KR102030959B1 - Earthquake proof apparatus for electric control box - Google Patents

Abstract

The present invention relates to a seismic device for an electric control enclosure, which is provided with a seismic means to prevent secondary damage such as power failure and fire generated when power distribution equipment is damaged during an earthquake. The seismic device comprises: a square contact plate (10) disposed on a mounting plate (B) of the electrical control enclosure (A) and having an upper end protrusion (11); a vertical bolt (20) provided by vertically penetrating a central portion of the upper end protrusion (11); a vertical spring (30) fitted to the vertical bolt (20); a fitting member (40) mounted on an upper end of the vertical bolt (20); a vertical placement plate (50) attached to a rear surface of the fitting member (40); a pair of horizontal bolts (60) provided through the vertical placement plate (50); and a plurality of elastic force adjustment springs (70) provided on both sides of a lower portion of the upper end protrusion (11) at both sides of the vertical bolt (20) and fixed by a vertical pin (71).

Description

EARTHQUAKE PROOF APPARATUS FOR ELECTRIC CONTROL BOX}

The present invention relates to an earthquake resistant device installed and used in an electrical control enclosure, and more particularly, to provide secondary damage such as a power failure and a fire caused by damage of various electric and electronic equipment installed on the installation plate in the event of an earthquake. An earthquake resistant device for an electrical control enclosure is provided.

In general, the electric control enclosure is provided with an installation plate inside the enclosure such as an electric control panel, a control box, a distribution box, a control box, a distribution panel, an electric enclosure, a distribution enclosure, a control enclosure, and the like. This will be installed.

For example, an electrical control enclosure such as a distribution panel is provided with various circuit breakers and switchgear in the enclosure to draw power from outside and to selectively supply power. Such a distribution panel includes a housing for preventing electric shock and safety accidents caused by various electricity in order to prevent the line from being exposed to the outside.

In particular, the distribution panel includes a circuit breaker in order to achieve electrical safety by cutting off the current supply in the event of overload in the process of distributing the main power drawn from the outside to each electric load. Such breakers may include a main breaker connected to the main input terminal and a plurality of branch breakers respectively connected to an electrical load.

Such an electrical control enclosure has an exterior type which is directly fixed to a wall through a built-in type embedded in the wall of the building and anchor bolts, and there is a ground type that is installed on the ground. However, in the case of the external type of the electrical control enclosure is fixed to the wall because the back of the enclosure is fixed to the wall using a bolt structure that penetrates the wall when the enclosure is fixed to the wall when installed. This structure may appear to be a stable structure at first glance because the electrical control enclosure is in close contact with the wall, but has a disadvantage of being vulnerable to vibration or moisture.

In particular, since the electrical control enclosure such as a distribution board is tightly fixed to the wall through the bolt structure, when vibration is transmitted through the wall during the earthquake, the vibration is transmitted to the inside of the enclosure through the bolt structure fixed to the wall. As a result, vibrations are transmitted to the inner structure of the enclosure, which causes screws or other structures to fix various electrical and electronic components, control components, and circuit devices to be released from their positions, and there is a concern that secondary damage may occur due to power failure and fire. .

Registered Patent No. 1139226 "Divided Distribution Board with Seismic and Dustproof Functions" (2012.04.10.)

Accordingly, the present invention has been made to solve the conventional problems as described above,

SUMMARY OF THE INVENTION An object of the present invention is to provide an earthquake-proof device for an electric control enclosure having seismic means so that secondary damage such as a power failure and a fire that occurs when various electric and electronic equipments installed on an installation plate are damaged during an earthquake can be prevented. .

In order to achieve the above object, the "earthquake resistant device for an electrical control enclosure" according to the present invention is a rear surface of the installation plate with a lower portion of the upper bent jaw formed to be bent at the upper end of the installation plate installed inside the electrical control enclosure. It is provided in close contact with the upper end is bent inward so as to be in close contact with the bottom of the upper bending jaw is formed with a top projection jaw, the bottom projection jaw projecting horizontally corresponding to the top projection jaw is attached to the bottom bottom square Plate; The first fixing nut is vertically provided to slidably penetrates the upper and lower projection jaw in the center of the upper end of the square contact plate, the thread is formed on the outer peripheral surface, the first fixing nut is in close contact with the lower surface of the lower projection jaw A vertical bolt screwed to the bottom; A vertical spring disposed between the upper protrusion protrusion and the lower protrusion protrusion while being fitted to the first fixing nut; It is fitted to the vertical bolt exposed to the upper portion of the upper projection jaw, the lower end is fixed by a second fixing nut screwed to the vertical bolt, the upper end is screwed to the upper end of the vertical bolt third fixing nut A fitting member fixed by the; A vertically placed plate vertically attached to the rear surface of the fitting member and vertically penetrating from the outer surface to both sides of the fitting member to form a pair of vertical through holes; A pair of fourth fixing nuts which are slidably inserted into the vertical through holes, are horizontally attached to the inner surface of the electrical control enclosure, have a thread formed on the outer circumferential surface, and are screwed forward of the vertically disposed plate; A pair of horizontal bolts; It is characterized by including.

In addition, the "earthquake resistant device for an electrical control enclosure" according to the present invention has a vertical pin that is slidably penetrates the upper projection and the lower projection by a plurality of vertically, and the upper projection and the lower projection of the lower projection A plurality of elastic force adjustment springs disposed therebetween and selectively fitted to the vertical pins to adjust elastic support force; It further comprises.

In addition, the square contact plate of the "earthquake resistance device for an electrical control enclosure" according to the present invention is formed so that the lower end of the square contact plate is horizontally bent and protrudes from the lower side of the lower projection so that the vertical pin is penetrated. Further comprising a pair of mounting protrusions and a pair of mounting portions for fastening the upper protrusion jaw to the lower surface of the upper bent jaw while being fastened through the upper bent jaw from both lower surfaces of the upper protrusion jaw to the upper portion. It is done.

As described above, the present invention is provided with an earthquake-proof means, the power distribution equipment is damaged during the earthquake can be prevented the occurrence of secondary damage such as power failure and fire, thereby having an effect that the safety of use is significantly improved.

1 is a schematic perspective view of a seismic device according to the present invention;
2 is a schematic rear perspective view of the seismic device according to the present invention;
3 is a schematic front view of FIG. 2;
4 is a schematic perspective view of an electric control enclosure in which a seismic device is installed according to the present invention;
5 is a schematic partial exploded rear perspective view of the electric control enclosure in which the seismic device is installed according to the present invention;
Figure 6 is a schematic exploded perspective view of the main portion of the electric control enclosure is installed seismic device according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the present invention may be embodied in many different forms and should not be limited to the described embodiments.

1 to 6 are schematic views of a seismic device according to the present invention. As shown therein, the earthquake resistance device for an electrical control enclosure according to the present invention is disposed on the mounting plate (B) of the electrical control enclosure (A) and has a square contact plate (10) having an upper projection jaw (11), and the upper end Vertical bolt 20 provided through the center portion of the protruding jaw 11 vertically, the vertical spring 30 to be fitted to the vertical bolt 20, the fitting is mounted on the top of the vertical bolt 20 A member 40, a vertical placement plate 50 attached to the rear surface of the fitting member 40, a pair of horizontal bolts 60 provided through the vertical placement plate 50, and the vertical bolts. It includes a plurality of elastic force control spring 70 is provided on both sides of the lower side of the upper projection jaw (11) and fixed by the vertical pin (71) to both sides of the (20).

The square contact plate 10 is in close contact with the rear surface of the mounting plate (B) to the lower portion of the upper bending jaw (C) is formed to be bent at the upper end of the mounting plate (B) installed in the electrical control enclosure (A). It is provided so that the upper end is bent inward to be in close contact with the lower surface of the upper bending jaw (C) is formed with an upper projection jaw 11 and the lower projection jaw 12 protruding horizontally corresponding to the upper projection jaw (11) It is attached to the bottom rear surface.

Here, the electrical control enclosure is provided with a mounting plate (B) therein, such as an electrical control panel, control box, switchboard, control box, distribution panel, electrical enclosure, distribution enclosure, control enclosure, etc., various control on such a mounting plate (B) Parts, electrical and electronic parts, etc. are installed.

The square contact plate 10 serves to provide a place where all the components of the earthquake resistance device are installed while allowing the present earthquake resistance device to be disposed on the rear surface of the installation plate (B).

The upper projection jaw 11 is in close contact with the lower surface of the upper bending jaw (C) so that the mounting plate (B) and the square contact plate 10 can be easily coupled to the upper end of the vertical spring (30) It serves to support and to be installed so as to vertically penetrate the upper end of the vertical bolt 20 and the vertical pin (71).

The lower protrusion projection 12 supports the lower end of the vertical spring 30 to support the vertical spring 30 together with the upper protrusion projection 11 and the vertical bolt 20 and the vertical pin ( The lower end of 71) penetrates and serves to support them.

The square contact plate 10 is an auxiliary protrusion formed so that the lower end of the square contact plate 10 is horizontally bent and protrudes to the lower portion of the lower projection jaw 12 so that the vertical pins 71 are supported therethrough. The upper projection jaw 11 is attached to the lower surface of the upper bending jaw C while being fastened through the upper bending jaw C from the lower surface of both sides of the jaw 13 and the upper projection jaw 11 upward. It further comprises a pair of mounting portion 14 to.

The auxiliary projection jaw 13 is to allow the vertical pin 71 to be more firmly supported while the lower end of the vertical pin 71 is penetrated. The mounting portion 14 is composed of a bolt and a nut is mounted on the upper surface of the upper projection jaw (11) in close contact with the lower surface of the upper bending jaw (C) by mounting them on the mounting plate (B) the square contact plate It serves to assemble by combining (10).

The vertical bolt 20 is vertically provided to slidably penetrates the upper projection jaw 11 and the lower projection jaw 12 at the center of the upper end of the square contact plate 10 and the thread is formed on the outer peripheral surface of the lower end The first fixing nut 21 is in close contact with the lower end of the protruding jaw 12 is screwed to the lower end.

The vertical bolt 20 serves to guide the vertical movement of the vertical spring 30 while providing a place where the vertical spring 30 is fitted and fixed, and at the same time includes the first fixing nut 21. It serves to provide a place where the parts are screwed or fitted into place. The first fixing nut 21 is to allow the lower end of the vertical bolt 20 to be fixed to the lower surface of the lower projection jaw (12).

The vertical spring 30 is disposed between the upper projection jaw 11 and the lower projection jaw 12 in a state of being fitted to the first fixing nut 21, and in the interior of the electrical control enclosure A. An elastic support force in the vertical direction is added to the mounting plate B to have seismic resistance in the vertical direction.

The fitting member 40 is fitted to the vertical bolt 20 exposed to the upper portion of the upper projection jaw 11 and fixed by a second fixing nut 41 screwed to the vertical bolt 20. The upper end is fixed by the third fixing nut 42 screwed to the upper end of the vertical bolt (20).

The fitting member 40 serves to provide a place where the vertical placement plate 50 is attached while being fitted and assembled to the vertical bolt 20, and the second fixing nut 41 is the vertical bolt 20. The screw is coupled to the upper portion of the fixing member serves to fix the lower end of the fitting member 40, the third fixing nut 42 is screwed to the upper end of the vertical bolt 20 is the upper end of the fitting member 40 It serves to fix the.

The vertical placement plate 50 is vertically attached to the rear surface of the fitting member 40 and vertically penetrates from the outer surface to both sides of the fitting member 40 to form a pair of vertical through holes 51, It serves to provide a place where the vertical through hole 51 is formed. The vertical through hole 51 is to be installed in the vertical placement plate 50 in a state in which the horizontal bolt 60 is movable up and down.

The horizontal bolt 60 is fitted into the vertical through-hole 51 so as to be slidable up and down, and is horizontally attached to the inner surface of the electrical control enclosure (A), the thread is formed on the outer peripheral surface and the vertical placement plate 50 Having a pair of fourth fixing nuts 61 screwed forward of the, so that the vertical placement plate 50 can be mounted on the inner surface of the electrical control enclosure (A) to be movable up and down will be. The fourth fixing nut 61 is screwed to the horizontal bolt 60 and serves to fix the vertical placement plate 50 to the horizontal bolt 60 in a state capable of moving up and down.

The elastic force adjustment spring 70 has a vertical pin (71) that is plurally fitted vertically through the upper projection jaw (11) and the lower projection jaw (12) to slide the upper projection jaw (11) and the lower It is disposed between the protruding jaw 12, it is to be selectively fitted to the vertical pin 71 to adjust the elastic support force in the vertical direction.

That is, the elastic force adjustment spring 70 is selectively fitted to the vertical pins 71 and in addition to the vertical spring 30 to allow to selectively adjust the seismic resistance in the vertical direction according to the user's intention, the vertical bolt 20 It is to be able to selectively adjust the elastic force on both sides of the square contact plate 10 to the center.

The seismic device configured as described above is installed between the upper bending jaw (C) of the mounting plate (B) and the inner surface of the electrical control enclosure (A), the mounting plate for the electrical control enclosure (A) (B) is to be elastically supported in the vertical direction to have a seismic resistance in the vertical direction.

In addition, the upper bending jaw (C) serves to provide a place where the seismic device is mounted so that the upper end of the mounting plate (B) can be easily mounted to the seismic device. The upper bending jaw (C) is formed to penetrate up and down of the plurality of installation holes (D) so that the vertical bolt 20 and the vertical pin (71) provided in the seismic device is fitted. Corresponding to the installation hole (D), it is preferable that the same size as the installation hole is formed in the upper projection jaw (11), the lower projection jaw (12) and the auxiliary projection jaw (13).

Although preferred embodiments of the present invention have been described above, the present invention may use various changes, modifications, and equivalents. It is clear that the present invention can be applied in the same manner by appropriately modifying the above embodiments. Accordingly, the above description does not limit the scope of the invention as defined by the limitations of the following claims.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but it will be apparent to those skilled in the art that various modifications are possible without departing from the scope of the present invention.

10: Square contact plate
11: upper projection jaw 12: lower projection jaw
13: auxiliary protrusion jaw 14: mounting portion
20: Vertical bolt
21: first fixing nut
30: vertical spring
40: fitting member
41: second fixing nut 42: third fixing nut
50: vertical placement plate
51: vertical through
60: Horizontal Bolt
61: fourth fixing nut
70: elastic force adjustment spring
71: vertical pin
A: electric control enclosure
B: mounting plate
C: Upper Bending Jaw
D: Installer

Claims (3)

It is provided to be in close contact with the rear surface of the mounting plate to the lower portion of the upper bending jaw formed to be bent on the upper end of the mounting plate installed in the electrical control enclosure, the upper end is bent inward so as to contact the lower surface of the upper bending jaw Protruding jaw (11) is formed, and the bottom contact jaw (12) protruding horizontally corresponding to the upper projection jaw (11) is a square contact plate (10) attached to the lower rear surface;
In the center of the upper end of the square contact plate 10 is provided vertically through the upper projection jaw 11 and the lower projection jaw 12 to slidably, a screw thread is formed on the outer peripheral surface, the lower projection jaw 12 The first fixing nut 21 is in close contact with the bottom of the vertical bolt 20 is screwed to the bottom;
A vertical spring 30 disposed between the upper protrusion jaw 11 and the lower protrusion jaw 12 while being fitted to the first fixing nut 21;
It is fitted to the vertical bolt 20 exposed to the upper portion of the upper projection jaw 11, the lower end is fixed by a second fixing nut 41 screwed to the vertical bolt 20, the upper end is the vertical A fitting member 40 fixed by a third fixing nut 42 screwed to an upper end of the bolt 20;
A vertically placed plate 50 vertically attached to the rear surface of the fitting member 40 and vertically penetrating from both sides of the fitting member 40 to form a pair of vertical through holes 51;
A pair that is slidably inserted up and down in the vertical through-hole 51, is horizontally attached to the inner surface of the electrical control enclosure, the thread is formed on the outer peripheral surface, the pair is screwed forward of the vertical placement plate 50 A pair of horizontal bolts 60 having a fourth fixing nut 61;
It has a vertical pin (71) that is slidably penetrates the upper projection jaw (11) and the lower projection jaw (12) vertically, between the upper projection jaw (11) and the lower projection jaw (12) A plurality of elastic force adjustment springs 70 disposed on the vertical pins 71 and selectively fitted to the vertical pins 71 to adjust elastic support forces;
An earthquake resistant device for an electrical control enclosure comprising a.
delete The method of claim 1,
The square contact plate 10,
An auxiliary projection jaw 13 formed so that the lower end of the square contact plate 10 is horizontally bent and protruded to the lower portion of the lower projection jaw 12 so that the vertical pin 71 is supported therethrough;
A pair of mounting portions 14 for mounting the upper projection jaw 11 to the lower surface of the upper bending jaw while being fastened through the upper bending jaw from both lower surfaces of the upper projection jaw 11 to the upper portion,
An earthquake resistant device for an electrical control enclosure further comprising.

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