KR20160087790A - the distribution board having earthquake-proof device and for horizontal control - Google Patents

Abstract

Conventionally, electric devices have been installed to stand up on the bottom such as a high-voltage switchboard, a low-voltage switchboard, a distribution board, and a motor control center (MCC). The present invention relates to a switchboard (high-voltage switchboard, low-voltage switchboard, distribution board, MCC) including an earthquake-proof device capable of protecting the electric device from vibration based on earthquake or the like and with easy horizontal adjustment. The switchboard comprises: a rectangular frame (20) which is formed of a rectangular skeleton and is made of metal; a side support fixture (21) which is fixed to the lower portion of the side periphery of the rectangular frame (20) like a wall face; four bases (23) which are provided under the lower corners of the rectangular frame (20), respectively; bottom springs (24) which are interposed between the four bases (23) and the lower corners of the rectangular frame (20) to provide elastic force; a rectangular upper plate (11) which covers the upper end of the rectangular frame (20); bolts (12) which penetrate and locks the corners of the rectangular frame (20) to fix the upper plate (11) to the rectangular frame (20); four rings (13) which are provided at the lower corners of the upper plate (11), respectively; four hooks (14) which are fixed by hooking to the rings (13); four lines (15), one end of which is fixed to the hook (14) and the other end is fixed to the upper edge of a device body (110); and four side springs (22) which are positioned between the device body (110) and the side support fixture (21) to provide elastic force.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a distribution board having an earthquake-

The present invention relates to a high-voltage switchboard, a low-voltage switchboard, a distribution board, a motor control center (MCC), and a high-voltage switchboard, and more particularly to a switchboard (A high-voltage switchboard, a low-voltage switchboard, a distribution board, an MCC) equipped with an earthquake-resistant device capable of protecting an electric device installed in a standing state on the floor from vibration caused by an earthquake or the like.

The collapse of structures and the economic loss caused by natural disasters such as earthquakes and typhoons are increasing. As a result, efforts are being made to secure the stability of structures throughout the world. Especially, large buildings such as power plants and bridges and large buildings such as high - rise buildings can be accompanied by huge loss of life and economic loss in destruction. Therefore, seismic design standards for these buildings are strengthened in Korea.

If the intensity of the earthquake is below a certain level, even if the building itself is sound due to the vibration of the building, various electric devices and objects therein may fall over or collide with each other and be damaged. Particularly, since the middle and large-sized electric devices such as the control panel are made of electrical parts such as control circuits, devices, and switches that are vulnerable to external vibration, mechanical structural strength is very weak. Therefore, the middle- or large-sized electric device should be installed in an earthquake-proof structure to reduce the risk of damage due to the vibration of the building.

As a technique for protecting an electric device from a seismic wave, Korean Patent Laid-Open Publication No. 2011-87748 (published on August 3, 2011) discloses an earthquake-proof device for an electric device. The earthquake-proof device disclosed in the above publication is provided with a support installed on both sides of the enclosure of the electric device, a horizontal axis extending from the support toward the side wall of the enclosure, and an elasticity between the horizontal axis and the side wall of the enclosure And an elastic flexible member having an elastic member.

Such a conventional earthquake-proof device has a structure in which supports are provided on both sides of the housing of the electric device, and the housing and the support are connected to each other by an elastic flexible member, so that a composite movement including axial translation and rotational movement Lt; / RTI > Therefore, by absorbing the external vibration energy such as a seismic wave from the elastic flexible member, the electric device can be protected from vibration.

However, in the above-mentioned conventional earthquake-proof apparatus for electric apparatus, a pair of supports fixed on the floor surface is coupled to both sides of the electric apparatus to support the electric apparatus in a floating state from the floor surface, so that the electric apparatus is liable to be placed in an unstable state. That is, the electric device can be easily tilted by rotating about the horizontal axis as the rotation center axis. Particularly, in the case of an electric device having a heavy weight, the strength of the support or the horizontal axis must be very high, and the elasticity of the elastic flexible member must be very large.

Patent No. 10-1193469 (an electric switchboard (a high-voltage switchboard, a low-voltage switchboard, a distribution board, an MCC) equipped with an earthquake-proofing device and easily adjustable in level)

However, conventional seismic devices are vulnerable to high-speed earthquakes, and there is a problem in that it is not possible to sufficiently protect the switchboard from bad conditions such as collapsing buildings.

It is an object of the present invention to provide an earthquake-resistant apparatus capable of sufficiently protecting even a bad earthquake such as a high-speed earthquake and a collapse of a building, and to provide a power distribution easily leveled.

In order to achieve the above object, according to the present invention, there is provided a display device comprising: a rectangular frame (20) formed of a rectangular skeleton and made of a metal; A side support 21 fixed to the lower end of the side wall of the square frame 20 as a wall; Four pedestals (23) provided below the lower edge of the square frame (20); A bottom spring (24) sandwiched between the four pedestals (23) and the bottom edge of the square frame (20) to provide an elastic force; A rectangular top plate 11 covering the top of the square frame 20; A bolt 12 which passes through the edges of the rectangular frame 20 to fix the upper plate 11 to the rectangular frame 20; Four rings 13 at the bottom edge of the upper plate 11; Four hooks 14 for hooking and fixing to the ring 13; Four ropes (15) one end of which is fixed to the hook (14) and the other end is fixed to the upper edge of the device body (110); And four side springs (22) positioned between the apparatus main body (110) and the side support (21) to provide an elastic force.

In the embodiment, four rings 13 respectively provided on the bottom edge of the apparatus main body 110; Four hooks 14 for hooking and fixing to the ring 13; And four ropes 15 one end of which is fixed to the hook 14 and the other end of which is fixed to the bottom edge of the apparatus main body 110.

According to the preferred effects of the present invention, the shock absorbing structure and the shock absorbing structure over the third order not only alleviates the impact applied to the apparatus body 110, but also absorbs some impacts. Can be safely protected.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an exploded perspective view showing a disassembled state of a seismic system structure of an electric distribution panel according to the present invention; Fig.
2 is a perspective view showing an assembled state of a seismic device structure of an electric distribution board according to the present invention.
3 is a front view showing a front view of a seismic isolation structure of an electric distribution board according to the present invention.
4 is a plan view showing a plan view of a structure of a seismic system of an ASSEMBLY according to the present invention;
5 is a front view of a use state for explaining a situation in which an earthquake occurs in the structure of a seismic system of an ASSA according to the present invention.
6 is a front view for explaining another embodiment of the switchboard according to the present invention;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Although the present invention relates to an electric distribution board (high-voltage distribution board, low-voltage distribution board, distribution board, MCC), an electric distribution board can be sufficiently realized by conventional techniques.

2 is an exploded perspective view showing an assembled state of a seismic isolation structure of an ASSEMBLY according to the present invention. FIG. 3 is a sectional view of an ASSEMBLY of an ASSEMBLY according to the present invention. 4 is a plan view showing a plan view of a structure of an earthquake-proof apparatus according to the present invention, and FIG. 5 is a view showing a state in which an earthquake occurs in the earthquake- Is a front view of the use state.

The present invention relates to a switchboard including a high-voltage switchboard, a low-voltage switchboard, a distribution board and an MCC (motor control center), wherein the main function of the switchboard is configured in the apparatus main body 110, We will focus on the seismic design to protect against damage.

Referring to FIGS. 1 to 4, a rectangular frame 20 made of a rectangular metal frame is provided, a side support 21 fixed to the lower end of the rectangular frame 20, .

Four pedestals 23 provided under the bottom edge of the square frame 20 and a bottom surface spring 24 interposed between the four pedestals 23 and the lower edge of the square frame 20 to provide an elastic force, Respectively.

A rectangular upper plate 11 covering the upper end of the rectangular frame 20 and a bolt 12 fastened through the edges of the rectangular frame 20 to fix the upper plate 11 to the rectangular frame 20 And four rings 13 are provided on the bottom edge of the upper plate 11, respectively.

Four hooks 14 for hooking and fixing the hooks 13 to the hooks 14 and four lines 15 each having one end fixed to the hook 14 and the other end fixed to the upper edge of the apparatus body 110 do.

And four side springs 22 positioned between the apparatus body 110 and the side support 21 to provide an elastic force.

Based on this structure, we will examine the effect of this.

When an earthquake occurs, the four primary springs 24 are primarily absorbed by the impact transmitted from the geological layer to relieve the impact primarily, and the structure is suspended by the four lines 15, And the four side springs 22 thirdarily mitigate the impact of the device body 110 swaying from side to side.

The third shock absorbing structure and the shock absorbing structure not only mitigate the impact applied to the apparatus main body 110 but also absorb some impacts. As shown in FIG. 5, even when a part of the string 15 is broken The impact due to the collapse of the ceiling due to the collapse of the ceiling due to the top plate 11 can be prevented even when the building is extremely collapsed.

In addition, since the apparatus main body 110 is suspended from the four rows 15, horizontal adjustment is facilitated by gravity.

6, in order to protect the apparatus main body 110 even in a situation where an earthquake occurs and the rectangular frame 20 is laid or turned over, the string 15 is placed at the lower edge of the square frame 20 And the hook 15 is fixed to the bottom edge of the apparatus main body 110 and the hook 14 is provided at one end of the string 15, .

That is, four rings (13) provided at the bottom edge of the apparatus main body (110); Four hooks 14 for hooking and fixing to the ring 13; It is preferable to further include four lines 15 to which one end is fixed to the hook 14 and the other end is fixed to the lower edge of the apparatus body 110.

11; Top plate 12; volt
13; Ring 14; hook
15; Line 20; Square frame
21; Side supports 22; Side spring
23; Pedestal 24; Bottom spring
110; Device body

Claims (1)

An earthquake-resistant device for protecting the apparatus main body 110, which performs the main functions of a high-voltage switchboard, a low-voltage switchboard, a distribution board, and an MCC (motor control center), from being damaged by natural disasters such as earthquakes, As a result,
A square frame 20 made of a metal material and formed as a rectangular skeleton;
A side support 21 fixed to the lower end of the side wall of the square frame 20 as a wall;
Four pedestals (23) provided below the lower edge of the square frame (20);
A bottom spring (24) sandwiched between the four pedestals (23) and the bottom edge of the square frame (20) to provide an elastic force;
A rectangular top plate 11 covering the top of the square frame 20;
A bolt 12 which passes through the edges of the rectangular frame 20 to fix the upper plate 11 to the rectangular frame 20;
Four rings (13) provided at the bottom edge of the upper plate (11);
Four hooks 14 for hooking and fixing to the ring 13;
Four ropes (15) one end of which is fixed to the hook (14) and the other end is fixed to the upper edge of the device body (110);
Four side springs (22) positioned between the apparatus main body (110) and the side supports (21) to provide an elastic force;
Four rings (13 ') provided at the bottom edge of the square frame (20);
Four hooks 14 'for hooking and fixing to the ring 13';
Four lines 15 'one end of which is fixed to the hook 14' and the other end is fixed to the lower edge of the device body 110;
And an apparatus main body lower spring (22 ') mounted on a lower portion of the apparatus main body (110) and providing an elastic force between the lower main body and the lower plate of the square frame (20) .

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