KR101742301B1 - The Distribution Board With Vibration isolation and Earthquake-proof Device - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an electric distribution board having an isolation and an earthquake-proof device for attenuating vibration or shock transmitted from a ground on which an electric distribution board is installed, and more particularly, It is possible to prevent the connection failure or malfunction inside the switchboard caused by the weak vibration or shock which is repeatedly and continuously transmitted for a long period of time even when the earthquake does not occur in the case where the earthquake occurs, It is possible to prevent the switchboard from being twisted or tilted by the influence of the strong vibration or impact caused by the fluctuation and to reduce the cost and manpower required for maintaining the inactivated state of the normal earthquake- Equipped with an earthquake-proof device that is easy to manufacture and install Regarding the switchboard,
The switchboard having the seismic isolation device according to the present invention is coupled to the lower surface of the cabinet 70 of the switchboard so as to absorb the seismic waves flowing from the installation surface and to transmit the vibration or impact of the seismic waves to the switchboard enclosure 70, An upper fixed plate (10) formed of a metal material magnetized by a magnetic body upon contact with the magnet, and a lower surface fixedly coupled to the mounting surface; And the mechanical magnetic body change-over switch 22 is provided so that the side face of the magnetic body change-over switch 22 is in close contact with one side face of the lower fixed plate 10, And a mechanical magnetic body transformer (22) for magnetizing the lower fixing plate (10), which is in close contact with the side face, with a magnetic body when the mechanical magnetic body change-over switch (22) is moved to an on position and converted into a magnetic body, (20); An intermediate movable plate 30 formed of a metal material influenced by a magnetic force and positioned on the upper side of the lower fixing plate 10 and having a lower spherical surface groove 31 formed at the center of the upper surface thereof; The upper end is fixedly coupled to the lower surface of the intermediate movable plate 30 and the lower end is fixedly coupled to the upper surface of the lower fixed plate 10 to elastically support the intermediate movable plate 30. [ A first resilient support (50); The upper portion of the upper movable plate 30 is fixed to the lower surface of the cabinet 70 by a predetermined distance from the upper side of the intermediate movable plate 30, An upper movable plate (40) on which the first movable plate (41) is formed; A steel ball 60 interposed between the lower spherical groove 31 and the upper spherical groove 41 so as to be movable along respective spherical surfaces of the lower spherical groove 31 and the upper spherical groove 41; And a plurality of second resilient supporting portions (51) fixed to the upper surface of the upper movable plate (40) and fixed to the upper surface of the intermediate movable plate (30) .

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a distribution board with vibration isolating and earthquake-

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an electric distribution board having an isolation and an earthquake-proof device for attenuating vibration or shock transmitted from a ground on which an electric distribution board is installed, and more particularly, It is possible to prevent the connection failure or malfunction inside the switchboard caused by the weak vibration or shock which is repeatedly and continuously transmitted for a long period of time even when the earthquake does not occur in the case where the earthquake occurs, It is possible to prevent the switchboard from being twisted or tilted by the influence of the strong vibration or impact caused by the fluctuation and to reduce the cost and manpower required for maintaining the inactivated state of the normal earthquake- Equipped with an earthquake-proof device that is easy to manufacture and install Quot;

In general, switchgear is an electric facility that supplies industrial power to users safely. It is a device used to monitor, control, and protect electrical systems when power is supplied from power plants or substations to consumers.

Such a switchboard is composed of a structure for attaching and supporting unit devices such as a breaker or a protective relay, and a collection of conductors for connecting and connecting the unit devices, and these various electrical appliances are safely insulated and housed in a rectangular steel housing .

Various unit electrical equipments included in the enclosure of the switchboard are very vulnerable to vibration, so they should be designed to minimize vibration transmitted to the switchboard. However, Since it is not installed in seismic isolation and vibration proof design, there is a problem that the vibration transmitted from the outside is directly transmitted and shocked. In connection with the imposition of seismic and seismic design for power facilities, seismic and seismic design for transmission and distribution are essential .

As shown in FIG. 1, the upper plate 110, which is coupled to the lower surface of the housing of the cab of the switchgear, A spring plate 130, a support plate 140 and a ball 150 are stacked in a spaced space between the lower plate 120 and the lower plate 120 fixed to the mounting surface. In a normal state in which no earthquake occurs, The upper plate 110 and the lower plate 120 are tightly fixed to each other to fix and support the cabinet. When an earthquake occurs, the vacuum state of the space is released, and air The upper plate 110 and the lower plate 120 are separated from each other so that the upper plate 110 and the lower plate 120 are separated from each other by the spring 130 and the ball 150, Although it is configured to attenuate the transmission of one vibration,

There is a problem in that the apparatus is structured such that an expensive high-capacity air suction device is required to realize a vacuum state of the spacing space in which the upper plate 110 and the lower plate 120 are tightly fixed,

Even if the vacuum state of the spacing space is realized so that the upper plate 110 and the lower plate 120 can be tightly fixed to each other, And the lower plate 120, so that it is difficult to firmly support the enclosure of the server and the maintenance of the enclosure.

In order to solve this problem, as shown in FIG. 2, in a normal state in which no earthquake occurs, the lower air charging part 132 and the upper air charging part 132 And the lower plate 151 and the upper plate 154 are fixedly supported by filling the air charging part 152 with high pressure air so as to fix and support the plurality of elastic supporting parts 140 at the initial mounting positions And it is configured to maintain the original elasticity at the time of installation even when the earthquake is not generated for a long period of time and absorb the seismic waves smoothly when an earthquake occurs,

A large capacity compressor is continuously supplied to fill the lower air charging part 132 and the upper air charging part 152 with high pressure air so as to fix the lower plate 151 and the upper plate 154 in a normal state without an earthquake Therefore, there is a problem in that power consumption and maintenance cost for operation of the large capacity compressor are excessively large when the normal operation is continued for a long time, and a large number of movable balls 155 for the left and right vibration and shock absorption when a seismic wave occurs, There is a problem in that the shape of the upper plate 154 supported by the balls and the configuration of the centering holding elastic body 160 and the like are complicated,

Particularly, there is a problem that the operation life is short and the maintenance and repair cost is increased in an installation environment in which the vibration durability of the vibration damping device is weak and the vibration or impact is continuously generated repeatedly continuously at all times.

Patent No. 10-1011388 (entitled "Seismic Design Plate and Seismic Design Plate Switchgear") Patent No. 10-1341151 (entitled " Switchgear Equipped with Seismic Protection Device ")

SUMMARY OF THE INVENTION It is an object of the present invention to provide a seismic isolation device for absorbing seismic waves, which is capable of significantly reducing power and maintenance costs required to maintain an inactivated state of a normal earthquake- It is possible to simplify the construction and to facilitate manufacture and maintenance,

Minimization of connection failure or malfunction of the switchboard due to continuous vibration in a switchboard installed at a place where constant vibration or impact is continuously generated repeatedly at normal times even in an ordinary earthquake such as a train station, a train station, or a construction site .

According to an aspect of the present invention, there is provided a cabin for a vehicle, which is coupled to a lower surface of an cabinet of a switchboard, absorbs seismic waves flowing from an installation surface and transmits vibration or impact of a seismic wave to the cabin An upper fixed plate (10) formed of a metal material magnetized by a magnetic body when it is in contact with the magnet and having a lower surface fixedly connected to a mounting surface; And the mechanical magnetic body change-over switch 22 is provided so that the side face of the magnetic body change-over switch 22 is in close contact with one side face of the lower fixed plate 10, And a mechanical magnetic body transformer (22) for magnetizing the lower fixing plate (10), which is in close contact with the side face, with a magnetic body when the mechanical magnetic body change-over switch (22) is moved to an on position and converted into a magnetic body, (20); An intermediate movable plate 30 located on the upper side of the lower fixing plate 10 and having a lower spherical surface groove 31 formed at the center of the upper surface thereof; The upper end is fixedly coupled to the lower surface of the intermediate movable plate 30 and the lower end is fixedly coupled to the upper surface of the lower fixed plate 10 to elastically support the intermediate movable plate 30. [ A first resilient support (50); The upper portion of the upper movable plate 30 is fixed to the lower surface of the cabinet 70 by a predetermined distance from the upper side of the intermediate movable plate 30, An upper movable plate (40) on which the first movable plate (41) is formed; A steel ball 60 interposed between the lower spherical groove 31 and the upper spherical groove 41 so as to be movable along respective spherical surfaces of the lower spherical groove 31 and the upper spherical groove 41; And a plurality of second resilient supporting portions (51) fixed to the upper surface of the upper movable plate (40) and fixed to the upper surface of the intermediate movable plate (30) And the earthquake-proof apparatus (1).

A plurality of support rod insertion grooves 42 formed at a predetermined depth are formed in the upper spherical surface groove 41 of the upper movable plate 40. In the present embodiment, And a plurality of support rod insertion grooves (42) are formed in a circumferential direction of the lower spherical surface groove (31) of the intermediate movable plate (30) A lower end of which is fixedly coupled to the upper surface of the lower fixing plate 10 and an upper end of which penetrates through the support rod moving hole 32, And a plurality of support rods (52) releasing or in close contact with the support rod insertion grooves (42) in accordance with predetermined upward and downward movement distances of the support rods (30)

Preferably, a changeover switch drive motor 23 for moving the mechanical magnetic body change-over switch 22 to the On or Off position; An earthquake measuring sensor 25 for measuring the occurrence of an earthquake in real time and outputting a signal to the outside; And a controller 24 for controlling the operation of the conversion switch driving motor 23 in response to an earthquake occurrence or non-occurrence signal from the earthquake measurement sensor 25.

INDUSTRIAL APPLICABILITY According to the present invention, there is provided an earthquake-resistant apparatus for an earthquake-proof earthquake-proof apparatus, which is capable of remarkably reducing power consumption and maintenance cost required for maintaining an inactivated state of a normal earthquake- And can be easily manufactured and maintained,

It is installed in the switchgear where weak vibration or impact is constantly generated repeatedly at all times even in the case where there is no earthquake, as in a train station, a train station, a construction site, etc. to minimize the occurrence of connection failure or malfunction due to continuous vibration .

1 is a sectional view showing a seismic resistant device provided in a conventional switchboard;
2 is a sectional view showing another seismic isolation device provided in a conventional switchboard;
FIG. 3A is an explanatory view showing an operation of an electrical switchboard with an isolation and vibration-proofing device according to the present invention, in which the mechanical magnetic body transformer and the lower fixed plate are normally converted into magnetic bodies and the lower fixed plate is tightly fixed to the intermediate movable plate by magnetic force State diagram;
3B is an exploded perspective view of the distribution board according to the present invention. FIG. 3B is a sectional view of the distribution board of FIG. 3B when the earthquake occurs. Fig. 8 is an operational state view showing that the first and second elastic members are elastically movable up and down;
FIG. 4A is an operational state diagram showing that an upper movable plate is fixedly supported through a support rod of a lower fixed plate in an ordinary distribution board having an isolation and vibration proofing apparatus according to the present invention; FIG.
FIG. 4B is an operating state diagram showing that the support rod is released from the upper movable plate and the fixed support of the upper movable plate is released when an earthquake occurs, according to the present invention; FIG. And
5 is a configuration diagram showing the configuration of an earthquake-proof and earthquake-proof apparatus in an ASSEMBLY with an earthquake-proof and earthquake-proof apparatus according to the present invention;

Hereinafter, embodiments of the present invention in which the above object can be specifically realized will be described with reference to the accompanying drawings. In describing the embodiments, the same names are denoted by the same reference numerals, and further description thereof will be omitted below.

FIG. 3A is a sectional view of an electrical distribution board in which an earthquake-proof and earthquake-proof apparatus 1 according to the present invention is installed; FIG. 3A is a schematic view showing a state in which the mechanical magnetic body conversion unit 20 and the lower fixed plate 10 are converted into magnetic bodies, 3B is an operational view showing that the movable plate 30 is tightly fixed to the movable plate 30. FIG. 3B is a sectional view of the switchboard with the earthquake-proof and vibration-isolating apparatus 1 according to the present invention, And the intermediate movable plate 30, which has been fixed by the magnetic force of the lower fixing plate 10, can be elastically moved upward and downward by the plurality of first elastic portions Fig.

4A is an exploded perspective view of a distribution board having an earthquake-proof and earthquake-proof apparatus 1 according to the present invention, in which an upper movable plate 40 is fixedly supported through a support rod 52 of a lower fixed plate 10 4B is a view showing an operation panel of the switchboard in which the seismic isolation device 1 according to the present invention is installed. In case of an earthquake, the support rod 52 is separated from the upper movable plate 40, Fig. 5 is an arrangement view showing the configuration of an earthquake-proof and earthquake-proof apparatus 1 in an electric distribution board having the earthquake-proof and earthquake-proof apparatus 1 according to the present invention.

As shown in Figs. 3A and 3B, the distribution board having the seismic isolation system 1 according to the present invention includes a lower fixation plate 1 located at the lower portion of the seismic system 1, A mechanical magnetic transducer 20 provided in a face-to-face contact with the lower fixed plate 10 to magnetize or unmagnetize the lower fixed plate 10 with a magnetic substance, An intermediate movable plate 30 located on the upper side of the intermediate movable plate 30 and a plurality of first elastic supporting portions 50 supporting the intermediate movable plate 30; An upper movable plate 40 to which an upper side is fixedly coupled to a lower portion of a housing 70 of a switchgear including devices, a steel ball 60 interposed between the intermediate movable plate 30 and the upper movable plate 40, The upper movable plate (40) The sanctuary basement comprises a plurality of second elastic supports 51.

The lower fixing plate 10 is formed of a metallic material magnetized by a magnetic body when it comes into contact with a magnet and has a magnetic force. As shown in FIGS. 3A and 3B, the lower surface is fixedly coupled to a mounting surface, And acts as a base of the seismic isolation and earthquake-proof apparatus 1. [

Unlike the electromagnet having a magnetic force only during current conduction, the mechanical magnetic transducer 20 converts the magnetic field of the magnetic field of the magnetic field generated by the magnetic field of the magnetic field, Is activated or deactivated and the activated magnetic force is maintained as it is regardless of whether or not the current is energized while the changeover switch 22 remains in the ON position. In the seismic isolation system 1 according to the present invention, a general mechanical type magnetic transducer conventionally used is employed, and a detailed description of the operation will be omitted. 3A and 3B, the mechanical magnetic body conversion unit 20 is provided with a mechanical magnetic body change-over switch 22 which is in contact with a side surface of the lower fixed plate 10 at one side and is provided at one side thereof, When the mechanical magnetic body change-over switch 22 is moved to the On position and is converted into a magnetic body, the lower fixed plate 10 positioned in close contact with the side is magnetized by a magnetic body, and the magnetized lower fixed plate 10 The magnetic force of the intermediate movable plate 30 pulls the intermediate movable plate 30 located at the upper side with a magnetic force larger than the elastic force of the plurality of first elastic support portions 50 and the lower side of the intermediate movable plate 30 contacts the lower fixed plate 10 So as to come into contact with the upper surface of the sheet.

As shown in FIGS. 3A and 3B, the intermediate movable plate 30 is located on the upper side of the lower fixed plate 10. When the lower fixed plate 10 is magnetized, the intermediate movable plate 30 is attracted by the magnetic force And a lower spherical surface groove 31 is formed at the center of the upper surface.

The steel ball 60 is interposed between the lower spherical groove 31 and the upper spherical groove 41 and moves along the spherical surfaces of the lower spherical groove 31 and the upper spherical groove 41.

3A and 3B, the upper end of the first elastic support portion 50 is fixedly coupled to the lower surface of the intermediate movable plate 30, and the lower end of the first elastic support portion 50 is fixed to the lower fixed plate 10 So that the intermediate movable plate 30 is elastically supported.

As shown in FIGS. 3A and 3B, the upper movable plate 40 is disposed at a predetermined distance from the upper side of the intermediate movable plate 30, and the upper surface of the upper movable plate 40 is connected to the lower surface of the switchgear housing 70 And an upper spherical surface groove 41 is formed at the center of the lower surface so as to face the lower spherical surface groove 31.

The upper ends of the plurality of second elastic supports 51 are fixedly coupled to the side surfaces of the upper movable plate 40 and the lower ends of the second elastic supports 51 are fixedly coupled to the upper surface of the intermediate movable plate 30, The movement of the upper movable plate 40 in accordance with the left and right movements of the steel ball 60 is maintained within a predetermined range and the left and right vibrations and the up and down vibrations are attenuated.

Preferably, as shown in Fig. 5, a change-switch drive motor 23 for moving the mechanical magnetic body change-over switch 22 to the on or off position is provided. A controller 24 for controlling the operation of the conversion switch driving motor 23 in response to an earthquake occurrence or non-occurrence signal from the earthquake measurement sensor 25, So as to automate the operation of the seismic isolation and earthquake-resistant device 1 according to the present invention.

The operation of the earthquake-proof and earthquake-proof apparatus 1 will now be described in more detail with respect to the operation of the earthquake-proof and earthquake-proof apparatus 1 in the distribution board having the earthquake-proof and earthquake-proof apparatus 1 according to the present invention. 5, a non-seismic occurrence signal is input to the controller 24 from the seismic measurement sensor 25, and the controller 24, which receives the non-seismic occurrence signal, 23, and the changeover switch 22 remains in the On position. While the changeover switch 22 is in the ON position, the mechanical magnetic transducer 20 is maintained as a magnetic body, and the lower fixed plate 10, which is seamed to the mechanical magnetic body transformer 20, And the intermediate movable plate 30 is pulled and fixed until it comes into contact with the upper surface of the lower fixed plate 10.

This is because, in the conventional earthquake-proof apparatus, in order to always firmly fix and support the housing 70 of the switchboard, the compressed air must be supplied by continuously operating the air compressor. On the other hand, in the seismic and earthquake- The changeover switch drive motor 23 is operated only when the changeover switch 22 is moved from the off position to the on position and then the changeover switch drive motor 23 is operated by the mechanical magnetic body change unit 20, It is possible to magnetically fix the stationary plate 10 and securely support the intermediate movable plate 30 so that power consumption and maintenance cost required for fixing and supporting the switchgear housing 70 without any additional power consumption It is possible to remarkably reduce the cost.

When the intermediate movable plate 30 is fixed to the lower fixed plate 10, the plurality of first elastic supporting portions 50 are also fixed in position and the steel ball 60 and the upper movable plate 40 are fixed. In the case of a switchboard installed at a place where repeated weak vibration or impact is constantly generated even in a normal state where no earthquake occurs as in a train station, a train station, a construction site, etc., The steel ball 60 is moved along the lower spherical groove 31 and the upper spherical groove 41 by frequent vibration transmitted continuously in all directions of the upper spherical groove 41 and the lower spherical groove 31 So that the frequent vibration transmitted from the mounting surface is attenuated by the plurality of second elastic supports 51 and the vibration of the steel ball 60 To switchgear enclosure 70 is returned to its original position.

3B and 5, an earthquake occurrence signal is input from the earthquake measurement sensor 25 to the controller 24, and the controller 24, which receives the earthquake occurrence signal, The motor 23 is driven to move the changeover switch 22 to the off position and by the off position movement of the changeover switch 22 the mechanical magnetic body conversion section 20 is switched to the non- And the intermediate movable plate 30 is disengaged from the first movable support plate 30. The intermediate movable plate 30 is moved in the direction of the axis of the first elastic support 50, It is possible to freely move up and down while moving toward the upper side through the elastic force. The plurality of first elastic supporters 50 move elastically upward and downward to attenuate strong seismic waves and the steel ball 60 moves along the lower spherical groove 31 and the upper spherical groove 41, The center of the upper spherical groove 41 and the lower spherical groove 31 can be automatically moved to be centered and weak seismic waves can be further attenuated through the plurality of second elastic supports 51.

4A and 4B, when it is necessary to fix the cabinet 70 more firmly in a place where the weak vibration does not continuously occur through the mounting surface, A support rod 52 into which a top end is inserted or detached into a plurality of support rod insertion grooves 42 provided around the upper spherical surface groove 41 of the plate 40 is inserted into the support rod 42 of the intermediate movable plate 30, The intermediate movable plate 30, the steel balls 60, and the outer peripheral surface of the lower fixed plate are provided with a predetermined length on the upper surface of the lower fixed plate so as to penetrate through the moving hole 32, As the upper movable plate 40 moves downward, the support rod 52 is inserted into the support rod insertion groove 42 to firmly support the upper movable plate 40 and the switchgear housing 70 , And when an earthquake occurs, As the intermediate movable plate 30, the steel ball 60 and the upper movable plate 40 are moved upward through the nonmagnetic conversion of the ephemeris transformer 20, The upper movable plate 40, the intermediate movable plate 30, and the steel ball 60 are freely moved, thereby facilitating the seismic and earthquake-resistant functions.

As described above, the switchboard having the earthquake-proof and earthquake-proof apparatus 1 according to the present invention significantly reduces power and maintenance costs required to maintain the inactivated state of the normal earthquake-proof apparatus 1 in which no earthquake occurs It is possible to easily manufacture and maintain the earthquake-resistant apparatus 1 that absorbs seismic waves,

It is installed in the switchgear where weak vibration or impact is constantly generated repeatedly at all times even in the case where there is no earthquake, as in a train station, a train station, a construction site, etc. to minimize the occurrence of connection failure or malfunction due to continuous vibration In the event of an earthquake, the seismic waves can be attenuated more actively in response to strong seismic waves.

It is to be understood by those skilled in the art that the present invention may be embodied in many other forms without departing from the spirit and scope of the invention,

Accordingly, the above-described embodiments are to be considered illustrative and not restrictive, and all embodiments within the scope of the appended claims and their equivalents are intended to be included within the scope of the present invention.

1: Seismic isolation and seismic isolation
10: lower fixing plate 20: mechanical magnetic body conversion part
21: Mechanical magnetic body conversion body 22: Mechanical magnetic body conversion switch
23: conversion switch drive motor 24: controller
25: Earthquake measurement sensor
30: intermediate movable plate
31: lower spherical surface groove 32: support rod moving hole
40: upper movable plate 41: upper spherical groove
42: support rod insertion groove 50: first elastic support
51: second elastic support portion 52: support rod
60: Steel ball 70: Switchboard enclosure

Claims (3)

And an earthquake-proof and earthquake-proof device coupled to a lower surface of the cabinet of the cabinet for absorbing seismic waves introduced from the installation surface to attenuate transmission of vibration or shock of seismic waves to the cabinet of the cabinet,
A lower fixing plate (10) formed of a metal material magnetized by a magnetic body upon contact with the magnet, and having a lower surface fixedly coupled to the mounting surface;
And the mechanical magnetic body change-over switch 22 is provided so that the side face of the magnetic body change-over switch 22 is in close contact with one side face of the lower fixed plate 10, And a mechanical magnetic body transformer (22) for magnetizing the lower fixing plate (10), which is in close contact with the side face, with a magnetic body when the mechanical magnetic body change-over switch (22) is moved to an on position and converted into a magnetic body, (20);
An intermediate movable plate 30 formed of a metal material influenced by a magnetic force and positioned on the upper side of the lower fixing plate 10 and having a lower spherical surface groove 31 formed at the center of the upper surface thereof;
The upper end is fixedly coupled to the lower surface of the intermediate movable plate 30 and the lower end is fixedly coupled to the upper surface of the lower fixed plate 10 to elastically support the intermediate movable plate 30. [ A first resilient support (50);
The upper portion of the upper movable plate 30 is fixed to the lower surface of the cabinet 70 by a predetermined distance from the upper side of the intermediate movable plate 30, An upper movable plate (40) on which the first movable plate (41) is formed;
A steel ball 60 interposed between the lower spherical groove 31 and the upper spherical groove 41 so as to be movable along respective spherical surfaces of the lower spherical groove 31 and the upper spherical groove 41;
A plurality of second elastic support portions (51) fixed to the side surfaces of the upper movable plate (40) and having a lower end fixedly coupled to the upper surface of the intermediate movable plate (30); And

A plurality of support rod insertion grooves 42 formed at predetermined depths are provided at predetermined intervals around the upper spherical surface groove 41 of the upper movable plate 40 and the lower spherical surface groove 42 of the intermediate movable plate 30 A plurality of support rod moving holes 32 are formed in the periphery of the lower fixed plate 31 so as to penetrate from the upper surface to the lower surface at positions opposed to the plurality of support rod insertion grooves 42, The upper end of the intermediate rod 30 is fixedly coupled to the upper surface of the support rod insertion hole 42 through the support rod moving hole 32, And a plurality of supporting rods (52) that are separated from or in contact with each other,
delete The method according to claim 1,
A changeover switch drive motor 23 for moving the mechanical magnetic body change-over switch 22 to the On or Off position;
An earthquake measuring sensor 25 for measuring the occurrence of an earthquake in real time and outputting a signal to the outside; And
And a controller (24) for receiving an earthquake occurrence or non-occurrence signal from the earthquake measurement sensor (25) and controlling the operation of the conversion switch drive motor (23) 1).

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