KR101911788B1 - Switchboard earthquake proof device - Google Patents

Abstract

The present invention relates to an earthquake-proof device for a switchboard, including: an upper cover which is coupled to the lower side of the switchboard; a lower cover installed on the lower side of the upper cover to be separated at a preset interval; an elastic strut installed between the upper cover and the lower cover to absorb vibration; an elastic steel plate installed between the upper cover and the lower cover to form sidewalls surrounding the elastic strut and including a plurality of bending inducing holes for inducing bending due to the vibration; an upper bracket mutually coupling the elastic steel plate to the upper cover; and a lower bracket mutually coupling the elastic steel plate to the lower cover. Accordingly, the present invention can conveniently install and operate the switchboard.

Description

{Switchboard earthquake proof device}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for seismic isolation of a switchboard for attenuating vibration transmitted through an earthquake of an ASSEMBLY.

Generally, the magnitude of the seismic force affecting the building when an earthquake occurs varies depending on the structural characteristics such as the height, shape, or material of the building, and the earthquake has a great influence on the advanced equipment or the switchboard installed on the floor of the building You can give.

In recent years, there has been a need for a system in which online / real-time processing systems are required, such as industrial information processing control devices, OA devices, and related facilities, and particularly in areas where utility is high such as electric power, nuclear power, water treatment, The demand for the earthquake resistance of the building is further increased.

The switchboard includes a distribution panel, a motor control center panel, a low-pressure panel, a high-pressure panel, a transformer panel, and a special high-pressure panel.

The switchboard is assembled by inserting an anchor bolt into an inside or outside concrete floor, assemble the floor angle, assemble the column angle to the floor angle, and assemble the enclosure to the assembled column angle. And it is vulnerable to earthquake because separate seismic design is not done.

Japanese Unexamined Patent Publication No. 1551194 includes a top plate, a bottom plate spaced apart from the top plate, and two or more elastic members mounted between the top plate and the bottom plate. The bottom surface of the switchboard A plurality of unit earthquake-resistant pads arranged by mutual coupling between the ground and the ground; And a connecting member for connecting between the unit earthquake-resistant pads adjacent to each other, wherein the elastic member comprises: an elastic layer having a steel plate and a rubber plate alternately laminated and an outer portion having a rubber cover surrounding the elastic layer; At least one firing bar passing through the elastic layer and a second firing bar vertically mounted between the upper plate and the lower plate and spaced apart from the side of the elastic member, And a wing portion formed of four wing stages extending along the respective rims, wherein the upper wing is formed at the two wing stages adjacent to the wing portion and the lower wing is formed at the two wing stages symmetrical to each other, Forming a mutually overlapping region between the upper and lower edges between the pads, And a third firing bar passing through the upper and lower steps of the upper plate and the upper and lower ends of the lower plate is formed at the base overlapping part, and one end of the third firing bar is connected to one plate And the other end is inserted into an elongated hole that is laterally cut in the blade end of the other plate, and is slid by the slot. The seismic switchboard using the unit earthquake resistant pad is disclosed.

In the prior art, a unit earthquake pad on which a switchboard is seated is designed to damp vibrational shock due to an earthquake when an earthquake occurs.

However, in the related art, when the switchboard is installed in the unit earthquake-proof pad, the unit earthquake pad is not fixed at one point and is slid to another place, so that the installation of the switchboard is inconvenient.

Further, in the prior art, since it is impossible to fix the switchboard at one point, there is a problem that the switchboard slides to another place when the switchboard is operated, which makes the operation of the switchboard inconvenient.

Korean Registered Patent No. 1551194 (2015.09.02.)

SUMMARY OF THE INVENTION It is an object of the present invention to provide an earthquake-resistant apparatus for a switchboard which is convenient to install and operate an switchboard.

The present invention relates to an apparatus for seismic isolation of an ASSEMBLY, comprising: an upper cover (11) coupled to a lower surface of an ASSB; A lower cover 12 disposed below the upper cover 11 at a predetermined distance; An elastic strut 20 installed between the upper cover 11 and the lower cover 12 to absorb vibrations; A plurality of bending induction holes 31 are formed between the upper cover 11 and the lower cover 12 to form side walls surrounding the elastic pillars 20 and to induce bending due to vibration, 30); An upper bracket 41 for coupling the elastic steel plate 30 and the upper cover 11 to each other; And a lower bracket 42 coupling the elastic steel plate 30 and the lower cover 12 to each other.

An upper support housing 43 disposed between the upper cover 11 and the elastic struts 20; A lower support housing (44) disposed between the lower cover (12) and the resilient support (20) and partially receiving the resilient support (20); An upper flow hole 11-1 formed in the upper cover 11, a central flow hole 43-1 formed in the upper support housing 43, A through bolt 45-1 penetrating through the lower flow hole 21 and a tilting groove 43-1 connected to the through bolt 45-1 and formed in the lower support housing 43, And a flow guide 45 including a tilting ball 45-2 which is inserted as far as possible.

In addition, a plurality of support plates 50 are arranged inside the elastic strut 20 in the vertical direction.

Further, the bending induction holes 31 are formed in the vertical direction.

A plurality of high-pressure tubes (60) inserted into a plurality of storage spaces formed on an outer circumferential surface of the elastic strut (20) and filled with high-pressure air; A wire 70, one end of which is connected to a cap 61 of the high-pressure tube 60; And a winder (80) for winding the other end of the wire (70) to open the plug (61) of the high-pressure tube (60) when a vibration of a specific value or more is sensed.

And a rupturable member (90) housed inside the high-pressure tube (60) and having both ends sharpened to rupture the high-pressure tube (60) when the high-pressure tube (60) is contracted.

Further, it further includes a connection pipe (100) connecting the adjacent pair of the high-pressure tubes (60).

Accordingly, in the seismic isolation device according to the present invention, since the upper cover for fixing the switchboard is fixed at one point, the installation and operation of the switchboard is advantageous.

In addition, the present invention has an advantage that the vibration due to an earthquake can be easily absorbed by using an elastic strut and an elastic steel plate.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view of an apparatus for seismic isolation of a distribution board according to the present invention; Fig.
2 is a cross-sectional view showing an apparatus for seismic protection of an ASS according to the present invention.
3 is a cross-sectional view showing a state in which a high-pressure tube, a wire, and a hoisting machine are formed in the seismic isolation device according to the present invention.
4 is a cross-sectional view showing a state in which a rupturing device is constructed in an earthquake-proof apparatus according to the present invention.
5 is a cross-sectional view showing a state in which a connecting pipe is formed in an electric cabinet earthquake-proof apparatus according to the present invention.

Hereinafter, the technical idea of the present invention will be described more specifically with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the technical concept of the present invention, are incorporated in and constitute a part of the specification, and are not intended to limit the scope of the present invention.

In the direction display of the present invention, the up and down direction of the figure is defined as the up and down direction.

FIG. 1 is a perspective view showing an apparatus for seismic protection of an ASSEMBLY according to the present invention, and FIG. 2 is a sectional view showing an ASSEMBLY according to the present invention.

As shown in FIG. 1, an apparatus according to the present invention includes an upper cover 11, a lower cover 12, an elastic strut 20, an upper bracket 41, and a lower bracket 42.

The upper cover 11 is an upper body of the present invention, which is formed in a plate structure and is coupled to the lower surface of the switchboard. A groove (not shown) may be formed on the upper surface of the upper cover 11 to increase frictional force with the lower surface of the switchboard.

The lower cover 12 is a lower body of the present invention. The lower cover 12 is formed in a plate structure and is spaced apart from the upper cover 11 by a predetermined distance, and is coupled to the ground.

The elastic strut 20 is a central body of the present invention and is installed between the upper cover 11 and the lower cover 12 and is made of an elastic material to absorb vibration caused by an earthquake. The lower end of the elastic strut 20 may be partially inserted into the upper surface of the lower cover 12.

The elastic steel plate 30 is installed between the upper cover 11 and the lower cover 12 to form side walls surrounding the elastic pillars 20 and is provided with a plurality of bending guides A hole 31 is formed. More specifically, the elastic steel plate 30 is arranged in a quadrangular structure and surrounds the elastic pillars 20. When the elastic pillars 30 are subjected to vibration, they are more easily bent through the bending induction holes 31 and absorb vibration.

The upper bracket 41 couples the elastic steel plate 30 and the upper cover 11 together. At this time, the upper bracket 41 is formed in an L-shaped structure and can be screwed to the elastic steel plate 30 and the upper cover 11, respectively.

The lower bracket 42 couples the elastic steel plate 30 and the lower cover 12 together. At this time, the lower bracket 42 may have an L-shaped structure and may be screwed to the elastic steel plate 30 and the upper cover 11, respectively.

Accordingly, in the seismic system of the switchboard according to the present invention, since the upper cover 11 to be connected to the switchboard is fixed at one point, there is an advantage that the installation and operation of the switchboard is convenient.

The present invention is also advantageous in that the vibration due to an earthquake can be easily absorbed by using the elastic strut 20 and the elastic steel plate 30.

The powertrain seismic device may further include an upper support housing 43, a lower support housing 44, and a flow guide 45 so that vibration absorption due to an earthquake is smoother.

The upper support housing 43 is a normal support panel and is disposed between the upper cover 11 and the elastic strut 20 and has an upper flow hole 11-1 formed therein. At this time, the upper flow hole 11-1 may have a circular section.

The lower support housing 44 is a conventional support panel and is disposed between the lower cover 12 and the elastic core 20 and has a central flow hole 43-1 formed therein. At this time, the central flow hole 43-1 may have a circular section.

A lower flow hole 21 is formed in the elastic strut 20 and a circular cross section is formed in the lower flow hole 21. The lower flow hole 21 is formed in the upper flow hole 11 -1) and the central flow hole 43-1.

The flow guide 45 induces a reduction in vibration transmitted to the switchboard by tilting and flowing the elastic strut 20 when an earthquake occurs. The flow guide 45 is provided with an upper flow hole 11-1 A central flow hole 43-1 formed in the upper support housing 43 and a through bolt 45-1 penetrating through the lower flow hole 21 formed in the elastic support 20, And a tilting ball 45-2 connected to the through bolt 45-1 and tiltingly inserted into the tilting groove 43-1 formed in the lower support housing 43. [ At this time, the through bolt 45-1 is fixed through a washer 46 and a nut (not shown) installed on the upper part.

Accordingly, when the earthquake occurs, the elastic struts 20 are tilted and moved within a distance from the upper flow hole 11-1, the central flow hole 43-1, and the lower flow hole 21, It is possible to reduce vibration.

A plurality of support plates 50 may be arranged inside the elastic struts 20 in the vertical direction.

The plurality of support plates 50 enhance the hardness of the elastic struts 20 and enhance the supporting force of the elastic struts 20 supporting the switchboards.

In addition, the bending inducing hole 31 may be formed in a vertical direction. Accordingly, the elastic steel plate 30 can be more flexed in the horizontal direction to absorb the vibration related to the transverse waves generated in the earthquake.

3 is a cross-sectional view showing a state in which a high-pressure tube, a wire, and a hoisting machine are formed in the seismic isolation device according to the present invention.

3, the powertrain seismic apparatus may further include a high-pressure tube 60, a wire 70, and a winder 80 for maximizing the elastic force of the elastic strut 20 when an earthquake occurs.

The high-pressure tube (60) is inserted into a plurality of storage spaces formed on the outer circumferential surface of the elastic strut (20) and filled with high-pressure air.

One end of the wire 70 is connected to a cap 61 of the high-pressure tube 60.

When a vibration sensor (not shown) is attached to the hoist 80 and vibration of a predetermined level or higher is detected, the other end of the wire 70 is wound to open the plug 61 of the high-pressure tube 60.

The process of maximizing the elastic force of the elastic strut 20 by the high-pressure tube 60, the wire 70 and the hoist 80 when an earthquake occurs will be described in more detail as follows.

1) When the vibration sensor mounted on the win- dow 80 senses vibration of a predetermined value or more (earthquake), the winder 80 winds the other end of the wire 70.

2) As the other end of the wire 70 is wound, one end of the wire 70 is pulled and opened by the stopper 61 of the high-pressure tube 60.

3) As the high-pressure air filled in the high-pressure tube 60 is discharged to the outside, a plurality of storage spaces formed on the outer circumferential surface of the elastic strut 20 are emptied, and the outer circumferential surface of the elastic strut 20 is formed into a wave structure The elastic force of the elastic strut 20 is further maximized.

4 is a cross-sectional view showing a state in which a rupturing device is constructed in an apparatus for seismic protection of an ASSP according to the present invention.

As shown in FIG. 4, the powertrain seismic system may include a rupturable member 90 for discharging the high-pressure air filled in the high-pressure tube 60 more quickly when an earthquake occurs.

The rupturable member 90 is housed inside the high-pressure tube 60 and is formed at both ends so that high pressure air is discharged from the high-pressure tube 60 to the outside, So that the high-pressure air filled in the high-pressure tube 60 can be discharged more quickly.

5 is a cross-sectional view illustrating a state in which a connecting pipe is formed in the seismic isolation device of the present invention.

As shown in FIG. 5, the powertrain seismic apparatus may further include a connector 100 connecting the pair of adjacent ones of the high-pressure tubes 60.

The connection pipe 100 serves to uniformize the pressure of a pair of adjacent ones of the high-pressure tubes 60 to maintain the balance of the elastic struts 20 as maximum as possible.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

11: Upper cover
11-1: Upper flow hole
12: Lower cover
12-1: Lower flow hole
20: Elastic holding
30: Elastic steel plate
31: bending induction hole
41: upper bracket
42: Lower bracket
43: upper support housing
43-1: central flow hole
44: Lower support housing
44-1: Tilting groove
45: Flow guide
45-1: Through bolt
45-2: Tilting Ball
46: Washer
50: Support plate
60: High pressure tube
61: Plug
70: wire
80: Winches
90: rupture member
100: Connector

Claims (7)

An upper cover (11) coupled to a lower surface of the switchboard;
A lower cover 12 disposed below the upper cover 11 at a predetermined distance;
An elastic strut 20 installed between the upper cover 11 and the lower cover 12 to absorb vibrations;
A plurality of bending induction holes 31 are formed between the upper cover 11 and the lower cover 12 to form side walls surrounding the elastic pillars 20 and to induce bending due to vibration, 30);
An upper bracket 41 for coupling the elastic steel plate 30 and the upper cover 11 to each other;
A lower bracket 42 for coupling the elastic steel plate 30 and the lower cover 12 to each other;
A plurality of high-pressure tubes (60) inserted into a plurality of storage spaces formed on an outer circumferential surface of the elastic strut (20) and filled with high-pressure air;
A wire 70, one end of which is connected to a cap 61 of the high-pressure tube 60; And
And a winch (80) for winding the other end of the wire (70) to open the plug (61) of the high-pressure tube (60) when a vibration of a specific value or more is sensed.
The method according to claim 1,
An upper support housing (43) disposed between the upper cover (11) and the resilient support (20);
A lower support housing (44) disposed between the lower cover (12) and the resilient support (20) and partially receiving the resilient support (20); And
An upper flow hole 11-1 formed in the upper cover 11, a central flow hole 43-1 formed in the upper support housing 43 and a lower flow hole formed in the lower portion of the elastic support 20, A through bolt 45-1 penetrating through the flow hole 21 and a tilting groove 43-1 connected to the through bolt 45-1 and formed in the lower support housing 43, (45) including a tilting ball (45-2) inserted into the tilting ball (45-2).
2. The apparatus of claim 1, wherein the resilient pillars (20)
Wherein a plurality of support plates (50) are arranged in the vertical direction inside the cabin.
2. The apparatus according to claim 1, wherein the bending induction hole (31)
An apparatus for earthquake-resistant equipment in an up-and-down direction.
delete The method according to claim 1,
And a rupturable member (90) housed in the high-pressure tube (60) and having both ends sharpened to rupture the high-pressure tube (60) when the high-pressure tube (60) is contracted.
The method according to claim 1,
And a connection pipe (100) connecting adjacent ones of the high-pressure tubes (60).

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