KR101742051B1 - Switchboard having earthquake proof device - Google Patents

Abstract

The present invention relates to a switchboard having an earthquake-proof device, which disperses and mitigates shock transferred in the event of an earthquake to secure stability against the earthquake. The switchboard having an earthquake-proof device according to the present invention comprises: a first movement prevention unit which supports both sides of the switchboard to prevent horizontal movement; a fixing unit which fixes the upper end and the lower end of the first movement prevention unit to a ceiling slab and a ground surface, respectively; a support unit which holds the switchboard up to be separated from the ground surface, includes a first earthquake-proof unit coming in contact with the lower surface of the switchboard on the upper surface thereof, and is provided with an installation frame on the lower surface thereof; a dispersion unit which is coupled to an inner space of the installation frame, and in which a plurality of vertical rods and horizontal rods are coupled in an intersecting form to disperse vibration or shock of earthquake wave; and a housing which has the support unit fixed to the upper end, is provided with an accommodation space for accommodating the installation frame therein, and is provided with a second earthquake-proof unit elastically supporting the lower surface of the installation frame on the bottom surface of the accommodation space.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a switchboard having a seismic isolation device,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electrical switchboard having an earthquake-resistant device, and more particularly, to an electrical switchboard having an earthquake-resistant device capable of preventing vibration or shock of a seismic wave during an earthquake.

In general, switchboards are electrical equipment that supplies industrial power to users. They are devices used to monitor, control, and protect electrical systems when power is supplied from power stations or substations. The switchboard consists of a rectangular steel enclosure, and devices such as circuit breakers and protective relays are attached inside the enclosure.

Generally, since the switchboard is fixed to the floor or the floor of the building, there is a possibility that the enclosure is deformed due to the impact of the earthquake when the earthquake occurs or various electric devices installed inside the enclosure are damaged or the switchboard falls down in severe cases.

In this case, power can not be stably supplied to a place where electric power is required, and there is a problem of electric shock due to a short circuit or the like.

Accordingly, there is a demand for a seismic switchboard that absorbs seismic waves in the event of an earthquake so that the enclosure of the switchboard is not deformed, the internal electrical equipment is not damaged, and the switchboard is prevented from falling, thereby preventing safety accidents such as short- .

Conventionally, the lower end of the conventional switchboard is fixed to the ground with an anchor bolt so that it is not conducted when an earthquake occurs.

However, the simple coupling method using such an anchor bolt has a problem that the vibration due to the earthquake is transmitted directly to the switchboard, so that the switchboard can be easily damaged or damaged by the seismic waves. In particular, when a plurality of switchboards are arranged in a row, the vibration of one of the switchboards may be transmitted to the other switchboards, thereby damaging the switchboards in a chain or damaging the connection between the switchboards.

Accordingly, conventionally, vibration damping pads or dustproof springs for absorbing vibration due to the ground are interposed between the anchor bolts and the ground, thereby alleviating the transmission of vibration caused by the earthquake to the switchboard. Conventional vibration damping pads and vibration damping springs have a problem that there is a limit in stably protecting the switchboard from seismic waves that vibrate largely to the left and right because the amplitude of the wave that can be buffered is small and mainly absorbs the up and down vibration.

Patent Registration No. 10-1394535 (Apr. 2014, 2014)

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide an electrical switchgear having an earthquake-resistant device capable of securing stability against earthquakes by dispersing and mitigating vibration and impact transmitted when an earthquake occurs. have.

The present invention relates to an earthquake-resistant apparatus for an earthquake-resistant earthquake-resistant earthquake, comprising: a ceiling slab; A supporting part having a mounting part formed on a bottom surface thereof and having a first vibration preventing part provided on an upper surface of the supporting part so as to be spaced apart from the ground surface and contacting the bottom surface of the switchboard; A plurality of vertical rods and horizontal rods crossing each other so as to disperse impacts, a plurality of vertical rods and a plurality of horizontal rods interposed between the vertical rods and the horizontal rods, And a housing provided with a second dustproof portion for elastically supporting a bottom surface of the installation frame.

The first flow restricting portions are respectively disposed on both sides of the switchboard, and the upper and lower ends are fixed to the ceiling slab and the ground via the fixing portion. One side of the support is fixed to the support, And a support member having a third dustproof portion contacted with the second dustproof portion.

In addition, the fixing portion includes a socket portion embedded in the inside of the ceiling slab and a ground surface and having a spiral groove formed in its inner periphery, an anchor embedded in the inside of the ceiling slab and the ground, And a fixing member fixed to the spiral groove of the socket portion to fix the support frame to the ceiling slab and the ground.

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The switchboard with the earthquake-proof device according to the present invention can prevent the switchboard from being conducted when an earthquake occurs, through the first flow-preventing portion that prevents the left and right flow of the switchboard, and disperses vibration and shock of the seismic waves through the dispersion portion The vibration and shock of the earthquake wave applied to the switchboard can be quickly and efficiently buffered through the respective dustproof portions provided in the form of a distribution distributed uniformly on the switchboard, thereby preventing the various devices installed on the switchboard from being damaged.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a front view showing an electric distribution board having an earthquake-proof apparatus according to the present invention; Fig.
FIG. 2 is a side view of an electric distribution board having a vibration isolation device according to the present invention. FIG.
3 is an exploded perspective view of a support portion, a dispersion portion, and a housing, which are applied to an electrical switchboard having an earthquake-proof apparatus according to the present invention.
4 is an assembled cross-sectional view of a support portion, a dispersion portion and a housing, which are applied to an ASSEMBLY according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Like parts are designated with like reference numerals throughout the specification.

FIG. 1 is a front view of an electrical switchboard having a seismic isolation device according to the present invention. FIG. 2 is a cross-sectional view of an electrical switchboard having an earthquake-proof device according to an embodiment of the present invention. The present invention relates to an earthquake-resistant apparatus for an earthquake-resistant apparatus, and more particularly, to an earthquake-resistant apparatus for earthquake- Fig.

The present invention relates to an earthquake-resistant apparatus having an earthquake-resistant device capable of attenuating and absorbing vibration or shock of a seismic wave transmitted from an earth surface to ensure structural stability. The earthquake-resistant apparatus includes a first flow- 30, a dispersion unit 40, and a housing 50. [

The first flow preventive portion 10 prevents the switchboard 1 from flowing in the left and right directions by earthquake and comprises a support base 11 and a support member 12.

The support base 11 may be formed as a rectangular bar or a round bar having a predetermined length and thickness and a flange P may be provided at the upper and lower ends so as to be fixed to the ceiling slab S and the floor G, do.

At this time, the flange (P) is formed with a plurality of through holes (not shown) penetrating upward and downward so that the fixing part (20) described later can be installed.

The support base 11 is spaced apart from the left and right sides of the switchboard 1 by a predetermined distance.

The two support rods 11 are opposed to the front and rear sides of the left side of the switchboard 1 and the other two support rods 11 are connected to the right side of the switchboard 1 The front side and the rear side are opposed to each other.

The support base 11 may be formed of a metal material having excellent durability and self-rigidity.

The support member 12 supports the switchboard 1 and has one side welded or bolted to the support base 11 while the other side is selectively connected to the side surface of the switchboard 1 The third dustproof portion 13 is formed.

The third anti-vibration part 13 is formed to have a larger cross-sectional area than the support member 12 and is made of a material having elasticity such as rubber or silicone. When the third anti-vibration part 13 contacts the switchboard 1, The shock absorbs the vibration or shock of the earthquake.

A plurality of the support members 12 described above are arranged so as to be uniformly distributed on the switchboard 1 so as to stably support the switchboard 1 and the third anti-vibration unit 13 can support the switchboard 1 1 so as to effectively cushion vibrations and shocks of the seismic waves applied thereto.

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In addition, since the switchboard 1 can be prevented from flowing in the left and right directions through the first flow preventive portion 10, it is possible to prevent the switchboard 1 from being conducted when an earthquake occurs, .

The fixing part 20 fixes the flanges P provided at the upper and lower ends of the supporting frame 11 to the ceiling slab S and the ground G respectively. The socket part 21, the anchor 22, , And a fixing member (23).

The socket portion 21 is opened at one side and a helical groove 21a is formed at the inner peripheral edge.

The socket portion 21 is embedded in the inside of the ceiling slab S and the inside of the ground G so that the open portion faces the through hole of the flange P. [

At this time, the socket portions 21 are embedded in the ceiling slab S and the ground G in the same number as the through holes.

A plurality of anchors 22 are formed on the outer surface of the socket portion 21 and are embedded in the ceiling slab S and the ground G together with the anchor 22 . The anchor 22 allows the socket portion 21 to be stably fixed without flowing due to vibration or shock of a seismic wave in the ceiling slab S and the ground G, The prevention part 10 can stably support the switchboard 1.

The fixing member 23 can be formed by a known bolt and is inserted into the spiral groove 21a of the socket portion 21 through the through hole of the flange P, And is stably fixed to the slab S and the ground G. [

The support portion 30 is formed to have an area corresponding to the entire bottom surface of the switchboard 1 and a first dustproof portion 31 is provided on the upper surface of the support portion 30 to contact the bottom surface of the switchboard 1.

The first anti-vibration unit 31 is made of a material having elasticity such as rubber or silicone, and buffers vibrations and shocks of a seismic wave applied to the switchboard 1.

The supporting portion 30 has a mounting frame 32 formed in a rectangular shape at both edges of the bottom surface and is mounted on the housing 50 to be described later so that when the switchboard 1 is supported on the floor so as to be spaced apart from the ground G And damps the vibration and shock of the seismic wave transmitted to the switchboard 1 from the earth station G. [

The dispersion unit 40 disperses vibrations and shocks of seismic waves transmitted from the ground G to the switchboard 1 so that a plurality of vertical rods 41 and horizontal rods 42 are installed on the installation frame 32, As shown in FIG.

As a result, the vibrations and shocks of the seismic waves transmitted from the ground G to the switchboard 1 are greatly reduced as the vibration and impact of the seismic waves are uniformly dispersed in the plurality of vertical rods 41 and the horizontal rods 42, The structural stability of the substrate 1 can be ensured.

In this case, when the vertical bar 41 and the horizontal bar 42 are formed in a zigzag shape or a wave shape, the vibration of the seismic wave transmitted to the switchboard 1 can be further reduced because the path of the seismic wave is long.

In addition, a plurality of air bags 60 filled with air are installed in empty spaces formed between the vertical bars 41 and the horizontal bars 42.

The air bladder 60 alleviates vibrations and shocks of the seismic waves transmitted on the mounting frame 32 and the dispersing portion 40 so that vibration and impact of the seismic waves transmitted to the switchboard 1 can be reliably reduced .

In addition, since the vertical bar 41, the horizontal bar 42, and the air bag 60 can increase the cross-section of the installation frame 32, the load of the switchboard 1 can be stably supported.

Meanwhile, the housing 50 is formed with a receiving space 50a in which the supporting part 30 is fixed to the upper end thereof by bolts or welding, and a mounting frame 32 in which the dispersing part 40 is coupled is accommodated .

At this time, the housing 50 is applied in the same manner as the number of the mounting frames 32, and a flange P 'fixed to the ground G through bolts is integrally formed on the lower side.

A plurality of second vibration preventing portions 51 are formed on the bottom surface of the accommodating space 50a to elastically support the bottom surface of the mounting frame 32.

The second anti-vibration portion 51 is formed by a known coil spring to reduce vibration and shock of a seismic wave.

As the vibrations and shocks of the relaxed seismic waves are dispersed by the dispersing unit 40, the vibration and the amount of impact of the seismic waves transmitted to the switchboard 1 can be remarkably reduced.

As described above, the switchboard with the earthquake-proof device according to the present invention can prevent the switchboard 1 from being conducted when an earthquake occurs through the first flow-preventing portion 10 for preventing the left and right flow of the switchboard, Vibration and shock of a seismic wave are dispersed and dispersed through the dispersing portion 40 and vibration and shock of a seismic wave applied to the switchboard 1 through the respective dustproof portions 13, It is possible to prevent the various devices provided on the switchboard 1 from being damaged.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, Of the right.

1: Distribution board 10: First flow prevention part
11: Support member 12: Support member
13: third anti-vibration unit 20:
21: socket portion 21a: spiral groove
22: anchor 23: fixing member
30: support part 31: first anti-vibration part
32: installation frame 40: dispersion part
41: vertical bar 42: horizontal bar
50: housing 50a: accommodation space
51: second anti-vibration part 60: air bag

Claims (4)

A switchgear (1) having an earthquake-proof device for absorbing a seismic wave transmitted from a ground surface to attenuate transmission of a vibration or an impact of a seismic wave to the switchboard (1)
A first flow preventing portion 10 for supporting both side surfaces of the switchboard 1 to prevent left and right flow,
A fixing part 20 for fixing the upper and lower ends of the first flow prevention part 10 to the ceiling slab S and the ground G respectively,
A supporting portion 30 having a mounting portion 32 formed on the bottom surface thereof and a first dustproof portion 31 provided on the top surface of the supporting portion 30 to contact the bottom surface of the switchboard 1,
A dispersion unit 40 coupled to the inner space of the mounting frame 32 and coupled to the vertical rods 41 and the horizontal rods 42 so as to disperse vibrations or shocks of seismic waves,
The support portion 30 is fixed to the upper end and a receiving space 50a in which the mounting frame 32 is accommodated is formed and the bottom surface of the mounting frame 32 is provided with elasticity And a housing (50) provided with a second dustproof portion (51) for supporting the second dustproof portion (51).
The method according to claim 1,
The first flow prevention portion (10)
A support 11 disposed on both sides of the distribution board 1 and having upper and lower ends fixed to the ceiling slab S and the ground G through the fixing portion 20,
And a support member (12) having one side fixed to the support base (11) and a third anti-vibration member (13) formed on the other side for selectively contacting the side surface of the switchboard (1).
3. The method of claim 2,
The fixing part (20)
A socket portion 21 embedded in the inside of the ceiling slab S and the inside of the ground G and having a helical groove 21a in its inner periphery,
An anchor 22 formed on the outer surface of the socket portion 21 and embedded in the ceiling slab S and the ground G,
And a fixing member 23 penetrating through the support member 11 and fixed to the spiral groove 21a of the socket member 21 to fix the support member 11 to the ceiling slab S and the ground G, And an earthquake-proof device.
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