KR102495866B1 - A distributing board with isolation - Google Patents

Abstract

According to an embodiment of the present invention, a distributing board with an isolator disposed between the distributing board and the ground to deliver ground vibrations to the distributing board, with the ground vibrations attenuated, comprises: a distributing board body; and the isolator disposed between the ground and the bottom surface of the distributing board body. The isolator includes: an upper connection portion installed on the bottom surface of the distributing board body; a lower connection portion making contact with the ground to support the load of the distributing board body seated on an upper side thereof; and an intermediate portion for joining the upper connection portion and the lower connection portion. The intermediate portion has sliding contact surfaces so that the horizontal movement of the lower connection portion and the horizontal movement of the upper connection portion can be asynchronously linked. Therefore, the distributing board can prevent a sudden movement of the lower connection portion and the impact caused by a sudden change in position from being transmitted to the distributing board body.

Description

A distributing board with isolation}

The present invention relates to a switchgear equipped with a seismic isolator, and more particularly, to a switchgear equipped with a seismic isolator coupled to the lower portion of the switchgear so that vibrations of the ground are attenuated and transmitted to the switchgear.

In a building or factory equipped with power consuming equipment with high power consumption or low power consumption but with a lot of power consuming equipment, high-voltage power of 22,900V is supplied from a substation and converted to commercial power of 220V or 380V.

Power facilities provided in buildings or factories include switchboards that perform a function of receiving and transforming high-voltage power to convert high-voltage power into commercial power, and distributing the high-voltage power to commercial power.

Here, the receiving switchboard may be a high voltage switchboard, a low voltage switchboard, a motor control panel, a distribution board, and the like.

The switchboard has an enclosure shape with a door that can be opened and closed on the front, and various auxiliary modules for receiving and distributing power such as an inlet, an automatic section switch, a lightning arrester, a power fuse, a transformer transformer, an integrated wattmeter, a transformer, a main circuit breaker, and a load circuit breaker are installed inside. there is.

On the other hand, switchgear must always supply commercial power to guarantee the operation of power consuming equipment and emergency operation of fire safety facilities. As the frequency of large and small earthquakes increases due to climate and environmental changes, anti-vibration devices are installed in switchboards to protect power distribution modules in case of earthquakes so that there is no disruption to commercial power supply.

Most of the conventional anti-vibration devices for switchboards have a structure in which an anti-vibration rubber or elastic member is installed between an upper plate fixed to the lower surface of the switchboard main body and a lower plate fixed to the bottom surface, and absorbs and alleviates vibration transmitted to the switchboard through the floor it was sleeping At this time, the vibration includes not only the vibration caused by the earthquake, but also the daily vibration (breaker opening/closing vibration, motor and pump vibration, valve vibration, traffic vibration, transformer vibration, etc.).

However, since the vibration-proof rubber or elastic member is vertically installed between the upper and lower plates, vibration transmitted in the vertical direction can be absorbed to some extent, but vibration transmitted in the horizontal direction cannot be properly absorbed.

Therefore, it is necessary to develop a seismic isolator for switchboards that can safely protect switchboards from earthquakes and facilitate power supply and supply by absorbing and canceling both vibrations acting vertically and horizontally on switchboards.

Korean Patent Registration No. 10-1427879

An object of the present invention is to absorb and offset vibration when an unexpected external force (earthquake, etc.) is applied to the switchgear from the outside, thereby minimizing the conduction of the switchgear or damage/damage of the switchgear caused by the external force, thereby safely protecting the switchgear and An object of the present invention is to provide a switchgear equipped with a seismic isolator capable of smoothly supplying and supplying power.

In a switchboard equipped with a seismic isolator according to an embodiment of the present invention, the switchboard and the switchboard main body are provided with a seismic isolator disposed between the switchboard and the ground so that the vibration of the ground is attenuated and transmitted to the switchboard. and a seismic isolator disposed between a bottom surface of the switchboard body and the ground, wherein the seismic isolator includes an upper connection part installed on the bottom surface of the switchboard body, a lower connection part for supporting a load of the switchboard body seated on the upper side in contact with the ground, and the above It includes an intermediary part that mediates the upper connection part and the lower connection part, and the intermediary part has a sliding contact surface so that the positional movement of the lower connection part in a horizontal direction and the positional movement of the upper connection part in a horizontal direction are interlocked asynchronously. It can be.

The intermediary part of the switchboard equipped with a seismic isolator according to an embodiment of the present invention includes an upper mounting part connected to the bottom surface of the upper connection part, a lower mounting part connected to the upper surface of the lower connection part, and a An upper sliding part formed on the opposite surface and a lower sliding part formed on the opposite surface of the upper mounting part of the lower mounting part and in contact with the upper sliding part, wherein the upper sliding part and the lower sliding part are formed on respective rims When the positions are moved from the basic position in which the edges are arranged side by side to the sliding position in which the respective rims are displaced, they can slide into contact with each other.

The intermediate part of the switchboard equipped with a seismic isolator according to an embodiment of the present invention connects the upper sliding part and the lower sliding part to each other while being connected to the upper mounting part or the lower mounting part, so that the upper sliding part and the lower sliding part are connected to each other. A band portion defining a positional movement limit when the sliding portion is in sliding contact, and the band portion,

When the positions of the upper sliding part and the lower sliding part move from the basic position to the sliding position, they are elastically deformed, and the sliding position may be determined by a critical point of the elastic deformation.

The band portion of the switchboard equipped with a seismic isolator according to an embodiment of the present invention includes a length band piece defining limits of movement of the upper sliding portion and the lower sliding portion in the longitudinal direction, and the upper sliding portion and the lower sliding portion. It is composed of a width band piece that defines a limit of movement of the sliding part in the width direction, and the length band piece and the width band piece can be elastically deformed independently of each other.

The length band piece of the switchboard equipped with a seismic isolator according to an embodiment of the present invention connects the upper sliding part and the lower sliding part while being mounted on the upper mounting part, and the width band piece is connected to the lower mounting part. While being mounted on, it is possible to connect the upper sliding part and the lower sliding part.

The upper mounting portion of the switchboard equipped with a seismic isolator according to an embodiment of the present invention has an upper plate portion formed in a plate shape and an upper band that is fixed with both ends of the length band piece inserted through the upper plate portion. A mounting hole is provided, and the size of both ends of the length band piece is larger than the size of the upper band mounting hole and is dependent on the upper mounting portion, and the lower mounting portion includes a lower plate portion formed in a plate shape and the upper plate portion. A lower band mounting hole is provided in which both ends of the width band piece are inserted and fixed through the lower plate, and the size of both ends of the width band piece is larger than the size of the lower band mounting hole, It can depend on the mounting part.

The length band piece of the switchboard equipped with a seismic isolator according to an embodiment of the present invention mediates the upper sliding part and the lower sliding part, and the length forming part disposed on the lower side of the upper mounting part and the length forming part It is formed larger than the longitudinal cross-sectional area, and is connected to both ends of the length forming part and has an upper hooking part disposed on the upper side of the upper mounting part, and the width band piece mediates the upper sliding part and the lower sliding part, , a width forming part disposed on the upper side of the lower mounting part and a lower hooking part disposed on the lower side of the lower mounting part while being formed larger than the longitudinal cross-sectional area of the width forming part and connected to both ends of the width forming part, respectively. can

The tensile strength of the upper hooking part of the switchgear equipped with the seismic isolator according to an embodiment of the present invention is greater than that of the length forming part, and the tensile strength of the lower hooking part is greater than that of the width forming part. It may be greater than the magnitude of the tensile strength.

The upper sliding part of the switchboard equipped with a seismic isolator according to an embodiment of the present invention is formed at a position corresponding to the first upper band through-hole formed at a position corresponding to the upper band mounting hole and the lower band mounting hole. and a second upper band through hole, wherein the lower sliding part has a first lower band through hole formed at a position corresponding to the upper band mounting hole and a second lower band formed at a position corresponding to the lower band mounting hole. A band through hole is provided, and the length band piece is mounted on the upper mounting part while passing through the first upper band through hole and the first lower band through hole, and the width band piece is connected to the second lower band. It may be mounted on the lower mounting portion while passing through the through hole and the second upper band through hole.

In the switchboard equipped with a seismic isolator according to an embodiment of the present invention, the first upper band through-hole and the second upper band through-hole pass through the upper sliding part to form a closed curve, and the first lower band through-hole penetrates the upper sliding part. The hole and the second lower band through hole may pass through the lower sliding part to form a closed curve.

The first upper band through-hole and the second upper band through-hole of the switchboard equipped with a seismic isolator according to an embodiment of the present invention are formed by being recessed from the rim of the upper sliding part, and the first lower band through-hole And the second lower band through-hole may be formed by being recessed from an edge of the lower sliding part.

The switchboard equipped with a seismic isolator according to an embodiment of the present invention further includes an upper buffer part interposed between the upper mounting part and the upper connection part and a lower buffer part interposed between the lower mounting part and the lower connection part, The upper buffer unit and the lower buffer unit may damp vibration caused by an external force applied in a vertical direction.

The upper buffer part of the switchgear equipped with a seismic isolator according to an embodiment of the present invention is formed by protruding from the upper surface of the upper mounting part, and the upper connection part is formed by being recessed from the bottom surface, and the upper buffer part is formed. The part is inserted into the upper recessed part and interlocks with the upper connection part when an external force is applied in a horizontal direction, the lower buffer part is formed to protrude from the lower surface of the lower mounting part, and the lower connection part is formed to be recessed from the upper surface. A lower recessed portion is formed, and the lower buffer unit is inserted into the lower recessed portion and interlocks with the lower connecting portion when an external force is applied in a horizontal direction.

The switchboard with a seismic isolator according to an embodiment of the present invention further includes an upper magnet part interposed between the upper mounting part and the upper connection part and a lower magnet part interposed between the lower mounting part and the lower connection part, The upper magnet part and the lower magnet part are formed with the same poles so that a repulsive force is applied to each other, and when the upper sliding part and the lower sliding part are in sliding contact, frictional force may be reduced by the repulsive force.

A switchgear with a seismic isolator according to an embodiment of the present invention further includes an electromagnet part disposed between a bottom surface of the switchgear body and the ground and generating attraction or repulsive force by applied power, and the electromagnet part comprises the An upper electromagnet piece installed on the bottom surface of the switchboard main body and a lower electromagnet piece disposed to face the upper electromagnet piece while seated on the ground may be provided.

A switchboard equipped with a seismic isolator according to an embodiment of the present invention is installed on the bottom surface of a switchboard main body, and the vibration sensing unit detects the vibration intensity of the bottom surface and the upper part according to the value detected by the vibration sensing unit. Further comprising a control unit for determining whether the electromagnet piece and the lower electromagnet piece are driven, wherein the control unit is configured to: One side is driven so that mutual attraction acts, and when the vibration intensity detected by the vibration sensing unit is greater than a preset value, the upper electromagnet piece and the lower electromagnet piece may not be driven.

In the switchboard equipped with a seismic isolator according to an embodiment of the present invention, a proximity sensor unit installed at the bottom corner of the switchboard body and detecting a separation distance from the ground, and according to a value detected by the proximity sensor unit, the Further comprising a control unit for determining whether the upper electromagnet piece and the lower electromagnet piece are driven, wherein the control unit, when the value sensed by the proximity sensor unit is out of a preset value range, the upper electromagnet piece and the lower electromagnet By driving the sides so that mutual attraction acts, it is possible to prevent the switchboard body from overturning.

A switchboard equipped with a seismic isolator according to an embodiment of the present invention further includes a wire portion in which tension is changed according to a change in the separation distance between the bottom surface of the switchboard body and the ground while mediating the bottom edge of the switchboard body and the ground, The wire unit may prevent the switchgear body from overturning by defining a distance limit between a bottom edge of the switchgear body and the ground.

The switchboard main body of the switchboard equipped with a seismic isolator according to an embodiment of the present invention includes an enclosure portion forming an accommodation space therein and an installation plate accommodated in the accommodation space and disposed parallel to the inner rear surface of the enclosure unit. And, while being disposed between the enclosure unit and the mounting plate unit, the main body buffer unit may further include a main body buffer unit such that the vibration of the enclosure unit is transmitted to the installation plate unit while being attenuated.

According to the present invention, the lower connection part connected to the ground is immediately interlocked with the ground by an external force applied to the ground in the horizontal direction, but the upper connection part connected through the intermediate part is interlocked with the positional movement of the lower connection part. The position is moved in a buffered state by the shock caused by the rapid positional movement and rapid positional change of the lower connection unit so that it is not transmitted to the main body of the switchgear.

In addition, the seismic isolator of the present invention returns to a preset position when the applied external force (earthquake, etc.) stops, and can stably support the switchgear.

In addition, the seismic isolator of the present invention, by placing a buffer between the upper connection part and the lower connection part, can effectively absorb vibration transmitted in a vertical direction to the switchgear when an earthquake occurs, thereby safely protecting the switchgear.

In addition, in the seismic isolator of the present invention, a repulsive force by a magnet acts between the upper connection portion and the lower connection portion, thereby minimizing friction due to surface contact.

In addition, according to the present invention, an electromagnet unit is placed between the main body of the switchboard and the ground so that the seismic isolation function is activated when an earthquake occurs, and when an earthquake is over, it is used to return the switchboard to a preset position, thereby supporting the switchboard more stably. can

In addition, the seismic isolator of the present invention is applicable to both long-period and short-period earthquakes, and resonance may not occur even in long-period earthquakes. (natural frequency 0.25Hz)

1 is a schematic perspective view showing a switchgear equipped with a seismic isolator according to an embodiment of the present invention;
2 is an exploded perspective view for explaining a seismic isolator according to an embodiment of the present invention;
3 is a schematic diagram for explaining a seismic isolator according to an embodiment of the present invention;
Figure 4 is a schematic diagram for explaining the operation of the seismic isolator according to an embodiment of the present invention.
5 is a schematic view illustrating an upper mounting portion and a lower mounting portion of a seismic isolator according to an embodiment of the present invention.
6 is a schematic diagram for explaining a seismic isolator according to another embodiment of the present invention.
7 is a schematic diagram for explaining a seismic isolator according to another embodiment of the present invention.
8 and 9 are schematic views for explaining a seismic isolator according to another embodiment of the present invention.
10 is a schematic diagram for explaining a seismic isolator according to another embodiment of the present invention.
11 is a schematic diagram for explaining a shock absorbing part of a main body of a seismic isolator according to an embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. However, the spirit of the present invention is not limited to the presented embodiments, and those skilled in the art who understand the spirit of the present invention may add, change, delete, etc. other elements within the scope of the same spirit, through other degenerative inventions or the present invention. Other embodiments included within the scope of the inventive idea can be easily proposed, but it will also be said to be included within the scope of the inventive concept.

In addition, components having the same function within the scope of the same idea appearing in the drawings of each embodiment are described using the same reference numerals.

1 is a schematic perspective view showing a switchboard equipped with a seismic isolator according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view for explaining the seismic isolator according to an embodiment of the present invention.

3 is a schematic diagram for explaining a seismic isolator according to an embodiment of the present invention, and FIG. 4 is a schematic diagram for explaining the operation of the seismic isolator according to an embodiment of the present invention.

And, Figure 5 is a schematic diagram for explaining the upper mounting portion and the lower mounting portion of the seismic isolator according to an embodiment of the present invention.

1 to 5, a switchboard 1 equipped with a seismic isolator according to an embodiment of the present invention is coupled to the lower portion of the switchboard 1 so that the vibration of the ground is attenuated and transmitted to the switchboard It may be a switchgear equipped with a seismic isolator.

A switchgear switchboard according to an embodiment of the present invention may include a switchgear switchboard main body 10 and a seismic isolator 20 disposed between a bottom surface of the switchgear switchboard main body 10 and the ground.

In the drawing, the seismic isolator 20 is formed in a rectangular shape, but it may be circular or a shape including angles and arcs.

The seismic isolator 20 may include an upper connection part 21 , a lower connection part 23 and an intermediate part 25 .

The upper connection part 21 may be installed on the lower surface of the switchgear body 10 .

The lower connection part 23 may support the load of the switchgear main body 10 seated on the upper side in contact with the ground.

The intermediate part 25 may mediate both while being disposed between the upper connection part 21 and the lower connection part 23 .

The intermediary part 25 has a sliding contact surface, so that the positional movement of the lower connection part 23 in the horizontal direction and the positional movement of the upper connection part 21 in the horizontal direction can be interlocked asynchronously.

Specifically, the intermediate portion 25 has a sliding contact surface so that the movement of the lower connection portion 23 in the horizontal direction is not immediately reflected in the movement of the upper connection portion 21 .

Accordingly, the lower connection part 23 is immediately interlocked with the ground by an external force applied to the ground in the horizontal direction, but the upper connection part 21 connected via the intermediate part 25 is the lower connection part 23 ) interlocked with the positional movement, but moved in a buffered state by the intermediate part 25 so that the shock caused by the rapid positional movement and rapid positional change of the lower connection part 23 is not transmitted to the switchgear main body 10. do.

In other words, the upper connection part 21 moves a distance smaller than the position movement distance of the lower connection part 23 and has a position change speed slower than the position change speed of the lower connection part 23 .

The intermediate portion 25 of the seismic isolator 20 according to an embodiment of the present invention includes an upper mounting portion 251, a lower mounting portion 252, an upper sliding portion 253, a lower sliding portion 254, and a band portion 255. ) can be provided.

The upper mounting part 251 may be connected to the lower surface of the upper connecting part 21 .

The lower mounting part 252 may be connected to an upper surface of the lower connecting part 23 .

The upper sliding part 253 may be formed on an opposite surface of the upper mounting part 251 to the lower mounting part 252 .

The lower sliding part 254 is formed on a surface of the lower mounting part 252 facing the upper mounting part 251 and may come into contact with the upper sliding part 253 .

The upper sliding part 253 and the lower sliding part are in a basic position in which the respective edges are arranged side by side (see the upper left drawing in FIG. When the position is moved to (refer to the drawing), mutual sliding contact may be made.

The band part 255 interconnects the upper sliding part 253 and the lower sliding part 254 while being connected to the upper mounting part 251 or the lower mounting part 252, so that the upper sliding part 253 ) and the sliding contact of the lower sliding part 254, a position movement limit may be defined.

The band part 255 is elastically deformed when the upper sliding part 253 and the lower sliding part 254 move from the basic position to the sliding position, and the sliding position is determined by the critical point of the elastic deformation. can be determined.

In addition, the band portion 255 includes a length band piece 255a and the upper sliding portion 253, which define limits of movement of the upper sliding portion 253 and the lower sliding portion 254 in the longitudinal direction. It may be composed of a width band piece 255b that defines a limit of movement of the lower sliding part 254 in the width direction.

The length band piece 255a and the width band piece 255b may be elastically deformed independently of each other.

The length band piece 255a may connect the upper sliding part 253 and the lower sliding part 254 while being mounted on the upper mounting part 251 .

The width band piece 255b may connect the upper sliding part 253 and the lower sliding part 254 while being mounted on the lower mounting part 252 .

On the other hand, the upper mounting part 251 has an upper plate part formed in a plate shape and an upper band mounting hole 251a fixed with both ends of the length band piece 255a inserted through the upper plate part. can be provided

The length band piece 255a may be subordinated to the upper mounting part 251 by having both ends larger than the size of the upper band mounting hole 251a.

The lower mounting portion 252 may include a lower plate portion formed in a plate shape and a lower band mounting hole 252a through which both ends of the width band piece 255b are inserted and fixed through the lower plate portion. can

The width band piece 255b may be subordinated to the lower mounting part 252 by having both ends larger than the size of the lower band mounting hole 252a.

The length band piece 255a may include a length forming part 256 and an upper hooking part 257.

The length forming part 256 mediates the upper sliding part 253 and the lower sliding part 254 and may be disposed on the lower side of the upper mounting part 251 .

The upper hanging part 257 is formed larger than the longitudinal cross-sectional area of the length forming part 256, and is disposed on the upper side of the upper mounting part 251 while being connected to both ends of the length forming part 256, respectively. It can be.

Since the upper hooking part 257 is larger than the size of the upper band mounting hole 251a, both ends of the length forming part 256 depend on the upper plate part by the upper hooking part 257. It can be.

Here, the tensile strength of the upper hooking part 257 may be greater than that of the length forming part 256 .

The width band piece 255b may include a width forming part 258 and a lower hooking part 259 .

The width forming part 258 mediates the upper sliding part 253 and the lower sliding part 254 and may be disposed on an upper side of the lower mounting part 252 .

The lower hooking part 259 is formed larger than the vertical cross-sectional area of the width forming part 258 and is disposed on the lower side of the lower mounting part 252 while being connected to both ends of the width forming part 258. It can be.

Since the lower hooking part 259 is formed larger than the size of the lower band mounting hole 252a, both ends of the width forming part 258 depend on the lower plate part by the lower hooking part 259. It can be.

Here, the tensile strength of the lower hooking part 259 may be greater than that of the width forming part 258 .

Referring to (a) of FIG. 5, the upper sliding part 253 includes a first upper band through hole 253a formed at a position corresponding to the upper band mounting hole 251a and the lower band mounting hole ( 252a) may be provided with a second upper band through-hole 253b formed at a corresponding position.

The lower sliding part 254 includes a first lower band through-hole 254a formed at a position corresponding to the upper band mounting hole 251a and a first lower band through-hole 254a formed at a position corresponding to the lower band mounting hole 252a. 2 lower band through-holes 254b may be provided.

The length band piece 255a may be mounted on the upper mounting portion 251 while passing through the first upper band through hole 253a and the first lower band through hole 254a.

The width band piece 255b may be mounted to the lower mounting portion 252 while passing through the second lower band through-hole 254b and the second upper band through-hole 253b.

The first upper band through hole 253a and the second upper band through hole 253b may pass through the upper sliding part 253 to form a closed curve.

The first lower band through hole 254a and the second lower band through hole 254b may pass through the lower sliding part 254 to form a closed curve.

The first upper band through-hole 253a and the first lower band through-hole 254a are formed to be larger than the cross section of the length-forming part 256, so that when the length-forming part 256 expands and contracts, the plates come into contact with each other. Friction with wealth can be minimized.

In addition, the second upper band through-hole 253b and the second lower band through-hole 254b are formed larger than the cross section of the width forming part 258, so that when the width forming part 258 expands and contracts, Friction with the contacting plate portion can be minimized.

In addition, referring to (b) of FIG. 5, in another embodiment, the first upper band through-hole 253a' and the second upper band through-hole 253b' are the upper sliding part 253' It may be formed by indenting from the rim of.

Also, the first lower band through-hole 254a' and the second lower band through-hole 254b' may be formed by being recessed from an edge of the lower sliding part 254'.

6 is a schematic diagram for explaining a seismic isolator according to another embodiment of the present invention.

Referring to FIG. 6 , a seismic isolator 120 according to another embodiment of the present invention includes an upper buffer part 31 and a lower buffer part 32 in the seismic isolator 20 described with reference to FIGS. 1 to 5 . can include more.

The upper shock absorbing part 31 may be interposed between the upper mounting part 1251 and the upper connecting part 121 .

The lower shock absorbing part 32 may be interposed between the lower mounting part 1252 and the lower connecting part 123 .

The upper shock absorbing part 31 and the lower shock absorbing part 32 may be a rubber material that provides a buffering force by an external force in a vertical direction, a buffer spring, or a wire rope buffer.

Accordingly, the upper shock absorbing part 31 and the lower shock absorbing part 32 can damp vibration caused by an external force applied in the vertical direction.

7 is a schematic diagram for explaining a seismic isolator according to another embodiment of the present invention.

Referring to FIG. 7 , a seismic isolator 220 according to another embodiment of the present invention includes an upper buffer part 31' and a lower buffer part 32' in the seismic isolator 20 described with reference to FIG. 6 . It relates to another embodiment.

The upper shock absorbing part 31' may protrude from the upper surface of the upper mounting part 2251.

Here, the upper connection part 221 may be formed with an upper recessed part 211 formed by being recessed from the bottom surface.

The upper shock absorbing part 31 ′ may be inserted into the upper recessed part 211 and interlock with the upper connecting part 121 when an external force is applied in a horizontal direction.

The height of the upper shock absorbing part 31 may be greater than that of the upper recessed part 211 . Accordingly, a fine separation space is formed between the upper connection part 221 and the upper mounting part 2251, so that a space in which the upper shock absorbing part 31' can be buffered can be provided.

The lower buffer part 32' may protrude from the lower surface of the lower mounting part 2252.

The lower connection part 223 may be formed with a lower recessed part 231 formed by being recessed from the upper surface.

The lower shock absorbing part 32 ′ may be inserted into the lower recessed part 231 and interlock with the lower connecting part 223 when an external force is applied in a horizontal direction.

The height of the lower shock absorbing part 32' may be greater than that of the lower recessed part 231. Accordingly, a fine separation space is formed between the lower connection part 223 and the lower mounting part 2252, thereby providing a space in which the lower buffer part 32' can be buffered.

8 and 9 are schematic diagrams for explaining a seismic isolator according to another embodiment of the present invention.

Referring to FIGS. 8 and 9 , a switchboard equipped with a seismic isolator 20 according to another embodiment of the present invention may further include an electromagnet unit 50 in addition to the switchboard described with reference to FIGS. 1 to 5 . there is.

The electromagnet part 50 is disposed between the bottom surface of the switchgear main body 10 and the ground, and an attractive force or a repulsive force may be generated by the applied power.

The electromagnet part 50 includes an upper electromagnet piece 51 installed on the bottom surface of the switchboard main body 10 and a lower electromagnet piece 52 disposed to face the upper electromagnet piece 51 while seated on the ground. can be provided.

In addition, the switchboard equipped with the seismic isolator 20 may further include a vibration sensor 60 and a control unit 70 .

The vibration sensing unit 60 is installed on the bottom surface of the switchgear main body 10 and can sense the intensity of vibration on the bottom surface.

The control unit 70 may determine whether to drive the upper electromagnet piece 51 and the lower electromagnet piece 52 according to the value detected by the vibration sensing unit 60 .

The control unit 70, when the vibration intensity detected by the vibration sensing unit 60 is less than or equal to a preset value, the upper electromagnet piece 51 and the lower electromagnet piece are driven so that mutual attraction acts. can

In addition, the control unit 70 may prevent the upper electromagnet piece 51 and the lower electromagnet piece from being driven when the vibration intensity detected by the vibration sensing unit 60 is greater than a preset value.

Accordingly, the control unit 70 activates the seismic isolation function when an earthquake occurs (when the vibration intensity detected by the vibration sensing unit 60 is greater than a preset value), and when the earthquake ends (the vibration sensing unit ( When the intensity of the vibration detected by 60) is less than or equal to the preset value), the switchgear can be supported more stably by being used to return the switchgear to the preset position.

In another embodiment, a proximity sensor unit 80 may be used instead of the vibration sensor unit.

The proximity sensor unit 80 is installed at the bottom edge of the switchgear main body 10, and can detect a separation distance from the ground.

Here, the controller 70 may determine whether to drive the upper electromagnet piece 51 and the lower electromagnet piece 52 according to the value sensed by the proximity sensor unit 80 .

The control unit 70, when the value detected by the proximity sensor unit 80 is out of the range of a preset value, the upper electromagnet piece 51 and the lower electromagnet piece 52 are driven so that mutual attraction occurs. By making it work, conduction of the switchgear body 10 can be prevented.

10 is a schematic diagram for explaining a seismic isolator according to another embodiment of the present invention.

Referring to FIG. 10 , a seismic isolator 420 according to another embodiment of the present invention includes an upper magnet part 41 and a lower magnet part 42 in the seismic isolator 20 described with reference to FIGS. 1 to 5 may further include.

The upper magnet part 41 may be interposed between the upper mounting part 4251 and the upper connecting part 421 .

The lower magnet part 42 may be interposed between the lower mounting part 4252 and the lower connecting part 423 .

The upper magnet part 41 and the lower magnet part 42 are formed with the same pole so that a mutual repulsive force can act thereon.

When the upper sliding part 253 and the lower sliding part 254 are in sliding contact, frictional force may be reduced by the repulsive force.

11 is a schematic diagram illustrating a shock absorbing part of a main body of a seismic isolator according to an embodiment of the present invention.

Referring to FIG. 11, the switchboard body 10 of the switchgear switchboard 1 according to an embodiment of the present invention is accommodated in an enclosure 11 forming an accommodation space therein and the accommodation space, and the enclosure unit It may be provided with a mounting plate portion 13 disposed parallel to the inner rear surface of (11).

The switchgear of the present invention may further include a main body buffer unit 90 .

The main body buffer 90 is disposed between the enclosure 11 and the installation plate 13 so that the vibration of the enclosure 11 is transmitted to the installation plate 13 while being attenuated. can do.

The main body buffer unit 90 may be composed of a plurality of buffer springs, one side of each buffer spring is fastened to the inner rear surface of the enclosure unit 11, and the other side is fastened to the installation plate unit 13, , It is formed in the coil spring between one side and the other side, and is formed in a structure that transmits the shock caused by the positional movement of the enclosure part 11 to the installation plate part 13 while the coil spring buffers it.

In the above, the configuration and characteristics of the present invention have been described based on the embodiments according to the present invention, but the present invention is not limited thereto, and various changes or modifications can be made within the spirit and scope of the present invention. It is apparent to those skilled in the art, and therefore such changes or modifications are intended to fall within the scope of the appended claims.

1: switchgear equipped with a seismic isolator
10: switchgear main body 20: seismic isolator
21: upper connection part 23: lower connection part
25: intermediate part 251: upper mounting part
252: lower mounting part 253: upper sliding part
254: lower sliding part 255: band part
31: upper buffer part 32: lower buffer part
41: upper magnet part 42: lower magnet part
50: electromagnet part 51: upper electromagnet piece
52: lower electromagnet piece 60: vibration sensing unit
70: control unit 80: proximity sensor unit
90: body buffer

Claims (16)

In the switchboard equipped with a seismic isolator coupled to the lower part of the switchboard so that the vibration of the ground is attenuated and transmitted to the switchboard,
switchgear body; and
Including; a seismic isolator disposed between the bottom surface of the switchboard body and the ground,
The seismic isolator,
an upper connection part installed on the lower surface of the switchboard main body;
a lower connection portion that supports the load of the switchgear main body seated on the upper side in contact with the ground; and
And a mediating part mediating the upper connection part and the lower connection part.
The mediator,
A sliding contact surface is formed so that the positional movement of the lower connection part in the horizontal direction and the positional movement of the upper connection part in the horizontal direction are asynchronously interlocked,
The mediator,
An upper mounting portion connected to a lower surface of the upper connecting portion;
A lower mounting portion connected to an upper surface of the lower connecting portion;
An upper sliding part formed on a surface of the upper mounting part opposite to the lower mounting part, and
a lower sliding part formed on a surface of the lower mounting part facing the upper mounting part and contacting the upper sliding part;
The upper sliding part and the lower sliding part are in sliding contact with each other when the position is moved from the basic position in which the respective edges are arranged side by side to the sliding position in which the respective edges are displaced,
an upper magnet part interposed between the upper mounting part and the upper connecting part; and
Further comprising a lower magnet portion interposed between the lower mounting portion and the lower connection portion,
The upper magnet part and the lower magnet part,
Formed with the same pole, mutual repulsive force acts,
The upper sliding part and the lower sliding part,
At the time of sliding contact, the frictional force is reduced by the repulsive force,
an upper buffer part interposed between the upper mounting part and the upper connecting part; and
It further includes; a lower buffer part interposed between the lower mounting part and the lower connection part,
The upper buffer part and the lower buffer part,
A switchboard equipped with a seismic isolator, characterized in that it damps vibration caused by an external force applied in a vertical direction.
According to claim 1,
The mediator,
A band portion that interconnects the upper sliding part and the lower sliding part while being connected to the upper mounting part or the lower mounting part, and defines a position movement limit when the upper sliding part and the lower sliding part are in sliding contact,
The band part,
A switchgear equipped with a seismic isolator that is elastically deformed when the upper sliding part and the lower sliding part move from the basic position to the sliding position, and the sliding position is determined by a critical point of the elastic deformation.
According to claim 2,
The band part,
A length band piece defining a limit of positional movement of the upper sliding part and the lower sliding part in the longitudinal direction, and
It is composed of a width band piece that defines a limit of movement of the upper sliding part and the lower sliding part in the width direction,
The switchboard with a seismic isolator, characterized in that the length band piece and the width band piece are elastically deformed independently of each other.
According to claim 3,
The length band piece,
Connecting the upper sliding part and the lower sliding part while being mounted on the upper mounting part,
The width band piece,
A switchboard with a seismic isolator, characterized in that the upper sliding part and the lower sliding part are connected while being mounted on the lower mounting part.
According to claim 4,
The upper mounting part,
An upper plate portion formed in a plate shape and an upper band mounting hole in which both ends of the length band piece are inserted and fixed through the upper plate portion,
The length band piece,
The size of both ends is formed larger than the size of the upper band mounting hole, and is dependent on the upper mounting part,
The lower mounting part,
A lower plate portion formed in a plate shape and a lower band mounting hole in which both ends of the width band piece are inserted and fixed through the lower plate portion,
The width band piece,
A switchboard with a seismic isolator, characterized in that the size of both ends is larger than the size of the lower band mounting hole and is dependent on the lower mounting part.
According to claim 5,
The length band piece,
It mediates the upper sliding part and the lower sliding part, and is formed larger than the longitudinal sectional area of the length forming part and the length forming part disposed on the lower side of the upper mounting part, and is connected to both ends of the length forming part, respectively, while the upper mounting part An upper engaging portion disposed on the upper side of the,
The width band piece,
The upper sliding part and the lower sliding part are interposed, and the width forming part disposed on the upper side of the lower mounting part is formed larger than the longitudinal sectional area of the width forming part, and the lower mounting part is connected to both ends of the width forming part, respectively. A switchboard with a seismic isolator, characterized in that it includes a lower hooking part disposed on the lower side of the.
According to claim 6,
The magnitude of the tensile strength of the upper hooking portion is greater than the magnitude of the tensile strength of the length forming portion,
A switchboard with a seismic isolator, characterized in that the tensile strength of the lower hanging part is greater than that of the width forming part.
According to claim 5,
The upper sliding part,
A first upper band through-hole formed at a position corresponding to the upper band mounting hole and a second upper band through-hole formed at a position corresponding to the lower band mounting hole,
The lower sliding part,
A first lower band through-hole formed at a position corresponding to the upper band mounting hole and a second lower band through-hole formed at a position corresponding to the lower band mounting hole,
The length band piece,
It is mounted on the upper mounting portion while passing through the first upper band through-hole and the first lower band through-hole,
The width band piece,
A switchboard with a seismic isolator, characterized in that it is mounted on the lower mounting portion while passing through the second lower band through-hole and the second upper band through-hole.
According to claim 8,
The first upper band through-hole and the second upper band through-hole,
Penetrating the upper sliding part to form a closed curve,
The first lower band through-hole and the second lower band through-hole,
A switchboard equipped with a seismic isolator, characterized in that the lower sliding part penetrates to form a closed curve.
According to claim 8,
The first upper band through-hole and the second upper band through-hole,
It is formed by being indented from the rim of the upper sliding part,
The first lower band through-hole and the second lower band through-hole,
A switchboard with a seismic isolator, characterized in that it is formed by being recessed from the edge of the lower sliding part.
delete According to claim 1,
The upper buffer part,
It is formed by protruding from the upper surface of the upper mounting portion,
The upper connection part is formed with an upper recessed part formed by being recessed from the bottom surface,
The upper buffer unit is inserted into the upper recessed portion and interlocks with the upper connection unit when an external force is applied in a horizontal direction,
The lower buffer unit,
It is formed by protruding from the lower surface of the lower mounting portion,
The lower connection part is formed with a lower recessed part formed by being recessed from the upper surface,
The switchboard with a seismic isolator is characterized in that the lower shock absorber is inserted into the lower recessed part and interlocks with the lower connection part when an external force is applied in a horizontal direction.
According to claim 1,
It further includes an electromagnet unit disposed between the bottom surface of the switchboard main body and the ground and generating attraction or repulsive force by the applied power,
The electromagnet part,
An upper electromagnet piece installed on the lower surface of the switchboard body and
A switchboard with a seismic isolator, characterized in that it includes a lower electromagnet piece disposed to face the upper electromagnet piece while being seated on the ground.
According to claim 13,
A vibration sensing unit installed on the bottom surface of the switchboard main body and sensing the intensity of vibration on the bottom surface; and
Further comprising a control unit for determining whether to drive the upper electromagnet piece and the lower electromagnet piece according to the value detected by the vibration sensor,
The control unit,
When the intensity of the vibration detected by the vibration sensor is less than or equal to a preset value, the upper electromagnet piece and the lower electromagnet piece are driven so that mutual attraction acts,
A switchboard equipped with a seismic isolator, characterized in that the upper electromagnet piece and the lower electromagnet piece are not driven when the intensity of the vibration sensed by the vibration sensor is greater than a preset value.
According to claim 13,
A proximity sensor unit installed at the bottom edge of the switchgear main body to detect a separation distance from the ground; and
Further comprising a control unit for determining whether the upper electromagnet piece and the lower electromagnet piece are driven according to the value detected by the proximity sensor unit,
The control unit,
When the value sensed by the proximity sensor unit is out of the range of the preset value, the upper electromagnet piece and the lower electromagnet piece are driven so that mutual attraction acts, thereby preventing the switchboard main body from conduction. A switchboard equipped with a device.
According to claim 1,
The body of the switchboard,
An enclosure portion forming an accommodation space therein and a mounting plate portion accommodated in the accommodation space and arranged parallel to the inner rear surface of the enclosure unit,
The switchgear further comprises a main body shock absorbing unit disposed between the enclosure unit and the installation plate unit so that the vibration of the enclosure unit is transmitted to the installation board unit while being attenuated.

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