KR102563269B1 - Earthquake-Resistant Mount for Distributing Board - Google Patents

Abstract

The present invention relates to a multi-purpose switchboard earthquake-resistant mount which has a damper for dampening vibration of a spring together with the spring for buffering an impact force caused by vibration of an earthquake to obtain safety of a switchboard when a natural disaster or earthquake occurs and can adjust a damping ratio of the damper.

Description

Earthquake-Resistant Mount for Distributing Board}

The present invention is provided with a damper for damping the vibration of the spring together with a spring for buffering the impact force caused by the vibration of the earthquake in order to secure the safety of the switchboard in the event of a natural disaster or earthquake, but a multi-purpose, characterized in that the damping ratio of the damper can be adjusted It is about the seismic mount of the switchboard.

Hereinafter, looking at the background art together with the accompanying drawings are as follows.

An earthquake is a phenomenon in which the earth's internal energy comes out to the surface and the ground cracks and shakes, and it acts as a load on buildings.

Earthquake loads are inertial forces resulting from ground motion, and loads can be concentrated on specific floors or specific structural members due to unexpected actions of non-structural elements or horizontal or vertical irregularities of buildings.

Therefore, all structures subject to earthquake-resistant design and their constituent members must have a certain strength that can withstand earthquakes, as well as ductility that can flexibly respond to earthquake shaking. .

Seismic design refers to a design that additionally considers seismic loads when designing so that a structure can maintain its safety and function even during an earthquake or after an earthquake occurs, but it is not designed to avoid damage from all expected earthquakes. It aims for the following three items.

Structural and non-structural members must not be damaged in small-scale earthquakes, non-structural members must be damaged and structural members must not be damaged in medium-scale earthquakes, and structural and non-structural members can be damaged in large-scale earthquakes, and structures collapse No personal injury should occur.

The mandatory earthquake-resistant design regulation was introduced in 1988, and the subject of mandatory earthquake-resistant design was a building with 6 floors or more or a total floor area of 100,000 or more. The application was expanded to 1,000 or more, and through a revision in 2015, earthquake-resistant design was made mandatory for all buildings with 3 floors or more or 500 or more.

In general, since the switchboard is bulky and heavy, it is installed on a lower frame and installed on a concrete foundation floor or a floor fixing plate.

Therefore, when an earthquake occurs in a building where these switchboards are installed, the panels are damaged. In the event of an earthquake, the size of the seismic force affecting the building varies depending on the structural characteristics such as the height, shape, and material of the building. It is necessary to protect against earthquakes, and to protect the panels, seismic mounts with seismic performance are required.

In particular, in areas where online/real-time processing systems are required, such as switchboards, especially in areas with a high level of publicity, there is a demand for earthquake resistance of advanced equipment as a countermeasure against earthquake damage in Korea, which is close to Japan, where earthquakes are frequent. desperate

Therefore, the Earthquake Disaster Countermeasures Act (Law No. 9636) and the Enforcement Decree of the Earthquake Disaster Countermeasures Act (Presidential Decree No. 21362) mandate the establishment of earthquake-resistant measures for all public buildings and facilities.

Existing seismic mounts in preparation for seismic forces are expensive devices focused on vibration prevention and attenuation, and in Korea, where earthquakes of a certain magnitude or more do not occur, there is a problem in that they are unnecessarily excessive facilities.

In addition, durability becomes a problem when only anti-vibration rubber pads or compression springs are used, and there is a problem that the switchboard installed on the top is overturned by the overturning moment.

In order to solve the above problem, in the conventional Patent Registration No. 10-1702449 (2017.01.26.), through the claim 1, "the lower frame (b1) of the switchboard (B) and the floor frame of the concrete foundation (A) In the seismic mount (C) installed at the corner between (a1) and absorbing vibration or shock to ensure the safety of the switchgear in the event of a natural disaster or earthquake, the seismic mount (C) is coupled to the floor frame (a1) a lower base iron plate part (1) that endures the external force caused by the dead weight and seismic force of the switchboard (B) and transmits the dead weight and seismic force of the switchboard (B) to the floor frame (a1); The lower base iron plate part ( An anti-vibration rubber pad part (2) installed on top of 1) to reduce the impact transmitted to the switchgear (B) and restore the displacement by attenuating the vertical displacement caused by vibration or seismic force with vibration absorbing power; It is installed in the inner center of the pad part 2 to reduce the impact transmitted to the switchboard (B) by damping the vertical displacement caused by vibration or seismic force with the elasticity of the spring like the anti-vibration rubber pad part (2) and displace A coil spring part 3 that restores and maintains the durability of the anti-vibration rubber pad part 2; It is formed on the upper part of the anti-vibration rubber pad part 2 and the coil spring part 3, and the switchboard ( An upper base steel plate part (4) coupled to the lower part of the lower frame (b1) of B) and transmitting the external force received by the switchboard (B) to the lower part; The lower frame (b1) of the switchboard (B) and the concrete foundation (A) By combining the bottom frame (a1) of ), the lower base iron plate part (1), the anti-vibration rubber pad part (2), and the upper base iron plate part (3) are vertically arranged to prevent separation, and the earthquake-proof mount (C) It consists of a connecting bolt stopper part 5 consisting of 3 to 5 connecting bolt stoppers 51 that overcomes the overturning moment received by internal force and limits the vertical displacement of the upper part of the earthquake-resistant mount (C), and the lower base iron plate part In the central part of (1), the coil spring part 3 is uniformly subjected to vibration or seismic force at the center, and the coil spring part 3 is fitted so that it is not separated from the inside of the anti-vibration rubber pad part 2. A coil spring support 11 having a height and a certain diameter is formed, and the lower base iron plate part 1 has a certain depth to prevent the anti-vibration rubber pad part 2 from departing from a certain position. A groove 12 and the same number of lower connection bolt stopper insertion holes 13 as the connection bolt stopper 51 into which the connection bolt stopper 51 is inserted from the bottom are formed, and the anti-vibration rubber pad part 2 consists of a plurality of anti-vibration rubber pads 21 to disperse seismic forces and improve durability, and the anti-vibration rubber pads 21 have a tensile strength of 20 MPa or more, an elongation of 500% or more, a hardness of 60 Hs or more, and a compression permanent The reduction rate is 35% [(100±1) ℃, 22Hr} or less, and the anti-vibration rubber pad 21 has a coil spring portion installation hole 211 into which the coil spring portion 3 is inserted and installed, and the connecting bolt stopper A plurality of pad connection bolt stopper passage holes 212 through which 51 passes are formed, and the coil spring part 3 is a cylindrical compression spring type to uniformly receive a compression load due to an earthquake force in the direction of the coil center line. , The limit of the repelling force of the coil spring part 3 is limited to the height of the anti-vibration rubber pad part 2 in order to maintain the durability of the anti-vibration rubber pad part 2, and in the upper base iron plate part 4 An upper anti-vibration rubber pad separation prevention groove 41 preventing the anti-vibration rubber pad part 2 from departing from a certain position, and an upper portion of the same number as the connection bolt stopper 51 through which the connection bolt stopper 51 passes. A connection bolt stopper passage hole 42 is formed, and the connection bolt stopper 51 is formed in succession to a bolt head 5111 caught on the lower base iron plate part 1 and the bolt head 5111, and a bolt having a male thread. a connecting bolt portion 511 composed of the main body 5112; It is inserted into the connection bolt part 511 to limit the vertical displacement of the earthquake-resistant mount (C) in the upper direction, and is composed of a stopper nut part 512 composed of two or more stopper nuts 5121 so as not to be loosened by vibration. , The lower base iron plate part 1, the anti-vibration rubber pad part 2, and the upper base iron plate part 4 facilitate the installation of the earthquake-resistant mount (C) and eliminate interference with the switchboard (B) for The two sides entering the lower frame (b1) of the switchboard (B) are cut into triangles in shape, and the coil spring support 11 is placed on the bottom upper surface of the lower base iron plate portion 1 to form the coil spring portion ( 3) is welded to the center of gravity so that it can receive an upper load or seismic force equally. It is made of flexible chloroprene rubber, and a female screw for screwing with the connecting bolt part 511 is formed inside the stopper nut 5121, and at a certain upper part of the bolt body 5112 A multipurpose switchboard anti-seismic mount using an anti-vibration pad is proposed, characterized in that a male screw 51121 for screwing with the stopper nut 5121 is formed.

However, the conventional Korean Patent Registration No. 10-1702449's multi-purpose switchboard earthquake-resistant mount reduces the impact transmitted to the switchboard (B) by attenuating the vertical displacement caused by vibration or seismic force with vibration absorbing power and restores the displacement. an anti-vibration rubber pad part 2; It is installed in the inner center of the anti-vibration rubber pad part 2 and damps the vertical displacement generated by vibration or seismic force with the elasticity of the spring like the anti-vibration rubber pad part 2, thereby reducing the impact transmitted to the switchboard B. The anti-vibration rubber pad part 2 is provided with a coil spring part 3 'which reduces the displacement, restores the displacement, and maintains the durability of the anti-vibration rubber pad part 2, so that the coil spring part 3 plays a role in alleviating shock and ) serves as a damper for damping the continuous vibration of the coil spring part 3, but because of the structure in which the damping ratio of the anti-vibration rubber pad part 2 serving as a damper cannot be adjusted, the average of the expected earthquake There is a problem in that it is not possible to properly select and install the anti-vibration rubber pad part 2 according to the intensity or maximum intensity.

Registered Patent No. 10-1702449 (2017.01.26.) Registered Patent No. 10-1941220 (2019.01.16.)

The multi-purpose switchboard earthquake-resistant mount of the present invention is intended to solve the following problems.

An object of the present invention is to provide a multi-purpose switchboard earthquake-proof mount having a damper for damping the vibration of the spring together with a spring for buffering the shock force caused by the vibration of an earthquake, and the damping ratio of the damper can be adjusted.

Another object of the present invention is to provide a damper for damping the vibration of the spring together with a spring for buffering the impact force caused by the vibration of the earthquake, but the damping ratio of the damper can be adjusted, and vibration in vertical, horizontal and inclined directions It is to provide a multi-purpose switchboard earthquake-proof mount that can withstand the impact force caused by the.

In order to solve the above problems, the multi-purpose switchboard earthquake-resistant mount of the present invention,

In the multi-purpose switchboard earthquake-proof mount installed between the corner of the lower frame of the switchboard and the concrete foundation (C) to absorb vibration or shock to ensure the safety of the switchboard in the event of a natural disaster or earthquake, on the lower side of the four corners A first concave groove (22h1) formed to be concave upward, and having a smaller diameter than the diameter of the first concave groove (22h1) and communicating with the first concave groove (22h1) to form an open top. A rectangular first frame 22 forming a through hole 22h2; and spaced apart from above the first frame 22 at a set interval, and perpendicular to the first through hole 22h2 at four corners. A rectangular second frame 23 having second through holes 23h arranged in a line; and a third through hole 27h formed perpendicularly in the center of the upper surface of the second frame 23. The damper 27 is disposed so that the third through hole 27h is vertically aligned with the second through hole 23h at the four corners; and a threaded portion is formed on the upper side to form the first concave groove 22h1 and the first , The bolt body 28a penetrating the two through holes 22h2 and 23h and the third through hole 27h and the lower end of the bolt body 28a are integrally formed on the upper surface of the first concave groove 22h1. A fastening device composed of a bolt composed of a bolt head 28c in contact with the surface of the first frame 22 and a nut 28b fastened to the threaded portion of the upper side of the bolt body 28a and in contact with the upper surface of the damper 27; And a spring 25 disposed around the bolt body 28a and installed between the first frame 22 and the second frame 23; and spaced apart from the top of the second frame 23 at a set interval And, at the four corners, a fourth through hole 24h1 is formed so that the bolt body of the bolt that can be coupled to the lower frame of the switchboard passes through, and a diameter larger than that of the fourth through hole 24h1 is formed at the center. The branch forms the fifth through hole 24h2, and through the cylindrical connection part 29 having a length longer than the length from the upper surface of the second frame 23 to the upper end of the bolt body 28a or the nut 28b. It includes a third frame 24 connected to the second frame 23, and the damper 27 is made of urethane material, and the damping ratio according to the fastening depth of the nut 28b to the threaded portion of the bolt body 28a It is characterized in that is controlled.

In another embodiment, the first frame 22 further includes an eighth through hole 22h formed in a funnel shape at the center of which a plate-shaped funnel head is located on the upper side, and the multi-purpose switchboard earthquake-proof mount , It is disposed on the concrete foundation (C) and forms a sixth through hole (21ah1) at the four corners, the upper side is open at the upper center and the lower side is formed in the shape of the lower half of the sphere. The rectangular lower frame 21a and the seventh through hole 21bh1 vertically aligned with the sixth through hole 21ah1 are formed at four corners, and the upper side is open at the upper center and toward the inside. A rectangular upper frame 21b in which a dish-shaped inclined concave groove 21b2 and a lower side communicate with the inclined concave groove 21b2 and a lower concave groove 21b1 formed in the shape of a part of the upper side of a sphere are formed. The lower and upper frames 21a and 21b include a bolt body B2 passing through the sixth and seventh through holes 21ah1 and 21bh1 and a bolt head integrally formed with the upper end of the bolt body B2. (B1) and a quadrangular fourth frame 21 coupled to each other by a nut N screwed to the threaded portion of the lower end of the bolt body B2; and a rod-shaped body 26a , The spherical rotary ball 26b formed integrally with the lower end of the body 26a and accommodated in the concave groove 21ah2 and the lower concave groove 21b1 to rotate, and the body 26a A connecting rod 26 formed integrally with the upper end and including a dish-shaped dish rotating body 26c that can rotate by being received or released from the funnel head above the eighth through hole 22h; and the body ( 26a) is disposed around the body 26a with the center in the center, and is located at a position corresponding to 1/2 to 2/3 of the length and width of the first frame 22 from the center of the first frame 22. It is characterized in that it further includes; a spring (S1) installed between the first frame 22 and the fourth frame 21 to support the frame 1 (22).

In another embodiment, in a multipurpose switchboard earthquake-proof mount installed between the corner portion of the lower frame of the switchboard and the concrete foundation (C) to absorb vibration or shock to ensure the safety of the switchboard in the event of a natural disaster or earthquake, It is disposed on the concrete foundation (C) and is formed to be concave upward from the lower side of the four corner parts, and a smaller diameter than the diameter of the first 'concave groove (21h1') A quadrangular 1st' frame 21' having a 1st' through hole 21h2' forming an open upper part in communication with the 1st' concave groove 21h1'; and four corners. A 6' through hole 22ah1' is formed in the upper portion, the upper side is open at the upper center, and the lower side is formed with a concave groove 22ah2' formed in the shape of the lower half of a sphere. ) and a 7th through hole 22bh1' vertically aligned with the 6th through hole 22ah1' at the four corners, the upper side being open at the upper center and inclined in a dish shape toward the inside. Including a rectangular upper frame 22b' in which an inclined concave groove 22b2' and a lower side communicate with the inclined concave groove 22b2' and a lower concave groove 22b1' formed in the shape of a part of the upper side of a sphere are formed. And, the lower and upper frames 22a' and 22b' are formed by the bolt body B2' passing through the 6' and 7' through holes 22ah1' and 22bh1' and the upper side of the bolt body B2'. A rectangular second frame 22 coupled to each other by a bolt head B1' formed integrally with the end and a nut N' screwed to the threaded portion of the lower end of the bolt body B2'. '); and a second' spaced apart from above the upper frame 22b' of the second' frame 22' at a set interval, and formed in a funnel shape with a dish-shaped funnel head in the center located on the upper side. A rectangular 3' frame 23' including a through hole 23h'; and spaced apart from above the 3' frame 23' at set intervals, and coupled to the lower frame of the switchboard at four corners. It forms a 4' through hole (24h1') formed so that the bolt body of the bolt that can be passed through, and has a larger diameter than the diameter of the 4' through hole (24h1') at the center of the 5' through hole (24h2 '), and through a cylindrical connecting portion 29' having a longer length than the length from the upper surface of the second 'frame 22' to the upper end of the bolt body 28a' or the nut 28b'. The 4th 'frame 24' connected to the 3rd 'frame 23'; and the rod-shaped body 26a', formed integrally with the lower end of the body 26a', and the concave groove ( 22ah2') and the spherical rotary ball 26b', which can be accommodated and rotated in the lower concave groove 22b1', and the upper end of the body 26a' and integrally formed with the second 'through hole 23h' A connecting rod 26' including a dish-shaped dish rotating body 26c' that can be accommodated or released from the funnel head on the upper side of the ); and the body 26a' at the center of the body ( 26a'), but at a position corresponding to 1/2 to 2/3 of the length and width of the 3' frame 23' from the center of the 3' frame 23', the 3' frame ( 23') installed between the 3' frame 23' and the 2' frame 22' (S1'); and the 1' frame 21' and the 2' frame. A spring 25' disposed around the bolt body 28a' between 22' and a 3' through hole 27h' perpendicular to the center, and the upper frame 22b' ) Damper 27 'disposed on the four corners of the upper surface; and a bolt body 28a' passing through the 6' and 7' through-holes 22ah1' and 22bh1' by forming threads on the upper side and the above A bolt composed of a bolt head 28c' integrally formed at the lower end of the bolt body 28a' and contacting the surface of the 1st' frame 21' contacting the upper surface of the 1st' concave groove 21h1'; A fastening device composed of a nut 28b' that is fastened to the threaded portion of the upper side of the body 28a' and in contact with the upper surface of the damper 27', wherein the damper 27' is made of a urethane material and has a bolt body 28a It is characterized in that the damping ratio is adjusted according to the fastening depth of the nut (28b') to the threaded portion of ').

The present invention has the following effects.

First, there is an effect of providing a multi-purpose switchboard earthquake-resistant mount having a damper for damping the vibration of the spring together with a spring for buffering the shock force caused by the vibration of the earthquake, but capable of adjusting the damping ratio of the damper.

Second, a damper for damping the vibration of the spring is provided together with a spring for buffering the shock force caused by the vibration of the earthquake, but the damping ratio of the damper can be adjusted, and at the same time, it can withstand the impact force caused by vibration in vertical, horizontal and inclined directions There is an effect of providing a versatile switchboard seismic mount that can be used.

1 is a perspective view illustrating that an earthquake-resistant mount for a multipurpose switchboard according to an embodiment of the present invention is installed between a lower surface of a switchboard and a concrete foundation.
FIG. 2 is a perspective view of an earthquake-proof mount for a multipurpose switchboard of FIG. 1 .
3 is a cross-sectional view taken along line AA of FIG. 2 .
4 is a perspective view of an earthquake-resistant mount for a multipurpose switchboard according to another embodiment of the present invention.
5 is a cross-sectional view taken along line A'-A' of FIG. 4;
6 is a longitudinal cross-sectional view of an earthquake-resistant mount for a multipurpose switchboard according to another embodiment of the present invention.

Hereinafter, the present invention will be reviewed with reference to the accompanying drawings, and the present invention will be described in detail in consideration of preferred embodiments.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in a variety of different forms, and only the present embodiments are intended to complete the disclosure of the present invention, and are common in the art to which the present invention belongs. It is provided to fully inform the knowledgeable person of the scope of the invention, and the invention is only defined by the scope of the claims. And, like reference numerals designate like elements throughout the specification.

(First embodiment)

1 is a perspective view showing that a multi-purpose switchboard earthquake-proof mount is installed between a lower surface of the switchboard and a concrete foundation according to an embodiment of the present invention, FIG. 2 is a perspective view of the multi-purpose switchboard earthquake-proof mount of FIG. 1, and FIG. 3 is a cross-sectional view along line A-A in FIG.

1 to 3, the multipurpose switchboard earthquake-resistant mount of the present invention is installed between the corner portion of the lower frame of the switchboard and the concrete foundation (C) to ensure the safety of the switchboard in the event of a natural disaster or earthquake, vibration or impact In the multipurpose switchboard earthquake-resistant mount that absorbs, the first frame 22, the second frame 23, the fastening device, the spring 25, the damper 27, and the third frame 24 include

The quadrangular first frame 22 has a first concave groove 22h1 formed to be concave upward from the lower side of the four corner portions and a diameter smaller than that of the first concave groove 22h1 and the first concave groove 22h1. A first through hole 22h2 communicating with the concave groove 22h1 and forming an open upper portion is formed. In the first embodiment, the rectangular first frame 22 is placed on the concrete foundation C to serve as a load supporter. In addition, the quadrangular second frame 23 is spaced apart from the top of the first frame 22 at a set interval, and the second through-holes are vertically aligned with the first through-holes 22h2 at four corners. (23h), and the damper 27 forms a third through hole (27h) perpendicular to the center, and the third through hole (27h) at the four corners of the upper surface of the second frame (23) It is arranged so as to be vertically aligned with the second through hole 23h, and is disposed at four corners of the upper surface of the second frame 23, and the fastening device forms a threaded portion on the upper side to form a first concave groove (22h1), the first and second through-holes (22h2, 23h), and the third through-hole (27h), the bolt body (28a) and the lower end of the bolt body (28a) is formed integrally with the first concave groove A bolt composed of a bolt head 28c in contact with the surface of the first frame 22 in contact with the upper surface of (22h1), and a nut 28b that is fastened to the threaded portion of the upper side of the bolt body 28a and in contact with the upper surface of the damper 27 The spring 25 is disposed around the bolt body 28a and is installed between the first frame 22 and the second frame 23, and the damper 27 is made of urethane The damping ratio is adjusted according to the fastening depth of the nut 28b to the threaded portion of the bolt body 28a.

According to the configuration, the damper 27 for damping the vibration of the spring 25 is provided together with the spring 25 for buffering the impact force caused by the vibration of the earthquake, but the damping ratio of the damper 27 can be adjusted. That is, the damper 27 is made of a urethane material, which is deformed when an external force is received and has an elastic restoring force to recover to its original state after the external force is removed, so that it can serve as a damper to damp vibration, so the spring ( 25) prevents breakage of the spring 25 due to excessive tension or compression to prevent the switchboard 10 from being overturned, and at the same time, when the nut 28b is fastened to the threaded portion of the bolt body 28a, the operator As the depth is adjusted, the damping ratio of the damper 27 can be adjusted, so that when the switchboard 10 receives the impact force caused by the vibration of the earthquake, the spring 25 primarily mitigates the shock and vibrates up and down. As a result, it is possible to control the frequency and duration of the vibration of the switchboard 10 by adjusting the frequency and duration of the vibration.

In another embodiment, in addition to the above configuration, it is also possible to further configure a washer w1 inserted around the bolt body 28a and disposed between the nut 28b and the damper 27. According to this configuration, when the nut 28b is fastened to the bolt body 28a, the damper 27 is prevented from being damaged by the nut 28b.

In another embodiment, in addition to the above configuration, it is fitted around the bolt body 28a and disposed between the bolt head 28c and the surface of the first frame 22 in contact with the upper surface of the first concave groove 22h1. It is also possible to additionally configure the spherical washer (w2) to be. According to this configuration, the first frame 22 and the second frame 23 spaced apart vertically and horizontally by the spherical washer w2 and the spring 25 coupled to the bolt body 28a flow in vertical and horizontal directions. Therefore, damage to the switchboard 10 can be minimized by effectively mitigating and absorbing the vibrations in the vertical, horizontal, and left-right directions acting on the switchboard 10 .

The third frame 24 is spaced above the second frame 23 at a set interval, and is formed at four corners so that the bolt body of the bolt that can be coupled to the lower frame of the switchboard passes through. A ball 24h1 is formed, and a fifth through hole 24h2 having a diameter larger than that of the fourth through hole 24h1 is formed at the center, and a bolt body 28a from the upper surface of the second frame 23 ) or the length to the upper end of the nut 28b is connected to the second frame 23 through a cylindrical connecting portion 29 having a longer length. According to this, the third frame 24 can be coupled to the lower frame of the switchboard with bolts (not shown) through the fourth through hole 24h1, and as a result, the multipurpose switchboard earthquake-resistant mount of the present invention is the lower frame of the switchboard It can be installed between the bottom of the concrete foundation (C). In addition, the third frame 24 forms a fifth through hole 24h2 having a larger diameter than the diameter of the fourth through hole 24h1 at the center thereof, so that the third frame 24 is in contact with the fifth through hole 24h2. It is possible to install one or more of a gyro sensor, a sensor for measuring the intensity of vibration, and a humidity sensor for measuring the humidity outside the switchboard on the surface of (24), and also the bolt body from the upper surface of the second frame (23). It is connected to the second frame 23 through a cylindrical connecting portion 29 having a length longer than the length to the upper end of (28a) or nut 28b, so that the third frame 24 and the second frame 23 By being able to secure a set interval or space between the nut 28b or bolt body 28a, the upper end of the third frame 24 is prevented from interfering with, and at the same time, the operator can secure the screw part of the upper side of the bolt body 28a To facilitate the work when fastening the nut (28b) to.

(Second embodiment)

Regarding the second embodiment, FIG. 4 is a perspective view of an earthquake-proof mount for a multipurpose switchboard according to another embodiment of the present invention, and FIG. 5 is a cross-sectional view taken along line A'-A' of FIG. 4 .

As shown in Figs. 4 and 5, the second embodiment further includes the following configurations in addition to the configurations of the first embodiment.

That is, in the second embodiment, the first frame 22 further includes an eighth through hole 22h formed in a funnel shape at the center of which a plate-shaped funnel head is located on the upper side, and the multi-purpose switchboard. The earthquake-resistant mount is disposed on the concrete foundation (C) and forms a sixth through hole (21ah1) at the four corners, the upper side is open at the upper center and the lower side is a concave groove formed in the shape of the lower half of the sphere ( 21ah2) is formed on the lower frame 21a, and the seventh through hole 21bh1 vertically aligned with the sixth through hole 21ah1 is formed at four corners, and the upper side is open at the upper center, A rectangular upper frame in which an inclined concave groove 21b2 inclined in a dish shape toward the inside and a lower concave groove 21b1 formed in the shape of an upper part of a sphere are formed in communication with the inclined concave groove 21b2 at the lower side ( 21b), wherein the lower and upper frames 21a and 21b are integrally with the bolt body B2 passing through the sixth and seventh through holes 21ah1 and 21bh1 and the upper end of the bolt body B2. A rectangular fourth frame 21 coupled to each other by a nut N screwed to a threaded portion of the lower end of the formed bolt head B1 and the bolt body B2; and a rod-shaped body ( 26a), a spherical rotary ball 26b formed integrally with the lower end of the body 26a and accommodated in the concave groove 21ah2 and the lower concave groove 21b1 to rotate, and the body ( 26a) integrally formed with the upper end of the funnel head portion of the upper side of the eighth through hole (22h) accommodating or unaccepting a connecting rod (26) including a dish-shaped rotating body (26c) capable of rotating; and Doedoe disposed around the body (26a) with the body (26a) in the center, corresponding to 1/2 to 2/3 of the length and width of the first frame (22) from the center of the first frame (22) A spring (S1) installed between the first frame 22 and the fourth frame 21 to support the first frame 22 in position; further includes.

According to the above configuration, due to shock or vibration generated during natural disasters or earthquakes, the connecting rod 26 is centered on the rotary ball 26b in a range of a portion of the upper hemisphere (eg, a vertical axis passing through the center of the rotary ball 26b). It can rotate freely in the angular range of 35 ° to 55 ° around the center), and according to this rotation, the spring S1 receives the force applied from the top to the bottom from the first frame 22 and vibrates while mitigating the first shock. These vibrations are attenuated by the damper 27, and the dish-shaped dish rotating body 26c is configured to rotate by being received or released from the funnel head above the eighth through hole 22h. Force applied from the first frame 22 moving together with the switchboard 10 when force is applied to the spring S1 as the first frame 22 tilts in a specific direction due to shock or vibration generated during a disaster or earthquake The upper surface of the spring S1, at least one part of the body 26a of the connecting rod 26 and the rotating plate 26c, and the concave groove 21ah2 in contact with the rotary ball 26b of the connecting rod 26 and the lower side Distributed and applied to the surfaces of the lower and upper frames 21a and 21b in contact with the concave groove 21b1, it is possible to prevent the spring S1 from being damaged while the first frame 22 is overturned along with the switchboard 10. there is.

(Third Embodiment)

Regarding the third embodiment, FIG. 6 is a longitudinal cross-sectional view of an earthquake-proof mount for a multipurpose switchboard according to another embodiment of the present invention.

As shown in FIG. 6, the multipurpose switchboard earthquake-resistant mount according to the third embodiment is installed between the corner of the lower frame of the switchboard and the concrete foundation (C) to ensure the safety of the switchboard in the event of a natural disaster or earthquake. In a multi-purpose switchboard earthquake-resistant mount that absorbs vibration or shock, a 1' frame 21', a 2' frame 22', a 3' frame 23', and a 4' frame 24 '), a connecting rod 26', a damper 27', and a fastening device.

The quadrangular 1st' frame 21' is disposed on the concrete foundation C, and the 1st' concave groove 21h1' formed to be concave upward from the lower surface of the four corner parts, and the first 'concave groove 21h1' A first' through hole 21h2' having a diameter smaller than that of the concave groove 21h1' and communicating with the first' concave groove 21h1' forms an open top. The first 'frame 21' is disposed on the concrete foundation C to serve as a load supporter. The quadrangular 2nd 'frame 22' forms a 6th 'through hole 22ah1' at the four corners, the upper side is open at the upper center, and the lower side is a concave groove formed in the shape of the lower half of the sphere ( 22ah2') is formed on the lower frame 22a' of a quadrangle, and the 7th through hole 22bh1' vertically aligned with the 6th through hole 22ah1' is formed at four corners, and the upper center is formed. An inclined concave groove (22b2') whose upper side is open and inclined in a saucer shape toward the inside and a lower concave groove (22b1') formed in the shape of a part of the upper part of the sphere by communicating with the inclined concave groove (22b2') and the lower side thereof The lower and upper frames 22a' and 22b' are bolt bodies passing through the 6' and 7' through holes 22ah1' and 22bh1'. (B2') and the bolt head (B1') formed integrally with the upper end of the bolt body (B2') and the nut (N') screwed into the thread forming portion of the lower end of the bolt body (B2') by, are interconnected. As described above, the rectangular lower frame 22a' and the rectangular upper frame 22b' of the rectangular 2' frame 22' are bolts passing through the 6' and 7' through holes 22ah1' and 22bh1'. A bolt head (B1') integrally formed with the upper end of the body (B2') and the bolt body (B2') and a nut (N') screwed into the threaded portion of the lower end of the bolt body (B2') By, since they are mutually coupled, when first assembling, the lower side of the rotary ball 26b', which will be described later, is accommodated in the lower concave groove 22b1', and in that state, the upper frame 22b' relative to the lower frame 22a' ) When coupled, the rotating ball 26b' is rotatably accommodated in the lower concave groove 22b1' and the inclined concave groove 22b2'. In addition, the quadrangular 3' frame 23' is spaced apart from the upper frame 22b' of the 2' frame 22' at a set interval, and has a dish-shaped funnel head at the center. It includes a second 'through hole 23h' formed in a funnel shape located on the upper side, and the connecting rod 26' is formed integrally with the rod-shaped body 26a' and the lower end of the body 26a'. It is formed integrally with the upper end of the concave groove (22ah2') and the lower concave groove (22b1') and the spherical rotary ball (26b') that can rotate by being accommodated in the lower concave groove (22b1'), the second It includes a dish-shaped dish rotating body 26c' that can be accommodated or released from the funnel head above the through hole 23h' and rotated, and the damper 27' is the body 26a' Doedoe placed around the circumference of the body (26a ') with the center in the center, corresponding to 1/2 to 2/3 of the length and width of the 3' frame (23') from the center of the 3' frame (23') A spring S1' installed between the 3' frame 23' and the 2' frame 22' to support the 3' frame 23' in position; and the 1' frame 21 A spring 25' disposed around the bolt body 28a' between the ') and the second 'frame 22'; and a third 'through hole 27h' perpendicular to the center. , It is disposed on four corners of the upper surface of the upper frame 22b ', and the fastening device forms a threaded portion on the upper side of the bolt body passing through the 6' and 7' through holes 22ah1' and 22bh1' ( 28a') and the bolt head 28c' that is integrally formed with the lower end of the bolt body 28a' and is in contact with the surface of the 1st 'frame 21' in contact with the upper surface of the 1st' concave groove 21h1'. It is composed of a bolt and a nut 28b' that is fastened to the threaded portion on the upper side of the bolt body 28a' and contacts the upper surface of the damper 27', and the damper 27' is made of urethane, so that the bolt body 28a' ), the damping ratio is adjusted according to the fastening depth of the nut 28b' to the threaded portion.

According to the configuration, a damper 27' for damping the vibration of the spring 25' is provided together with a spring 25' for buffering the impact force caused by the vibration of the earthquake, but the damping ratio of the damper 27' can be adjusted there is. In other words, since the damper 27' is made of urethane material, it can function as a damper that damps vibration, so that breakage of the spring 25 due to excessive tension or compression of the spring 25 is prevented, thereby preventing the switchboard 10 from falling. At the same time, when the nut 28b is fastened to the threaded part of the bolt body 28a, the damping ratio of the damper 27' can be adjusted as the operator adjusts the fastening depth, so that the switchboard 10 can When the spring (25') vibrates up and down while primarily relieving the impact by receiving the impact force by the spring (25'), it is to control the frequency and vibration time of the switchboard (10) as a result. it becomes possible In addition, according to the above configuration, the connecting rod 26' can freely rotate in the range of the upper hemisphere around the rotating ball 26b' due to shock or vibration generated during a natural disaster or earthquake, and according to this rotation The spring S1' receives the force applied from the top to the bottom from the 3' frame 23' and vibrates while mitigating the first shock, but this vibration is damped by the damper 27', and the dish-shaped plate circuit The entire 26c' is configured to be accommodated or released from the funnel head above the eighth through hole 22h' and rotated, so that the 3' frame ( 23') tilts in a specific direction and applies force to the spring S1', the force applied from the 3' frame 23' moving along with the switchboard 10 is applied to the upper surface of the spring S1' and the connecting rod. A concave groove 21ah2' and a lower concave groove 22b1 in contact with at least one part of the body 26a' and the plate rotating body 26c' of (26') and the rotary ball 26b' of the connecting rod 26'. ') is distributed and applied to the surfaces of the lower and upper frames 22a' and 22b' in contact with the switchboard 10 to prevent the spring S1' from being damaged while the third' frame 23' is overturned. can do.

The 4' frame 24' is spaced apart from the top of the 3' frame 23' at a set interval, and is formed so that bolt bodies of bolts that can be coupled to the lower frame of the switchboard pass through at four corners. A 4' through hole 24h1' is formed, a 5' through hole 24h2' having a larger diameter than the diameter of the 4' through hole 24h1' is formed at the center, and a 2' frame is formed. It is connected to the 3rd frame 23' through a cylindrical connection part 29' having a length longer than the length from the upper surface of the 22' to the upper end of the bolt body 28a' or the nut 28b' there is. According to this, the 4' frame 24' can be coupled to the lower frame of the switchboard 10 with bolts (not shown) through the 4' through hole 24h1', resulting in the multipurpose switchboard of the present invention. The earthquake-resistant mount can be installed under the lower frame of the switchboard and between the concrete foundation (C). In addition, the 4' frame 24' forms a 5' through hole 24h2' having a larger diameter than the diameter of the 4' through hole 24h1' at the center, so that the 5' through hole (24h1') is formed. It is possible to install at least one of a gyro sensor, a sensor for measuring the intensity of vibration, and a humidity sensor for measuring the humidity outside the switchboard on the surface of the 4' frame 24' in contact with 24h2'). Connected to the second frame 23 through a cylindrical connection part 29 'having a length longer than the length from the upper surface of the 2' frame 22' to the upper end of the bolt body 28a' or the nut 28b' It is possible to secure a set interval or space between the 4' frame 24' and the 3' frame 23', so that a part of the body 26a' of the connecting rod 26' and the plate rotating body ( 26c') protrudes into the set interval or space to enable rotation and vertical movement of the 3' frame 23'.

In another embodiment, in addition to the above configuration, it is also possible to further configure a washer (w1') inserted around the bolt body (28a') and disposed between the nut (28b') and the damper (27') . According to this configuration, when the nut 28b' is fastened to the bolt body 28a', the damper 27' is prevented from being damaged by the nut 28b'.

In another embodiment, in addition to the above configuration, the surface of the 1st 'frame 21' in contact with the upper surface of the 1st' concave groove 21h1' by being fitted around the bolt body 28a' and the bolt head 28c It is also possible to additionally configure a spherical washer (w2') disposed between the '). According to this configuration, the first 'frame 21' and the second' frame 22' spaced apart vertically by the spherical washer w2' and the spring 25' coupled to the bolt body 28a' Since it can flow in vertical and horizontal directions, damage to the switchboard 10 can be minimized by effectively mitigating and absorbing vibrations acting on the switchboard 10 in up, down, front and rear, and left and right directions.

In all the embodiments described above, the multipurpose switchboard earthquake-resistant mount of the present invention is shown and described as being applied to the switchboard 10, but the present invention is not limited thereto and is applied to the switchboard 10 in other embodiments. In addition, it can be applied or used to other structures requiring earthquake resistance (eg, electrical structures such as transformers, generators, rectifiers, UPS, etc.).

The present invention described above has been described with reference to the first embodiment shown in the drawings, but this is only exemplary, and those skilled in the art can make various modifications and equivalent other embodiments therefrom. point should be made clear. Therefore, the true technical protection scope of the present invention should be construed by the appended claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

10. Switchboard 21. 4th frame
21'. 1' frame 21a. lower frame
21ah1. 6th through hole 21ah2. groove
21 b. Upper frame 21b1. lower concave groove
21b2. Inclined concave groove 21bh1. 7 through hole
21h1'. 1' concave groove 21h2'. 1st' through hole
22. First frame 22'. 2nd' frame
22a'. lower frame 22ah1'. 6' through hole
22ah2'. recessed groove 22b'. upper frame
22b1'. Lower concave groove 22b2'. Inclined concave groove
22bh1'. 7' through hole 22h. 8th through hole
22h1. First concave groove 21h1'. 1' concave groove
22h2. 1st through hole 23. 2nd frame
23'. 3' frame 23h. 2nd through hole
23h'. 2nd 'through hole 24. 3rd frame
24'. 4th frame 24h1. 4th through hole
24h1'. 4th' through hole 24h2. 5 through hole
24h2'. 5' through hole 25. Spring
26, 26'. connecting rods 26a, 26a'. body
26b, 26b'. Rotary balls 26c, 26c'. rotating dish
27, 27'. Damper 27h. 3rd through hole
27h'. 3' through hole 28a. bolt body
28b, 28b'. Nuts 28c, 28c'. bolt head
29, 29'. Cylindrical connections B1, B1'. bolt head
B2, B2'. Bolt body C. Concrete foundation
N, N'. Nuts S1, S1'. spring

Claims (3)

delete In the multi-purpose switchboard earthquake-proof mount installed between the corner of the lower frame of the switchboard and the concrete foundation (C) to absorb vibration or shock to ensure the safety of the switchboard in the event of a natural disaster or earthquake,
A first concave groove (22h1) formed to be concave upward from the lower surface of the four corner portions, and having a smaller diameter than the diameter of the first concave groove (22h1) and communicating with the first concave groove (22h1) to open A rectangular first frame 22 forming a first through hole 22h2 forming an upper portion; and
A quadrangular second frame spaced apart from the first frame 22 at a set interval and having second through holes 23h vertically aligned with the first through holes 22h2 at four corners. (23); and
A third through hole 27h is formed vertically in the center, and the third through hole 27h is vertically aligned with the second through hole 23h at four corners of the upper surface of the second frame 23. and a damper 27 disposed thereon;
The bolt body 28a passing through the first concave groove 22h1, the first and second through holes 22h2 and 23h, and the third through hole 27h by forming a threaded portion on the upper side and the bolt body 28a A damper ( 27) a fastening device consisting of a nut 28b in contact with the upper surface; and
A spring 25 disposed around the bolt body 28a and installed between the first frame 22 and the second frame 23; and
A fourth through-hole 24h1 is formed above the second frame 23 at a set interval and formed so that the bolt body of the bolt that can be coupled to the lower frame of the switchboard passes through at the four corners, The fifth through hole 24h2 having a diameter larger than that of the fourth through hole 24h1 is formed in the upper surface of the second frame 23 to the upper end of the bolt body 28a or the nut 28b. And a third frame 24 connected to the second frame 23 through a cylindrical connecting portion 29 having a length greater than the length of
The damper 27 is made of urethane, and the damping ratio is adjusted according to the fastening depth of the nut 28b to the threaded portion of the bolt body 28a .

The first frame 22 further includes an eighth through hole 22h formed in a funnel shape in which a dish-shaped funnel head is located on the upper side in the center,
The multi-purpose switchboard earthquake-resistant mount,
It is disposed on the concrete foundation (C) and forms a sixth through hole (21ah1) at the four corners, and a concave groove (21ah2) is formed in the upper center, the upper side is open, and the lower side is formed in the shape of the lower half of the sphere. A rectangular lower frame 21a and a seventh through hole 21bh1 vertically aligned with the sixth through hole 21ah1 are formed at four corners, and the upper side is open at the upper center and the dish goes inward. Including a rectangular upper frame 21b in which an oblique concave groove 21b2 inclined in the shape and a lower concave groove 21b1 formed in the shape of a part of the upper side of a sphere are formed by communicating with the inclined concave groove 21b2 and the lower side thereof. And, the lower and upper frames 21a and 21b are formed integrally with the upper end of the bolt body B2 and the bolt body B2 penetrating the sixth and seventh through holes 21ah1 and 21bh1, and the bolt head ( B1) and a quadrangular fourth frame 21 coupled to each other by a nut N screwed to a threaded portion of the lower end of the bolt body B2; and
A rod-shaped body 26a and a spherical rotary ball 26b integrally formed with the lower end of the body 26a and accommodated in the concave groove 21ah2 and the lower concave groove 21b1 to rotate and a dish-shaped dish rotating body 26c formed integrally with the upper end of the body 26a and accommodated or released from the funnel head above the eighth through hole 22h to rotate. (26); and
Doedoe disposed around the body (26a) with the body (26a) at the center, corresponding to 1/2 to 2/3 of the length and width of the first frame (22) from the center of the first frame (22) A multi-purpose switchboard earthquake-proof mount further comprising a spring (S1) installed between the first frame (22) and the fourth frame (21) to support the first frame (22) in position. In the multi-purpose switchboard earthquake-proof mount installed between the corner of the lower frame of the switchboard and the concrete foundation (C) to absorb vibration or shock to ensure the safety of the switchboard in the event of a natural disaster or earthquake,
It is disposed on the concrete foundation (C) and is formed to be concave upward from the lower side of the four corner parts, and a smaller diameter than the diameter of the first 'concave groove (21h1') A quadrangular 1st' frame 21' having a 1st' through hole 21h2' forming an open top in communication with the 1st' concave groove 21h1'; and
A rectangular lower frame having a 6' through hole 22ah1' formed at the four corners, an upper side open at the upper center, and a concave groove 22ah2' formed in the shape of the lower half of a sphere at the lower side ( 22a') and the 7th through-hole 22bh1' vertically aligned with the 6th through-hole 22ah1' at the four corners, the upper side being open at the upper center, and the plate shape toward the inside. A rectangular upper frame (22b') having an inclined inclined concave groove (22b2') and a lower concave groove (22b1') formed in the shape of a part of the upper side of a sphere by communicating with the inclined inclined concave groove (22b2') on the lower side. The lower and upper frames 22a' and 22b' include a bolt body B2' passing through the 6' and 7' through holes 22ah1' and 22bh1' and the bolt body B2'. A rectangular second frame coupled to each other by a bolt head (B1') integrally formed with the upper end of the bolt body (B2') and a nut (N') screwed into the thread forming portion of the lower end of the bolt body (B2'). (22'); and
The 2nd' through hole 23h formed in a funnel shape spaced above the upper frame 22b' of the 2' frame 22' at a set interval and having a dish-shaped funnel head in the center located on the upper side. A rectangular third 'frame 23' including '); and
4th through-holes 24h1' spaced above the 3rd frame 23' at set intervals and formed so that bolt bodies of bolts that can be coupled to the lower frame of the switchboard pass through at four corners; Forming a 5' through hole (24h2') having a larger diameter than the diameter of the 4' through hole (24h1') at the center, and forming a bolt body from the upper surface of the 2' frame (22') ( 28a') or a 4' frame 24' connected to the 3' frame 23' through a cylindrical connecting portion 29' having a length longer than the length to the top of the nut 28b'; class
The rod-shaped body 26a' and the lower end of the body 26a' are integrally formed and are accommodated in the concave groove 22ah2' and the lower concave groove 22b1' to rotate in a spherical shape. The ball 26b' is formed integrally with the upper end of the body 26a' and is accommodated in or released from the funnel head above the 2nd' through hole 23h' to rotate. A connecting rod (26') including the whole (26c'); and
The body (26a') is disposed around the body (26a') with the body (26a') at the center, and the length and width of the 3' frame (23') from the center of the 3' frame (23') is 1/2 to 1/2 of the width. A spring (S1') installed between the 3' frame 23' and the 2' frame 22' to support the 3' frame 23' at a position corresponding to 2/3; and
A spring 25' disposed around the bolt body 28a' between the first 'frame 21' and the second' frame 22'; and
A damper 27' having a 3' through hole 27h' vertically formed in the center and disposed at four corners of the upper surface of the upper frame 22b'; and
The bolt body 28a' passing through the 6' and 7' through-holes 22ah1' and 22bh1' by forming a threaded portion on the upper side and the lower end of the bolt body 28a' are integrally formed with the first' yoke. A bolt composed of a bolt head 28c' in contact with the surface of the 1st 'frame 21' in contact with the upper surface of the inlet groove 21h1' and fastened to the threaded portion of the upper side of the bolt body 28a' to form a damper 27'Including; fastening device consisting of a nut (28b') in contact with the upper surface,
The damper (27') is made of urethane material and the damping ratio is adjusted according to the fastening depth of the nut (28b') to the threaded portion of the bolt body (28a').