shaft 151, one end of which is rotatably connected to the central axis of the operation mechanism 130. The other end of the power transmission shaft 151 is rotatably supported by the support 149.

On the upper side of the upper plate 143, the cam shaft 171, the first operating shaft 181 and the second operating shaft 191 are arranged in parallel with each other, these cam shaft 171, the first operating shaft 181 And the second operation shaft 191 is disposed above the power transmission shaft 151 in a direction perpendicular to the power transmission shaft 151, respectively. The cam shaft 171, the first operating shaft 181, and the second operating shaft 191 are respectively rotatably supported at both ends by a first support frame 211 coupled to the upper plate 143. have.

As shown in FIG. 3, the power transmission shaft 151 has a rod connecting portion 153 protruding in the axial direction so that one end of the connecting rod 161 for transmitting power to the cam shaft 171 can be connected. Is formed.

As shown in FIG. 4, the camshaft 171 includes a plurality of cams 175 spaced apart from each other along the longitudinal direction of both ends. The cams 175 are formed to correspond to the positions of the plurality of main circuit switches 110 arranged in respective phases below the frame 140. The cam 175 is the main circuit link unit 251 when the movable contact portion 112, 122 of any one of the main circuit switch 110 and the ground circuit switch 120 is in contact with the fixed contact point (114, 124) Alternatively, the first section 176a to which the ground circuit link unit 261 is in contact, and the movable contact parts 112 and 122 of the main circuit switch 110 and the ground circuit switch 120 are spaced apart from the fixed contact parts 114 and 124. In this case, the main circuit link unit 251 and the ground circuit link unit 261 is provided with a camping profile having a second section (176b) in contact. The cam shaft 171 is provided with a rod connecting portion 173 so that the other end of the connecting rod 161, one end of which is connected to the power transmission shaft 151, can be connected.

The connecting rod 161 is formed to connect the power transmission shaft 151 and the cam shaft 171 disposed vertically with a height difference from each other, as shown in Figure 6, the amount of the connecting rod 161 At the end, coupling portions 163a and 163b are formed in different directions to be coupled to the rod connecting portion 153 of the power transmission shaft 151 and the rod connecting portion 173 of the cam shaft 171, respectively.

The first operating shaft 181 and the second operating shaft 191 are disposed parallel to each other on both sides of the cam shaft 171, one side of the cam 175 on the first operating shaft 181. A plurality of main circuit link units 251 are provided to contact the second section 176b, respectively. The second operation shaft 191 is provided with a plurality of ground circuit link parts 261 so as to be in contact with the second second section 176b of the cam 175, respectively. A trip spring 195 may be connected to the first operating shaft 181 and the second operating shaft 191 to apply an elastic force to rotate the first operating shaft 181 and the second operating shaft 191 to an initial position. A pair of spring connection parts 183 and 193 are formed so as to correspond to each other. The trip spring 195 is implemented in the form of a pair of tension coil springs, and spring fixing grooves 184 and 194 are cut in the respective spring connection portions 183 and 193 so that each end of the trip spring 195 can be held. ) Are formed respectively.

The main circuit link unit 251 may include a plurality of first links 253 connected to the first operation shaft 181, and a plurality of first links having one side connected to the main circuit contact spring unit 221a. Two links 255 are provided. A roller 257 is provided in the connection area between the first link 253 and the second link 255 so as to be in contact with the cam 175.

The ground circuit link unit 261 may include a plurality of third links 263 connected to the second operation shaft 191 and a plurality of fourth terminals having one side connected to the ground circuit contact spring unit 221b. The link 265 is provided. A roller 267 is provided in the connection area between the third link 263 and the fourth link 265 so as to be in contact with the cam 175.

On the other hand, since the configuration of the main circuit contact spring unit 221a and the ground circuit contact spring unit 221b are similar to each other, the following description is limited to the main circuit contact spring unit 221a and the ground circuit contact spring unit 221b. Will be described by quoting the same reference numeral. As shown in FIGS. 10 and 11, the main circuit contact spring unit 221a includes a rod 225 connected to the movable contact 112 of the main circuit switch 110, and the rod 225. A contact spring 230 is disposed outside the. The rod 225 is, in this embodiment, the upper rod portion 226a for guiding the contact spring 230, one end is connected to the lower portion of the upper rod portion 226a and the other end is the main circuit switch The lower rod part 226b connected with the movable contact part 114 of 110 is comprised. The lower rod part 226b is connected to the movable contact part 112 of the main circuit switch 110 through the nut 244 and the washer 246. A pin hole 227 is formed at an upper end of the upper rod part 226a to accommodate a link pin 237 to which the second link 255 is connected. The pin hole 227 is formed in the form of a long hole having a long vertical length so that the link pin 237 can move up and down. A spring support part 228 is formed on the upper rod part 226a to support the lower end of the contact spring 230, and pressurizes the contact spring 230 on an upper side of the contact spring 230. The washer 232 and the bush 234 are arranged so that it is. The bush 234 has a pin hole 235 is formed so that the link pin 237 can be received.

At both ends of the link pin 237, a separation prevention part 240 is formed to prevent the second link 255 coupled through the washer 238 from being separated outward. The release preventing part 240 is implemented in the form of a pin groove 241 formed on both ends of the link pin 237 and a stop ring 243 coupled to the pin groove 241 in this embodiment.

Both ends of each of the link pins 237 may have a pin guide having a long hole vertically formed on both sides of the first support frame 211 shown in FIG. 8 or the second support frame 221 shown in FIG. It is coupled to the inside of the 215,225 to be movable up and down. The second support frame 221 disposed between the first support frame 211 and the first support frame 211 includes the main circuit contact spring unit 221a and the ground circuit contact spring unit 221b. Passing holes 213 and 223 are formed to allow the upper region to pass therethrough, respectively.

Referring to the coupling process of the main circuit contact spring unit (221a) as follows. First, the lower end of the contact spring 230 on the outside of the rod 225 is coupled to be supported by the spring support 228, the washer 232 and the bush 234 is coupled to the upper end of the contact spring 230. . Next, the contact spring 230 is compressed to insert the link pin 237 into the pin holes 227 and 235. The washers 238 are coupled to both ends of the link pin 237, the lower ends of the second links 255 are coupled to each other, and the washers 238 are coupled to the outside thereof. When the second link 255 is coupled, the link pins 237 are coupled to the pin guides 215 and 225 of the first support frame 211 and the second support frame 221, and the first support frame 211 And a stop ring 243 coupled to the pin groove 241 at the outside of the second support frame 221 to prevent the departure.

By this configuration, when the coupling is completed, as shown in FIG. 12, the rollers 257 and 267 of the main circuit link unit 251 and the ground circuit link unit 261 are connected to the second section of the cam 175. 176b), respectively, and the operation mechanism 130 is connected to the power transmission shaft 151 at a neutral position.

When the operation mechanism 130 is rotated to the main circuit insertion position by a main circuit input command or the like, the power transmission shaft 151 rotates in the same direction as the central axis of the operation mechanism 130, that is, clockwise in the drawing. do. As a result, the connecting rod 161 is moved upward and the cam shaft 171 is rotated in the clockwise direction. At this time, the roller 257 of the main circuit link portion 251 in contact with the second section 176b of the cam 175 is pressed and simultaneously moved to the right and lower sides of the drawing. Accordingly, the first operation shaft 181 rotates downward and the second link 255 presses the main circuit contact spring unit 221a downward. The downwardly pressurized rod 225 is moved downward and the movable contact portion 112 of the main circuit switch 110 is moved downward to contact the fixed contact portion 114. When the cam 175 continues to rotate, the roller 257 leaves the second section 176b and contacts the first section 176a as shown in FIG. 13. The link pin 237 is downwardly moved inside the pin hole 227 while the roller 257 is moved, and the contact spring 230 is bushed 234 downwardly with the link pin 237. It is further compressed by the movable contact portion 112 and the fixed contact portion 114 to be in contact with each other at a predetermined pressure or more. In this process, the trip spring 195 is tensioned to accumulate elastic force. On the other hand, when the power transmission shaft 151 is rotated counterclockwise by the operation mechanism 130, the cam shaft 171 is rotated counterclockwise. The main circuit link part 251 and the first operation shaft 181 have accumulated elastic force of the contact spring 230 and the trip spring 195 at the moment when the roller 257 leaves the first section 176a. 12 is rapidly rotated to the initial (neutral) position shown in FIG. 12, whereby the movable contact portion 112 of the main circuit switch 110 is quickly disconnected from the fixed contact portion 114. FIG.

When the central axis of the operating mechanism 130 is rotated counterclockwise at the neutral position of the cam 175, the power transmission shaft 151 is also rotated counterclockwise. The camshaft 171 is rotated counterclockwise, and the roller 267 of the ground circuit link portion 261 in contact with the second section 176b of the cam 175 is pressed by the cam 175 to the outside. And simultaneously moved downward, and the second operation shaft 191 rotates clockwise. Accordingly, the rod 225 of the ground circuit contact spring unit 221b is moved downward and the movable contact portion 122 of the ground circuit switch 120 is in contact with the fixed contact portion 124. As the cam 175 is continuously rotated and the roller 267 is in contact with the first section 176a of the cam 175, the link pin 237 is a pin hole ( 227 is moved downwards and the bush 234 is moved downward to compress the contact spring 230. In this case, the trip spring 195 is tensioned by the rotation of the second operation shaft 191 to accumulate elastic force. On the other hand, when the power transmission shaft 151 is rotated in the clockwise direction by the operating mechanism 130, the cam shaft 171 is rotated in the clockwise direction. When the cam 175 rotates in the clockwise direction and the roller 267 leaves the first section 176a of the cam 175, the contact pressure of the trip spring 195 and the ground circuit contact spring unit 221b is applied. By the elastic force of the spring 230, the second operating shaft 191 is quickly rotated counterclockwise and the rod 230 is quickly moved up. As a result, the movable contact portion 122 of the ground circuit switch 120 is quickly separated from the fixed contact portion 124.

As described above, according to the present invention, the main circuit switch and the ground circuit switch can be smoothly driven by converting the rotational motion of the operation mechanism into a linear motion and transferring the same to the main circuit switch and the ground circuit switch.

In addition, according to the present invention, three phases can be opened and closed collectively using the same axis, thereby increasing stability.

Further, according to the present invention, since the main circuit switch and the ground circuit switch are driven using the same axis, the main circuit switch and the ground circuit switch must be turned off when the main circuit switch and the ground circuit switch are turned on, so that the interlock function is implemented to improve stability. It can be secured.

Claims (7)

A driving force between the main circuit switch for opening and closing the main circuit, a ground circuit switch for opening and closing the ground circuit, and an operation mechanism for operating the main circuit switch and the ground circuit switch in the input, interruption, and ground positions, respectively; As a power transmission device of the high voltage load switchgear for transmitting the main circuit switch and the ground circuit switch, A power transmission shaft having one end connected to the operation mechanism; A cam shaft disposed above the main circuit switch and the ground circuit switch and interlocked with the power transmission shaft and provided with a cam; First and second operating shafts disposed above each of the main circuit switch and the ground circuit switch; A main circuit contact spring unit connected to the movable contact of the main circuit switch; A ground circuit contact spring unit connected to the movable contact portion of the ground circuit switch; A main circuit link portion having a pair of links respectively connected to the first operation shaft and the main circuit contact spring unit, the connecting portion being in contact with one side of the cam; And a pair of links connected to the second operation shaft and the ground circuit contact spring unit, respectively, wherein the connection portion includes a ground circuit link portion in contact with the other side of the cam. The method of claim 1, One end is connected to the power transmission shaft and the other end is a power transmission device of the high voltage load switch, characterized in that it further comprises a connecting rod connected to the cam shaft. The method of claim 2, And the power transmission shaft and the cam shaft are vertically spaced apart from each other and vertically disposed. The method according to any one of claims 1 to 3, And a support frame for supporting the cam shaft and the first and second operating shafts. The method of claim 4, wherein And a trip spring for applying an elastic force such that the first and second operating shafts are rotated to the trip position. The method of claim 5, The first transmission shaft and the second transmission shaft is a power transmission device of the high voltage load switch, characterized in that the spring connection portion is formed is connected to each end of the trip spring. The method of claim 4, wherein The main circuit link unit and the ground circuit link unit is a power transmission device of the high voltage load switchgear characterized in that the rolling contact portion is formed in contact with the cam.

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