KR101349616B1 - Earthquake-proofing switchboard - Google Patents

Abstract

The present invention relates to an earthquake-proof distribution board. The purpose of the present invention is to provide the earthquake-proof distribution board capable of preventing damage to components comprising the distribution board or preventing the distribution board from being overturned by reducing vibrations transmitted to a case by operating a vibration-proof unit formed on the lower side of the case with regard to the vibrations from the outside. [Reference numerals] (AA) X-axis; (BB) Y-axis

Description

Earthquake-proof switchboard {Earthquake-proofing switchboard}

The present invention relates to a switchboard, and more particularly, to prevent damage to the switchboard due to seismic waves by relieving the vibration transmitted to the enclosure while the dustproof unit provided at the lower end of the housing by the vibration transmitted from the outside. It is about a true switchgear.

In general, apartment houses for residential purposes, apartments for buildings, schools for education, and factories with a large number of facilities for production are used to receive high voltage power from power transmission lines and convert them into low voltage transformers. Switchboards for distributing power to various electrical equipment systems are installed.

The switchboard is composed of a plurality of devices such as stabilizers, instruments, indicators, relays, switchgear installed inside the enclosure, the bottom of the enclosure is fixed as anchor bolts on the ground or the floor of the building.

Thus, because the switchboard is fixed to the ground or building by anchor bolts, when an earthquake occurs, vibrations are transmitted directly to the switchboard, which may cause deformation of the enclosure, damage to various electrical equipment installed inside the enclosure, or severe collapse of the switchboard. have.

In this case, it is impossible to stably supply power where power is needed, and there are problems such as an electric shock due to a short circuit.

Accordingly, when an earthquake occurs, seismic waves are absorbed so that the switchgear enclosure is not deformed, the internal electrical equipment is not damaged, and the seismic isolating switchgear that can prevent safety accidents such as a short circuit or fire by preventing the switchboard from falling over is required. It is becoming.

For the construction of such a quake-type switchgear, a dustproof pad or a dustproof spring is installed on the bottom of the enclosure to absorb and mitigate vibration.

However, since the vibration pads and the vibration springs have a small amplitude of the waves that can buffer them and mainly absorb vertical vibration, there is a problem in protecting the switchboard from seismic waves vibrating greatly from side to side.

Republic of Korea Patent Publication No. 1139226 (2012.04.26)

The present invention has been made in consideration of the above problems, and an object of the present invention is to reduce the vibration transmitted to the enclosure while the dustproof unit provided at the lower end of the enclosure against the vibration transmitted from the outside, thereby constituting the switchboard It is to provide a base isolation type switchgear that can prevent breakage of the switchboard and overturning of the switchgear.

The present invention to achieve the object as described above and to perform the problem for eliminating the drawbacks of the prior art is an enclosure that is installed inside the device constituting the switchboard; An upper plate fixed to the bottom of the enclosure; A base plate positioned below the upper plate while being spaced apart from the upper plate by a predetermined distance, and fixed to the ground of the ground or building on which the switchboard is installed, and moving along with the ground; And connecting the upper plate and the base plate, and when the seismic wave or the external shock wave is transmitted to the base plate, the upper plate and the housing vibrate by connecting the upper plate and the base plate so that the base plate moves in a direction corresponding to the vibration direction. The dustproof unit is configured to include, wherein the dustproof unit is configured on the bottom surface of the upper plate and behaves to allow the base plate to move in the left and right directions, the gas or the elastic body during the horizontal movement of the base plate An X-axis dustproof unit having a first damper that compresses and generates a buffer force; And a second damper configured on an upper surface of the base plate and connected to the X-axis dustproof unit to allow the base plate to move in the front and rear directions, compressing the gas or the elastic body during the forward and backward movement of the base plate, and generating a buffering force. It provides a base isolation switchgear comprising a; Y-axis dustproof unit provided.

On the other hand, it is preferable that a cushion block is further installed between the X-axis dustproof unit and the Y-axis dustproof unit.

On the other hand, the X-axis dustproof unit, coupled to the Y-axis dustproof unit and the first block to move in the left and right direction with the Y-axis dustproof unit, and is fixedly installed on the upper plate to have a structure extending in the left and right A first LM guide coupled to the first block, the first LM guide including a first rail supporting a lateral movement of the first block; And a first slide body coupled to the first block and moving together with the first block, and having a structure extending in the horizontal direction through the first slide body, both ends of which are fixed to the upper plate and filled with air therein. And a first rodless cylinder which is formed by a first cylinder tube having a first piston coupled to the first slide body and a magnetic force and moving together with the first slide body to form the first damper.

In this case, the first damper is composed of two first rodless cylinders, the two first rodless cylinders are arranged to be located on both sides of the first LM guide, respectively, the two first rodless cylinders by a connecting pipe Interconnected and configured to share internal air.

On the other hand, the Y-axis dustproof unit is fixed to the base plate so as to have a structure extending in the front and rear direction, the second rail moving in the front and rear direction with the base plate, and coupled to the X-axis dustproof unit in the left and right directions A second LM guide having a moving structure and composed of a second block coupled to the second rail to support the forward and backward movement of the second rail; And a second slide body coupled to the second block and moving together with the second block, and having a structure extending in the front-rear direction through the second slide body, both ends of which are fixed to the base plate and filled with air therein. And a second rodless cylinder having a second cylinder tube having a second piston which is bound by a second slide body and a magnetic force to form a second damper.

In this case, the second damper is composed of two second rodless cylinders, the two second rodless cylinders are arranged to be located on both sides of the second LM guide, respectively, the two second rodless cylinders Interconnected by means of sharing internal air.

According to the present invention having the above characteristics, when the vibration caused by an earthquake or explosion accident around the switchboard is transmitted to the switchboard, the cushion block provided between the X-axis vibration unit and the Y-axis vibration unit for the vibration in the vertical direction Absorbs the vibration to alleviate the vibration transmitted to the switchboard, and the base plate is moved in the vibration direction by the X-axis dustproof unit and the Y-axis dustproof unit with respect to the vibration in the horizontal direction. Since the damper provided in the Y-axis dustproof unit reduces vibration while compressing air or an elastic body, there is an effect of preventing damage or overturning of the switchboard due to vibration or shock transmitted from the outside.

1 is a front view showing the structure of a switchboard according to a preferred embodiment of the present invention;
Figure 2 is a perspective view showing the structure of the dustproof unit according to the present invention,
3 is a front view showing the structure of the dustproof unit according to the present invention;
Figure 4 is a side view showing the structure of the dustproof unit according to the present invention,
5 is a perspective view showing a state in which the upper plate is removed in a perspective view of the dustproof unit according to the present invention;
6 is a cross-sectional view taken along line AA ′ of FIG. 4;
7 is a cross-sectional view taken along line BB ′ of FIG. 4;
8 is a perspective view showing a coupling structure of the X-axis dustproof unit and the Y-axis dustproof unit according to the present invention;
9 is a perspective view showing a state in which the upper plate is moved in the front and rear directions by the Y-axis dustproof unit,
10 is a perspective view showing a state in which the upper plate is moved in a diagonal direction by the X-axis dustproof unit and the Y-axis dustproof unit.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a front view showing the structure of a switchboard according to a preferred embodiment of the present invention.

The seismic isolation switchboard according to the present invention is configured to additionally configure the dustproof unit 200 at the lower end of the enclosure 100 installed inside the various devices constituting the switchboard to mitigate the vibration transmitted to the enclosure 100 from the outside. In addition, the dustproof unit 200 has a characteristic of gradually mitigating the vibration transmitted to the enclosure 100 while acting on vibrations such as earthquake waves or shock waves transmitted through the floor where the switchboard is installed. Meanwhile, in order to enable the dustproof unit 200 to support the enclosure 100 more stably, the plurality of dustproof units 2000 may be configured to support one enclosure 100.

The seismic isolation switchboard according to the present invention for implementing the above features is configured to include a housing 100, an upper plate 210, a base plate 220, and a dustproof unit 200.

The enclosure 100 is a case in which various devices constituting the switchboard are installed. The enclosure 100 and the devices installed inside the enclosure 100 may not only be configured in various structures, but also widely used switchboards. The same structure as that of bar, the detailed description of the housing 100 and the devices installed inside the housing will be omitted.

The upper plate 210 is fixedly installed on the bottom of the housing 100.

The base plate 220 is fixedly installed on the ground or the floor of the building is installed switchboard. The base plate 220 is disposed to have a structure spaced apart from the upper plate 210 at a predetermined lower portion of the upper plate 210 by a predetermined distance.

2 is a perspective view showing the structure of the dustproof unit according to the invention, Figure 3 is a front view showing the structure of the dustproof unit according to the invention, Figure 4 is a side view showing the structure of the dustproof unit according to the invention, Figure 5 Figure 6 is a perspective view showing a state of removing the upper plate in a perspective view of the dustproof unit according to the invention, Figure 6 is a cross-sectional view taken along line AA` of Figure 4, Figure 7 is a cross-sectional view taken along line BB` of Figure 4, Is a perspective view showing a coupling structure of the X-axis dustproof unit and the Y-axis dustproof unit according to the present invention.

The above-mentioned dustproof unit 200 is a structure in which the X-axis dustproof unit 230 and the Y-axis dustproof unit 240 are assembled.

The dustproof unit 200 is installed between the upper plate 210 and the base plate 220 to connect the upper plate 210 and the base plate 220, the earthquake plate or shock wave is transmitted to the base plate 220 When the base plate 220 is moved in a direction that conforms to the vibration direction, that is, it moves with the ground in which the switchboard is installed, the upper plate 210 and the upper plate 210 and the base plate 220 to maintain in place By implementing the relative motion between the, to alleviate the vibration transmitted to the upper plate (210).

The X-axis dustproof unit 230 is to move the base plate 220 in the left and right directions (D1) by the vibration transmitted from the outside, is installed below the upper plate 210, the left and right directions (D1) It has a structure that generates a buffer force while compressing air or an elastic body during the movement. Meanwhile, the left and right directions D1 are directions parallel to the X axis.

The X-axis dustproof unit 230 is composed of a first LM guide 231 and a first damper 232.

The first LM guide 231 is coupled to the Y-axis dustproof unit 240 and moved together with the Y-axis dustproof unit 240 in the left and right directions D1 and the first block 2311. ) Is coupled to the first rail 2312 fixedly installed on the bottom surface of the upper plate 210 to have a structure extending in the left and right direction (D1) to support the left and right direction (D1) movement of the first block (2311). It consists of. For reference, a plurality of balls (not shown) are installed inside the first block 2311, and the balls are disposed between the first block and the first rail by the first block 2311 and the first rail 2312. This reduces the resistance generated. Since the LM guide having such a structure is already widely used, the first LM guide 231 may be configured using the known LM guide, and thus a detailed description of the structure of the first LM guide 231 is omitted. do.

The first damper 232 is to slowly relieve vibration while compressing an elastic body or air, such as a spring, in the process of the X-axis dustproof unit 230 to allow movement of the base plate 220 in the left and right directions (D1). . The first damper 232 may be composed of a known rodless cylinder.

More specifically, the first damper 232 may be coupled to the first block 2311 of the first LM guide 231 and behave together with the first block 2311. It consists of a 1st rodless cylinder 232 'comprised of the 1st cylinder tube 2232 which penetrates the 1st slide body 2321, and extends in the left-right direction D1.

On the other hand, the first cylinder tube 2232 is filled with air at a predetermined pressure, the first piston is coupled to the first slide body 2321 by a magnetic force and behaves together with the first slide body 2321. 2323 is provided, and both ends of the first cylinder tube 2232 are directly or indirectly fixed to the upper plate 210.

As such, the first rodless cylinder 232 ′ constituting the first damper 232 is disposed to have a structure parallel to the first LM guide 231 at a position adjacent to the first LM guide 231. Is composed of two so that the first rodless cylinder (232`) is located on both sides of the first LM guide (231).

As such, the first rodless cylinder 232` consisting of two is configured so that both ends thereof are interconnected by a connecting pipe 2324 to share internal air, and the connecting pipe 2324 is an air distributor 250 if necessary. It is connected to and configured to receive air replenishment. As described above, in connecting the connection pipe 2324 to the air distributor 250, the check valve 2325 is connected to the connection pipe 2324 to prevent the air of the first rodless cylinder 232 ′ from being discharged to the air distributor 250. ) Is installed.

When the vibration of the first rodless cylinder 232 ′ configured as described above is transmitted to the base plate 220 in a direction parallel to the left and right directions D1, the first slide body 2321 is the first block 2311. In addition, the left and right direction (D1) of the base plate 220 is allowed to move while moving in the left and right direction (D1), and in this process, the first piston (2323) bound by the first slide body (2321) by magnetic force is Since the inside of the first cylinder tube 2232 is moved and the air is compressed, vibration is alleviated.

The Y-axis dustproof unit 240 is to move the base plate 220 in the front and rear direction (D2) by the vibration transmitted from the outside, is installed on the base plate 220, the X-axis dustproof unit ( It is coupled to 230, and has a structure for generating a buffer force while compressing air or an elastic body during movement in the front and rear direction (D2). Meanwhile, the front-rear direction D2 is a direction parallel to the Y axis.

The Y-axis dustproof unit 240 includes a second LM guide 241 and a second damper 242.

The second LM guide 241 is fixed to the upper surface of the base plate 220 to have a structure extending in the front and rear direction (D2) and the second rail (2412) moving together with the base plate 220, and The second coupled to the X-axis dustproof unit 230 has a structure to move in the left and right direction (D1), and coupled to the second rail 2412 to support the forward and backward direction (D2) movement of the second rail (2412) Block 2411. In this way, a plurality of balls are installed inside the second block 2411 constituting the second LM guide 241, and the balls are positioned between the second rail 2412 and the second block 2411 to form a second ball. The frictional resistance generated between the rail 2412 and the second block 2411 is reduced.

Meanwhile, a cushion block 260 is installed between the first block 2311 and the second block 2411, and the cushion block 260 is an X-axis dustproof unit 230 from the Y-axis dustproof unit 240. The vertical direction transmitted to the vibration will be alleviated.

In order to install the cushion block 260, an upper fixing block 261 is installed at a lower portion of the first block 2311, and a lower fixing block 262 is installed at an upper portion of the second block 2411. The cushion block 260 is installed between the block 261 and the lower fixing block 262.

Meanwhile, the upper fixing block 261 is coupled to the first slide body 2321 of the first rodless cylinder 232 ′ constituting the first damper 232. Accordingly, the first block 2311, the upper fixing block 261, and the first slide body 2321 may move together while forming one assembly.

Similarly, the second fixed body 2421 of the second rodless cylinder 242 ′ of the lower fixing block 262 is coupled with the second slide body 2421. Accordingly, the second block 2411, the lower fixing block 262, and the second slide body 2421 form one assembly and behave together.

The second damper 242 is to gradually relieve vibration while compressing an elastic body or air, such as a spring, in the process of allowing the Y-axis dustproof unit 240 to move forward and backward (D2) of the base plate 220. . The second damper 242 may be composed of a known rodless cylinder.

More specifically, the second damper 242 may be coupled to the second block 2411 of the second LM guide 241 and behave together with the second block 2411. It consists of the 2nd rodless cylinder 242 'comprised by the 2nd cylinder tube 2422 penetrating the 2nd slide body 2421 and extending in the front-back direction D2.

On the other hand, the second cylinder tube 2422 is filled with air at a predetermined pressure, the second piston which is bound by the second slide body 2421 by a magnetic force and moves together with the second slide body 2421 2423 is provided, and both ends of the second cylinder tube 2422 are fixed to the base plate 220.

As such, the second rodless cylinder 242` constituting the second damper 242 is disposed to have a structure parallel to the second LM guide 241 at a position adjacent to the second LM guide 241, and Is composed of two so that the second rodless cylinder 242` is located on both sides of the second LM guide 241.

Thus, the second rodless cylinder 242` consisting of two is configured so that both ends thereof are interconnected by the connecting tube 2424 to share the internal air, and the connecting tube 2424 is an air distributor 250 if necessary. It is connected to and configured to receive air replenishment. In this way, in connecting the connection tube 2424 to the air distributor 250, the check tube 2425 is connected to the connection tube 2424 to prevent the air of the second rodless cylinder 242 ′ from being discharged to the air distributor 250. ) Is installed.

The second rodless cylinder 242 ′ configured as described above has the second cylinder tube 2422 and the base plate 220 when the vibration in the direction parallel to the front-rear direction D2 is transmitted to the base plate 220. Together, they move in the front-rear direction D2. Meanwhile, when the second slide body 2421 coupled to the second cylinder tube 2422 is coupled to the first block 2311 through the second block 2411, the base plate 220 moves forward and backward D2. Together, it does not move in the front-rear direction D2 and maintains its position. Accordingly, the second piston 2423, which is bound by the second slide body 2421 by magnetic force, is held in place irrespective of the forward and backward direction D2 of the second cylinder tube 2422. The air filled in 2422 is compressed by the second piston 2423 to mitigate vibration.

When the vibration is transmitted due to an earthquake or an explosion accident around the seismic isolation switchboard of the present invention configured as described above, the vertical vibration is a cushion installed between the X-axis vibration unit 230 and the Y-axis vibration unit 240 Block 260 absorbs the vibration to reduce the vibration transmitted to the enclosure (100).

On the other hand, with respect to the horizontal vibration, the base plate 220 is moved in a direction that conforms to the vibration direction, wherein the X-axis dustproof unit 230 and the Y-axis dustproof unit 240 is the behavior of the base plate 220 as described above To allow horizontal vibrations to be reduced to the upper plate 210 and the enclosure 100.

On the other hand, the behavior of the base plate 220 is to be implemented by moving in the left and right direction (D1) or front and rear direction (D2) by any one of the dustproof unit of the X-axis dustproof unit 230 and Y-axis dustproof unit 240. Alternatively, the X-axis dustproof unit 230 and the Y-axis dustproof unit 240 may be implemented by moving in a diagonal direction while operating together.

Therefore, even when the vibration is transmitted in any direction, it is possible to respond by the two dustproof units. For reference, FIG. 9 illustrates a state in which the base plate 220 is moved forward by the Y-axis dustproof unit 240, and in FIG. 10 by the X-axis dustproof unit 230 and the Y-axis dustproof unit 240. FIG. The state in which the base plate 220 is moved in the diagonal direction is shown.

In the movement of the base plate 220 as described above, the rodless cylinders provided in each of the dustproof units 230 and 240 may gradually relieve vibration while the air filled therein is compressed.

As described above, the seismic isolating switchgear according to the present invention has the main apparatuses installed as the base plate 220 behaves in place of the upper plate 210 and the housing 100 within the range allowed by the dustproof unit against the vibration in the horizontal direction. The 100 can be prevented from flowing by the seismic wave, and thus it is possible to more effectively prevent the switchboard from being damaged or overturned even during an earthquake.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

Description of the Related Art
100: enclosure 210: upper plate
220: base plate 230: X axis dustproof unit
231: First LM Guide 2311: First block
2312: first rail 232: first damper
232`: 1st rodless cylinder 2321: 1st slide body
2322: first cylinder tube 2323: first piston
2324 connector 240 Y-axis dustproof unit
241: second LM Guide 2411: second block
2412: second rail 242: second damper
242`: 2nd rodless cylinder 2421: 2nd slide body
2422: second cylinder tube 2423: second piston
2424: connector 260: cushion block

Claims (6)

The housing 100 is installed inside the device constituting the switchboard;
An upper plate 210 fixed to the bottom of the enclosure 100;
A base plate 220 positioned at a lower portion of the upper plate 210 spaced apart from the upper plate 210 by a predetermined distance, and fixed to a ground of a ground or a building on which a switchboard is installed and behaving together with the ground; And
The upper plate 210 and the base plate 220 are connected to each other, but when an earthquake wave or an external shock wave is transmitted to the base plate 220, the upper plate 210 moves in a direction corresponding to the vibration direction. It is configured to include; and a dustproof unit 200 for connecting the base plate 220 and the upper plate 210 and the housing 100 to suppress the vibrations.
The dustproof unit 200,
Is configured on the bottom of the upper plate 210 and behaves to allow the base plate 220 to move in the left and right direction (D1), while compressing the gas or elastic body during the movement of the base plate 220 in the left and right direction (D1) and buffering force X-axis dustproof unit 230 is provided with a first damper 232 for generating a; And
Is configured on the upper surface of the base plate 220 and connected to the X-axis dustproof unit 230 and behaves to allow the base plate 220 to move in the front and rear direction (D2), the front and rear directions of the base plate 220 ( D2) Y-axis dustproof unit 240 is provided with a second damper (242) for compressing the gas or the elastic body during movement to generate a buffer force. The method according to claim 1,
A seismic isolation switchboard, characterized in that the cushion block 260 is installed between the X-axis dustproof unit 230 and the Y-axis dustproof unit 240. The method according to claim 1, wherein the X-axis dustproof unit 230,
The upper plate is coupled to the Y-axis dustproof unit 240 and has a structure extending in the left-right direction D1 and the first block 2311 moving in the left-right direction D1 together with the Y-axis dustproof unit 240. A first LM guide 231 fixedly installed at 210 and configured with a first rail 2312 coupled to the first block 2311 to support a left-right direction D1 movement of the first block 2311; And
A first slide body 2321 that is coupled to and fixed to the first block 2311 and moves together with the first block 2311, and extends in the left and right directions D1 through the first slide body 2321. Both ends are fixed to the upper plate 210 and the air is filled therein, and the first piston 2323 which is bound by the first slide body 2321 and magnetic force and moves together with the first slide body 2321 is provided. And a first rodless cylinder (232 ′) configured to include a first cylinder tube (2322) provided to form the first damper (232). The method according to claim 3,
The first damper 232 is composed of two first rodless cylinders (232`), the two first rodless cylinders (232`) are arranged to be located on both sides of the first LM guide 231, respectively And two first rodless cylinders 232 ′ are interconnected by a connector tube 2324 to share internal air. The method according to claim 1, wherein the Y-axis dustproof unit 240,
A second rail 2412 fixed to the base plate 220 so as to have a structure extending in the front-rear direction D2 and moving in the front-rear direction D2 together with the base plate 220, and the X-axis dustproof unit The second block 2411 coupled to the 230 has a structure moving in the left and right direction D1 and coupled to the second rail 2412 to support the forward and backward direction D2 of the second rail 2412. A second LM guide 241 consisting of; And
A second slide body 2421 coupled to the second block 2411 and moving together with the second block 2411, and a structure extending through the second slide body 2421 and extending in the front-rear direction D2. And a second cylinder tube 2422 having both ends fixed to the base plate 220 and filled with air, and having a second piston 2423 coupled to the second slide body 2421 by magnetic force. And a second rodless cylinder (242 ′) configured to form a second damper (242). The method according to claim 5,
The second damper 242 is composed of two second rodless cylinders 242 ′, and the two second rodless cylinders 242 ′ are disposed on both sides of the second LM guide 231, respectively. And, the second rodless cylinders 242` are interconnected by a connecting pipe 2424 to share internal air.

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