KR102158964B1 - Distribution board with earthquake-proof device - Google Patents

Abstract

The present invention relates to a switchgear equipped with a seismic device, and more particularly, a seismic device that is provided in plural under the switchgear and absorbs vibrations or shocks caused by earthquakes to increase structural safety against the earthquake resistance of the switchgear. It relates to a switchgear equipped with.
In the switchgear provided with the seismic device according to the present invention, in a switchgear box including a switchgear box and a seismic device that is installed under the switchboard box and absorbs vibration or shock, the seismic device is fixedly installed on the ground, and A lower support member protruding from a curved portion having a predetermined curvature and having a coupling groove in the shape of an upper narrow light in the longitudinal direction above the curved portion; It is coupled to the upper portion of the lower support member to absorb vibration or shock transmitted in the horizontal direction, and a first seating groove corresponding to the curved portion is formed to be curved at the lower portion, and a coupling protrusion corresponding to the coupling groove protrudes in the longitudinal direction. A first buffer member formed; An upper support member coupled to an upper portion of the first buffer member and having a second seating groove corresponding to an upper portion of the first buffer member curved at a lower portion thereof; A second buffer member installed on the upper support member to absorb vibration or shock transmitted in a vertical direction, and a vibration and shock in the corresponding direction according to the direction in which the vibration or shock is transmitted by being installed inside the second buffer member It characterized in that it comprises a third buffer member for absorbing.

Description

Distribution board with earthquake-proof device

The present invention relates to a switchgear equipped with a seismic device, and more particularly, a seismic device that is provided in plural under the switchgear and absorbs vibrations or shocks caused by earthquakes, thereby enhancing the structural safety of the switchgear. It relates to a switchgear equipped with.

In general, a switchboard is a device used for monitoring, control, and protection of the power system, and refers to a unit device, a supporting structure, and an assembly of wires to connect it, and facilities that divide into places where power is to be used are built-in or Panels to control equipment will be provided.

If vibration or shock is applied to the switchboard due to external factors such as earth movement or explosion, electrical components such as internal power devices, wiring and protection relays of the control panel may be damaged, and the supply of power is interrupted due to power failure. Otherwise, there is a risk that a fire may occur.

Building collapse accidents have occurred due to natural disasters such as earthquakes, typhoons, and tsunamis, which are becoming more frequent in recent years, and economic losses are increasing. Therefore, securing the safety of buildings is considered important. Even in the case of damage, the seismic design standards are gradually being strengthened to minimize the interruption of power supply and the resulting economic loss.

As an example of a technique for solving this problem, Patent Publication No. 10-0939475 discloses a switchgear having a seismic function.

In the switchboard having the seismic function, a plurality of seismic means are installed between the floor angle and the support angle, and the seismic means has a bearing insertion hole into which the self-aligning bearing is inserted, and the bearing support fixed to the upper surface of the horizontal plate of the floor angle case; A bearing stop ring is installed at the lower end of the self-aligning bearing, and the lower end is inserted into the bearing insertion hole of the bearing support case together with the self-aligning bearing, and the upper end is inserted through a bolt through hole drilled in the support angle, and through a nut. Support bolts fixed to the horizontal plate of the support angle; When the inner ball is inserted into the bearing insertion hole of the bearing support case while the inner ball is coupled to the lower end of the support bolt, and an impact is applied in the horizontal direction from the outside, the support bolt is set as the center axis with the lower end coupled to its own ball. A self-aligning bearing that is inclined in the opposite direction to which the impact force is applied and allows the compression spring to absorb the impact force; The self-aligning bearing and the support bolt are installed in the bearing support case with a hole in the center through which the support bolt passes, and the bearing support case is fixedly installed on the horizontal plate of the floor angle through several bolts on the upper surface of the bearing support case. A cover to prevent separation from the; It is characterized in that it consists of a compression spring installed between the upper surface of the horizontal plate of the bottom angle and the bottom surface of the horizontal plate of the support angle in a form that surrounds the outer side of the support bolt and the bearing support case and the cover, and absorbs vibration and shock applied from the outside. .

However, the prior art has a problem in that when an impact is applied in the horizontal direction, the support bolts move at a predetermined angle within the bearing support case, and at this time, damage and abrasion occur while colliding with each other, and the support bolts are separated from the bearing support case. have. In addition, there is a problem in that noise is generated when the support bolt hits the bearing support case.

KR 10-0939475 B1 (2010.01.22.)

An object of the present invention has been devised to solve the above-described problems, and effectively absorbs and offsets vibrations or shocks generated by earthquakes through a seismic device having multiple seismic structures. It is to provide a switchgear equipped with a seismic device capable of reducing or reducing.

In order to achieve the above object, a switchgear equipped with a seismic device according to the present invention includes a switchgear box and a seismic device installed below the switchboard box to absorb vibrations or shocks, wherein the seismic device is on the ground. A lower support member which is fixedly installed, a curved portion having a predetermined curvature is protruded above the curved portion, and a coupling groove in the shape of an upper narrow beam is formed on the upper portion of the curved portion in the longitudinal direction; It is coupled to the upper portion of the lower support member to absorb vibration or shock transmitted in the horizontal direction, and a first seating groove corresponding to the curved portion is formed to be curved at the lower portion, and a coupling protrusion corresponding to the coupling groove protrudes in the longitudinal direction A first buffer member formed; An upper support member coupled to an upper portion of the first buffer member and having a second seating groove corresponding to an upper portion of the first buffer member curved at a lower portion thereof; A second buffer member installed on the upper support member to absorb vibration or shock transmitted in a vertical direction, and a vibration and shock in the corresponding direction according to the direction in which the vibration or shock is transmitted by being installed inside the second buffer member It characterized in that it comprises a third buffer member for absorbing.

In addition, the first buffer member is characterized in that it is made of a polyurethane foam having an elastic restoring force.

In addition, the second buffer member is installed on the upper portion of the upper support member and the lower portion of the switchboard housing, respectively, the fixing plate having a protruding hole having an open upper groove protruding; It characterized in that it comprises a compression spring installed between the fixed plates to absorb vibration or shock transmitted in the vertical direction.

In addition, the third buffer member includes a case in which an upper receiving space is formed and an elastic body is installed therein; A support bracket elastically supported by the elastic body and having a horizontally penetrating through hole; A mount member fixed to the upper inner side of the case and elastically supporting the support bracket; And a vibration damping member installed between the mount members to cancel or reduce vibrations or shocks transmitted in the horizontal direction.

In addition, the vibration damping member is installed in the through hole of the support bracket, a cylinder having a hollow formed therein; Operating rods respectively inserted into both sides of the cylinder and conveyed to the left and right to compress air; And a separation preventing hole formed at one end of the actuating rod and inserted into the mount member to prevent separation of the actuating rod.

As described above, the switchgear equipped with the seismic device according to the present invention effectively absorbs and mitigates the vibration or shock generated by the earthquake through the seismic device having multiple seismic structures. It has the effect of preventing damage.

1 is a front view showing a switchgear equipped with a seismic device according to the present invention.
Figure 2 is a front view showing a seismic device according to the present invention.
Figure 3 is a perspective view showing a seismic device according to the present invention.
Figure 4 is an exploded perspective view showing a seismic device according to the present invention.
Figure 5 is a front cross-sectional view showing a seismic device according to the present invention.
6 is an enlarged cross-sectional view showing a third buffer member according to the present invention.
7 is an enlarged view of the elastic body of the third buffer member according to FIG. 6.
8 is a view for explaining the operation of the seismic device according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a front view showing a switchgear equipped with a seismic device according to the present invention, Figure 2 is a front view showing a seismic device according to the present invention.

As shown in Figs. 1 and 2, the switchgear provided with the seismic device according to the present invention is a switchgear box 10, a seismic device 20 installed below the switchgear box 10 to absorb vibration or shock. In the switchboard comprising a, the seismic device 20 includes a lower support member 30, a first buffer member 40, an upper support member 50, a second buffer member 60, and a third buffer member 70 ).

Figure 3 is a perspective view showing a seismic device according to the present invention, Figure 4 is an exploded perspective view showing the seismic device according to the present invention, Figure 5 is a front cross-sectional view showing the seismic device according to the present invention.

3 to 5, the lower supporting member 30 is fixedly installed on the ground, and is preferably made of a metal or synthetic resin material having high strength.

In the lower support member 30, a curved portion 31 having a predetermined curvature is protruded at an upper portion thereof, and a coupling groove 32 in the form of an upper narrow beam is formed on the upper portion of the curved portion 31 in the longitudinal direction.

The coupling protrusion 42 of the first buffer member 40 is coupled to the coupling groove 32, and an adhesive may be filled in order to improve the coupling force with the coupling protrusion 42.

The lower support member 30 includes a support plate 33 to be fixed to the ground by fastening bolts, and a plurality of bolt holes 331 are formed in the support plate 33 to fasten bolts.

The lower support member 30 supports the first buffer member 40 installed to absorb vibration or shock caused by an earthquake, and the first buffer member 40 along the curved portion 31 of the lower support member 30 ) To induce compression change.

The first buffer member 40 is coupled to the upper portion of the lower support member 30 to absorb vibration or shock transmitted in a horizontal direction, and a first seating groove 41 corresponding to the curved portion 31 at the lower portion The coupling protrusion 42 is formed to be curved and corresponding to the coupling groove 32 is formed to protrude in the longitudinal direction.

The first buffer member 40 is made of a polyurethane foam having an elastic restoring force, and is formed in a shape having a predetermined curvature on an outer surface as well as an inner surface on which the first seating groove 41 is formed.

The first buffer member 40 is elastically deformed by a predetermined thickness with respect to the vibration transmitted in the vertical direction, and the thickness corresponding to the tangential direction of the curvature along the curved portion 31 for the vibration transmitted in the horizontal direction. As much as possible, elastic deformation occurs.

In particular, the first buffer member 40 causes a change in compression along the curved portion 31 to prevent resonance and warpage acting on the switchboard, and to secure a quick elastic restoring force while reducing friction between members for durability. Improves.

The upper support member 50 is made of a rectangular parallelepiped having a predetermined thickness, and a second seating groove corresponding to the upper portion of the first buffer member 40 at the lower portion so as to be coupled to the upper portion of the first buffer member 40 51 is formed to be curved.

The upper support member 50 is made of a hard synthetic resin material, and the lower part is closely coupled to the upper part of the first buffer member 40.

The upper support member 50 is not shown in the drawing, but is coupled to the curved portion 31 and the first buffer member 40 in the same structure.

The second buffer member 60 is installed on the upper support member 50 to absorb vibration or shock transmitted in the vertical direction, and includes a fixing plate 61 and a compression spring 62.

The fixing plate 61 is fastened and fixed to an upper portion of the upper support member 50 and a lower portion of the switchgear housing 10 with bolts, respectively.

The compression spring 62 is made of a soft rubber material, and is installed between the fixing plates 61 to absorb vibration or shock transmitted in a vertical direction.

The second buffer member 60 supports the switchgear housing 10 in normal times and acts elastically by the vibration transmitted in the vertical direction when an earthquake occurs. When the vibration is removed, the second buffer member 60 returns to its original state and vertically vibrates. By absorbing the vibrations transmitted to the switchgear housing 10 is minimized.

6 is a cross-sectional view showing an enlarged third buffer member according to the present invention.

As shown in Fig. 6, the third buffer member 70 is installed inside the second buffer member 60 to absorb the vibration and shock in the corresponding direction according to the direction in which the vibration or shock is transmitted, It includes a case 71, a support bracket 72, a mount member 73, and a vibration damping member 74.

The case 71 has an open upper receiving space and an elastic body 711 is installed therein.

The support bracket 72 is elastically supported by the elastic body 711, and a through hole 721 penetrating horizontally is formed.

The support bracket 72 is accommodated in the case 71 and is elastically supported by the elastic body 711, and the upper part is installed to be exposed to the outside of the case 71.

The mount member 73 is fixed to the upper inner side of the case 71 to elastically support the support bracket 72.

It is preferable that the mount member 73 is made of a rubber material, and one end of the operating rod 742 of the vibration damping member 74 is inserted to be transportable therein.

The mount member 73 is formed to surround a part of the vibration damping member 74 to prevent the vibration damping member 74 from being separated.

The vibration damping member 74 is installed between the mount members 73 to cancel or reduce vibrations or shocks transmitted in the horizontal direction.

The vibration damping member 74 is installed in the through hole 721 of the support bracket 72, is inserted into a cylinder 741 having a hollow inside, and is transferred to both sides of the cylinder 741, An operation rod 742 for compressing air and a separation prevention device 743 formed at one end of the operation rod 742 and inserted into the mount member 73 to prevent the operation rod 742 from being separated Includes.

When the vibration or shock is transmitted from the fixing plate 61 in the vertical direction, the third buffer member 70 configured as described above can absorb the vibration or shock by the elastic body 711 elastically supporting the support bracket 72. Absorbed.

In addition, when vibration or shock is transmitted in the horizontal direction, the mount member 73 supports both sides of the support bracket 72 and at the same time causes elastic deformation to absorb vibration and shock.

In addition, the case 71 is also shaken in a horizontal direction due to vibration or shock. At this time, the operating rods 742 supporting both sides of the case 71 are inserted into the inside of the cylinder 741 and the cylinder ( 741) is compressed, and vibration and shock are canceled or reduced by this air compression.

7 is an enlarged view of the elastic body of the third buffer member according to FIG. 6.

As shown in Figure 7, the elastic body 711 is provided in a plurality of bellows-shaped cover 711b having a spring 711a therein, and a plurality of the inside of the cover 711b. It includes a support ball (711c) made of a honeycomb structure for supporting the compressive load.

The cover 711b is formed of an elastic rubber material, and is formed in a bellows shape to be folded or unfolded when the spring 711a is compressed or restored.

The spring 711a serves to offset and reduce vibrations or shocks generated by the support bracket 72.

The support ball (711c) is preferably made of a polyurethane foam having an elastic restoring force, like the first buffer member (40).

As the air layer is formed by the honeycomb structure, the support ball 711c not only has a soundproof function, but also has the advantage of being strong against bending or compression.

The elastic body 711 minimizes the sudden operation of the support bracket 72 by vibration or shock transmitted when an earthquake occurs, thereby preventing the support bracket 72 from being damaged or noise generated.

8 is a view for explaining the operation of the seismic device according to the present invention.

As shown in FIG. 8, when vertical vibration is transmitted to the switchboard due to an earthquake or the like while supporting the switchboard housing 10, the second buffer member 60 in the vertical direction through the compression spring 62 It absorbs vibrations or shocks transmitted to it.

In addition, when the horizontal vibration is transmitted to the switchboard, the first buffer member 40 causes a compression change along the curved portion 31 and the thickness of the portion corresponding to the center in the width direction of the curved portion 31 gradually decreases.

The stiffness of the compression spring 62 is maintained through the compression change of the first buffer member 40 and absorbs the vibration transmitted in the horizontal direction, thereby preventing phenomena such as resonance and distortion acting on the switchboard.

In particular, as the first buffer member 40 is operated due to horizontal vibration and the elastic support 70 is also operated, the horizontal vibration concentrated on the first buffer member 40 is partially distributed to the first buffer member ( 40) is prevented from occurring.

On the other hand, through the third buffer member 70 installed inside the compression spring 62, it is possible to prevent damage to the switchgear by effectively absorbing and mitigating it in response to the direction in which vibration or shock is transmitted as well as in the vertical and horizontal directions. have.

Although the present invention has been described based on a preferred embodiment with reference to the accompanying drawings, it is apparent to those of ordinary skill in the art that various modifications are possible without departing from the scope of the present invention from this description. Accordingly, the scope of the invention should be interpreted by the claims set forth to include examples of such many modifications.

10: switchgear enclosure 20: seismic device
30: lower support member 31: curved portion
32: coupling groove 33: support plate
331: bolt ball
40: first buffer member 41: first seating groove
42: coupling protrusion
50: upper support member 51: second mounting groove
60: second buffer member 61: fixed plate
62: compression spring
70: third buffer member 71: case
711: elastic body 711a: spring
711b: cover 711c: support ball
72: support bracket 721: through hole
73: mount member 74: vibration damping member
741: cylinder 742: working rod
743: departure prevention port

Claims (5)

In the switchgear box comprising a switchgear box (10), a seismic device (20) installed below the switchgear box (10) to absorb vibration or shock,
The seismic device 20,
A lower support member 30 which is fixedly installed on the ground and has a curved portion 31 having a predetermined curvature protruding above the curved portion 31 and having a coupling groove 32 in the longitudinal direction above the curved portion 31 ;
It is coupled to the upper portion of the lower support member 30 to absorb vibration or shock transmitted in a horizontal direction, and a first seating groove 41 corresponding to the curved portion 31 is formed to be curved at the lower portion, and the coupling groove ( A first buffer member 40 having a coupling protrusion 42 corresponding to 32 protruding in the longitudinal direction;
An upper support member 50 coupled to an upper portion of the first buffer member 40 and having a second seating groove 51 corresponding to the upper portion of the first buffer member 40 curved at the lower portion thereof;
A second buffer member 60 installed on the upper support member 50 to absorb vibration or shock transmitted in a vertical direction, and
A third shock absorbing member 70 installed inside the second shock absorbing member 60 to absorb vibration and shock in a corresponding direction according to a direction in which the vibration or shock is transmitted;
Including,
The third buffer member 70,
A case 71 in which an upper open receiving space is formed and an elastic body 711 is installed therein;
A support bracket 72 that is elastically supported by the elastic body 711 and having a through hole 721 penetrating horizontally;
A mount member 73 that is fixed on the inner upper part of the case 71 to elastically support the support bracket 72; And
A vibration damping member 74 installed between the mount members 73 to cancel or reduce vibration or shock transmitted in the horizontal direction;
Switchgear provided with a seismic device comprising a.
The method of claim 1,
The first buffer member 40,
Switchgear provided with a seismic device, characterized in that made of polyurethane foam with elastic restoring force.
The method of claim 1,
The second buffer member 60,
A fixed plate 61 installed at an upper portion of the upper support member 50 and at a lower portion of the switchgear housing 10, and having a protruding hole having an open upper portion protruding;
A compression spring 62 installed between the fixed plates 61 to absorb vibration or shock transmitted in a vertical direction;
Switchgear provided with a seismic device, characterized in that it comprises a. delete The method of claim 1,
The vibration damping member 74,
A cylinder 741 installed in the through hole 721 of the support bracket 72 and having a hollow inside;
Operating rods 742 which are respectively inserted into both sides of the cylinder 741 and conveyed to the left and right to compress air; And
A separation prevention device 743 formed at one end of the actuating rod 742 and inserted into the mount member 73 to prevent separation of the actuating rod 742;
Switchgear provided with a seismic device comprising a.

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