KR101446890B1 - Antivibration pad and earthquake resistant switchgear provided with the same - Google Patents

Abstract

More particularly, the present invention relates to an upper and lower refracting type vibration damping pad, and more particularly, to an upper and lower refracting type vibration damping pad having an upper plate 10a and a lower plate 10b having respective space portions 15, A pair of bearings 20 which are formed so as to be recessed into the respective space portions 15 of the pair of bearings 10a and 10a so as not to be separated as the cover 25, A shaft 30 divided into a connecting spring 35 and an elastic tube 40 inserted between the side cover 25 and the shaft 30. The elastic tube 40 is inserted A compression spring 50 installed between the upper and lower plates 10a and 10b and a plurality of tension springs 60 connecting the upper and lower plates 10a and 10b to each other, The pad 1 and the earthquake-resistant switchboard 1 having the vibration-proof pad 1 are formed, It is possible to effectively absorb and cushion vibrations and shock acting in vertical and horizontal directions by vertically bending the pad 1 and ultimately to protect the switchboard S from an earthquake, This invention relates to an invention for preventing secondary disasters.

Description

TECHNICAL FIELD [0001] The present invention relates to a vertical vibration type vibration damping pad,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vertical vibration damping pad and a vibration damping pad provided at a lower portion of a power / And the shaft provided on the vibration-proof pad is divided into upper and lower bends. Thus, vibrations and shocks caused by seismic waves can be effectively absorbed and buffered, thereby protecting the power / communication equipment such as the power distribution board from earthquakes, And more particularly to an up-and-down refracting type vibration damping pad and an earthquake-resistant switchboard having the same, which can prevent a secondary disaster caused by interruption of power and communication in the event of a disaster such as an earthquake.

According to the meteorological statistics of Korea's earthquake occurrence, it is confirmed that not only the incidence of earthquakes continues to increase but also earthquakes with a magnitude of 5 or more are occurring periodically. It is also recognized that Korea is no longer a safe zone from earthquakes The government is also making efforts to protect people and property from natural disasters such as earthquakes by enacting or strengthening various laws such as 'Natural Disaster Countermeasures Act' and 'Earthquake Disaster Countermeasures Act'.

In this regard, a large number of disaster facilities such as large buildings and apartments are newly installed and expanded in order to minimize the damage when an earthquake occurs. However, a large number of the disaster facilities may become obsolete when electric power or communication is interrupted, And second communication disruption occurs. Therefore, seismic design for power / communication equipments such as electric motor control panel, distribution board, communication control panel, and the like, as well as a substation installed in a large building or an apartment are more important.

The applicant of the present invention, as an invention for solving the problems of the prior art, has been described in Patent Publication No. 1232336, entitled "Substructure of Switchboard with Vibration Pad for Switching & I will look at it.

The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide an apparatus and a method for assembling a shaft, A lower cap 330 which is fitted to both ends of the shaft 310 and is formed on both sides of the elastic packing 320 and a fastening member 330 which is fastened to both sides of the shaft 310, A plurality of elastic members 400 for vertically connecting the upper plate 100 and the lower plate 200 to each other, and an upper cap 340 coupled to the lower cap 330, .

In addition, in the above-mentioned prior invention, a space portion 332 is formed inside the lower cap 330, and an upper portion of the space portion 332 is formed in a lower portion of the lower cap 330 to facilitate the flow of the shaft 310 A bearing 331 is further provided.

The patented invention having the above-described structure can be easily fabricated with a simple structure, and it is possible to protect the transmission / reception section from vibration by the action of the elastic member 400 when an earthquake occurs, It is a useful invention that can maximize the stability of the switchboard by absorbing the pressure and weight of the switchboard in the home box, preventing the damage inside the switchboard.

However, in the case of the above-mentioned patented invention, the elastic packing 320 absorbs vibration and impact generated in the vertical direction at the time of occurrence of an earthquake, but the elastic packing 320 is insufficient to absorb vertical vibration alone, To absorb the force acting in the vertical direction. In addition, since the bearings 331 are formed at both ends of the shaft 310 to allow the shaft 310 to flow right and left, vibration and shock generated in the horizontal direction can be absorbed when an earthquake occurs. However, It is necessary to compensate to absorb the force acting in the horizontal direction effectively.

Registration No. 10-1139226 (April 26, 2012 announcement) Registration No. 10-1155995 (Announcement of Jun. 18, 2012)

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a power / communication facility installed in a large building or apartment, By forming an anti-vibration pad, it is possible to protect the switchboard from earthquakes by forming a vertical vibration pad that can effectively absorb and cushion vibration and shock acting in vertical and horizontal directions when an earthquake occurs. The present invention has been made to solve the above-mentioned problems.

According to another aspect of the present invention, there is provided a vertical vibration damping pad comprising: an upper plate and a lower plate having respective space portions; A pair of bearings, a shaft which is fastened to both ends of the pair of bearings and which is divided so that a connecting spring is interposed at an intermediate portion thereof, an elastic tube which is inserted between the both sides of the shaft and into which the shaft is inserted, A compression spring installed between the upper and lower plates, and a plurality of tension springs interconnecting the upper and lower plates.

According to the present invention, the upper and lower plates are connected to each other, and a safety bolt is fixed to the upper plate and the lower plate, And a spherical surface opposed to a lower surface of the lower plate is formed, wherein a ball is further interposed between the spherical surfaces.

According to another aspect of the present invention, there is provided an anti-vibration pad comprising: an upper plate of the anti-vibration pad mounted on a lower portion of an electric cabinet; and a lower plate disposed on a base fixed to a bottom surface of the anti- Another feature of the seismic switchboard with vertical and horizontal anti-vibration pads is that it can protect the switchboard from vibration and shock.

According to the present invention having the above-described structure, as the vibration-proof pad is vertically bent due to the configuration of the elastic tube provided to the vibration-proof pad, the plurality of tension springs, the compression spring, the connection spring and the divided shaft, (Including control panels, motor control panels, distribution boards, and communication control panels) installed in large buildings or apartments, and protects the switchboard from earthquakes. And further prevents damage to the power / communication equipment due to the earthquake, thereby preventing secondary disasters due to interruption of power and communication.

1 is a cross-sectional view showing a configuration of a vibration pad according to a conventional invention
Fig. 2 is a perspective view showing the vertical refraction type anti-vibration pad according to the present invention.
Fig. 3 is an exploded perspective view showing the vertical refraction type anti-vibration pad according to the present invention
4 is a cross-sectional view showing the vertical refraction type anti-vibration pad according to the present invention
5 is a sectional view showing an additional structure of the vertical refractive type vibration damping pad according to the present invention
FIG. 6 is a view showing the state of use of the anti-vibration switchboard having the anti-
FIGS. 7 and 8 are diagrams showing an operation state of the vertical refraction type anti-vibration pad according to the present invention

Hereinafter, the structure of the vertical vibration damping pad and the vibration damping switchboard having the same according to the preferred embodiment of the present invention will be described in detail with reference to FIGS. 2 to 6. First, the structure of the vertical vibration damping pad 1 will be described.

The vibration damping pad 1 according to the present invention has a top plate 10a and a bottom plate 10b formed in a disc shape on the upper and lower sides thereof and the upper and lower plates 10a and 10b are provided with a plurality of The mounting holes 11 are formed so that the upper plate 10a and the lower plate 10b can be separately installed on the distribution board S and the base B using the fixing bolts. A plurality of hooks 12 are formed on the upper and lower plates 10a and 10b so that a tension spring 60 to be described later can be mounted. A plurality of through holes 13 are formed in the through holes 10b and the hook holes 12 are inserted into the through holes 13 to fix the position.

Each space 15 is formed in the bottom surface of the upper plate 10a and the upper surface of the lower plate 10b so that the space 15 is formed as a hemispherical concave sliding surface .

A pair of bearings 20 are divided into the space portions 15 of the upper and lower plates 10a and 10b so that the bearings 20 have a shape corresponding to the sliding surface of the space portion 15 A bearing 21 is formed at the center of each of the bearings 20 and a bearing 20 is provided on both sides of the space 15 on the upper and lower plates 10a and 10b, (25) are formed. On the other hand, a through hole 26 communicating with the female threaded portion 21 of the bearing 20 is formed at the center of the both side cover 25.

As shown in the drawing, the shaft 30 is divided into an intermediate portion and a divided portion (not shown) of the shaft 30. The shaft 30 has a male screw portion 31 formed at both ends of the pair of bearings 20, It is possible to absorb and cushion the vibrations and shocks in the vertical direction applied to the shaft 30 by the interposition of the connecting springs 35. In addition, even when an external force in the horizontal direction is applied, the shaft 30 is vertically bent The restoring force of the rear connecting spring 35 acts to absorb and cushion vibration and shock in the horizontal direction.

The elastic tube 40 is formed between the side covers 25 of the upper and lower plates 10a and 10b so that the shaft 30 is inserted into the inner peripheral surface of the elastic tube 40, Vibration and shock acting in the vertical direction and the horizontal direction are absorbed and buffered by the elastic tube 40, together with the shaft 30 having the shaft 35. At this time, the elastic tube 40 is preferably made of a urethane material, but the present invention is not limited to the material of the elastic tube 40.

Particularly, between the upper plate 10a and the lower plate 10b, a compression spring (not shown) having a relatively strong elastic force is provided so as to support a load applied from the switchboard S and sufficiently absorb and cushion vibration and shock acting in a vertical direction, The elastic tube 40 having the shaft 30 inserted therein is inserted into the center of the compression spring 50. On the other hand, the compression spring 50 can absorb and buffer not only the external force acting in the vertical direction but also the external force acting in the horizontal direction like the other connection spring 35 and the elastic tube 40.

The upper plate 10a and the lower plate 10b are connected to each other by a plurality of tension springs 60. The tension springs 60 are engaged with the hooks 12 formed on the upper and lower plates 10a, And when the switchboard S on which the dustproof pad 1 is mounted is shaken or tilted, the switchboard S can be returned to its original position without being conducted by the restoring force of the tension spring 60. [

The upper and lower plates 10a and 10b of the vibration proof pad 1 according to the present invention are connected to each other by a tension spring 60. However, There is a possibility that the connection of the upper and lower plates 10a and 10b may be disassembled when an excessive external force acts on the vibration-proof pad 1. As a result,

A plurality of insertion holes 16 are formed in the upper plate 10a and a plurality of fastening holes 17 are formed in the lower plate 10b, And the other end of the safety bolt 70 passes through the insertion hole 16 to form a safety bolt 70 to which the nut 75 is fastened. The safety bolt 70 is not obstructed by the vibration absorbing action of the vertically bendable vibration pad 1 while the inner diameter of the insertion hole 16 is made larger than the outer diameter of the safety bolt 70, The connection of the upper and lower plates 10a and 10b can be safely maintained by the safety bolt 70 without being disassembled when an external force that can be absorbed by the dustproof pad 1 is applied to the dustproof pad 1. [

The safety bolt 70 of the present invention may be attached to the upper and lower plates 10a and 10b through the upper and lower plates 10a and 10b, (10a) and the lower plate (10b) when the upper plate (10b) is interconnected.

5, the upper surface of the base B fixed to the bottom surface of the building and the spherical surfaces 85a and 85b facing the lower surface of the lower plate 10b are recessed, By further interposing the balls 80 in the space between the spherical surfaces 85a and 85b, it is possible to maximize the absorption of the external force in the horizontal direction applied to the vibration-proof pad 1.

Hereinafter, a vibration damping pad (1) having the above-described configuration is first formed, and the vibration damping pad (1) The upper plate 10a of the pad 1 is mounted and the lower plate 10b of the vibration-proof pad 1 is installed on the base B fixed to the bottom surface of the building. S).

At this time, the switchboard (S) collectively refers to an electric motor control panel, a distribution panel, a communication control panel including a switchboard, and the like, and is not limited to a switchboard in a narrow sense, Means the power / communication facilities.

Hereinafter, the operation of the vertical refracting type vibration damping pad and the vibration damping switchboard having the same will be described with reference to FIGS. 4 to 8. FIG.

First, when vibrations and impacts occur in a vertical direction at the time of an earthquake, a plurality of elastic bodies such as the connection spring 35 of the vibration-proof pad 1, the elastic tube 40, and the compression spring 50 shown in FIG. The vibration damping pad 1 according to the present invention is provided with a plurality of elastic bodies of different kinds different from the conventional ones, so that it is possible to more effectively and sufficiently cope with the external force in the vertical direction.

7, the upper and lower centers of the upper plate 10a and the lower plate 10b of the vibration-proof pad 1 are deflected, and then, The resilient force of the connecting spring 35, the resilient tube 40 and the compression spring 50 and the tension of the tension spring 60 act effectively to absorb and buffer the external force in the horizontal direction. At this time, unlike the conventional art, the shaft 30 is divided, and the shaft 30 is smoothly operated without being disturbed by the upward / downward refraction of the vibration pad 1 due to the action of the bearing 20. [

8, when the switchboard S is shaken around the base end thereof by a complex external force transmitted to the switchboard S, the plurality of elastic bodies provided on the vibration-proof pad 1, The tension of the spring 60 allows the switchboard S to maintain its original position without being conducted.

5, when a ball 80 is further formed between the lower plate 10b of the vibration-proof pad 1 and the base B of the building bottom surface, the horizontal external force transmitted when the earthquake occurs and / The shake of the switchboard S can be more effectively absorbed. On the other hand, when the safety bolt 70 is additionally provided, the structure of the vibration-proof pad 1 can be stably maintained without being disassembled even if an external force that can be absorbed by the vibration-proof pad 1 is transmitted.

1: anti-vibration pad 10a: upper plate
10b: lower plate 15:
20: Bearing 25: Cover
30: shaft 35: connecting spring
40: elastic tube 50: compression spring
60: Tension spring 70: Safety bolt
80: balls 85a, 85b: spherical surface
B: Base S: Overall

Claims (4)

An upper plate 10a and a lower plate 10b having respective space portions 15;
A pair of bearings 20 formed in the space portions 15 of the upper plate 10a and the lower plate 10b so as not to be separated by the cover 25;
A shaft (30) divided at both sides of the pair of bearings (20) and having a connecting spring (35) interposed therebetween;
An elastic tube (40) inserted between the shafts (30) and between the side covers (25);
A compression spring 50 inserted between the upper plate 10a and the lower plate 10b with the elastic tube 40 inserted therein;
And a plurality of tension springs (60) connecting the upper plate (10a) and the lower plate (10b) to each other.
The method according to claim 1,
A safety bolt 70 is formed which is connected to the upper plate 10a and the lower plate 10b so as to be fluidly engaged with any one of the upper plate 10a and the lower plate 10b Up and down refraction type dustproof pad.
The method according to claim 1,
The upper surface of the base B fixed to the bottom surface of the building and the spherical surfaces 85a and 85b facing the lower surface of the lower plate 10b are formed, (80) is further interposed between the upper and lower vibration damping pads.
An earthquake-resistant switchboard comprising an upper and lower refracting type anti-vibration pad (1) constituted by any one of claims 1 to 3 between a lower portion of an earthquake-resistant switchboard (S) and a base (B)

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