KR20210044607A - Earthquake-resistant reinforcement system for distributing board - Google Patents

Abstract

The present invention provides an earthquake-resistant reinforcement system of a distributing board having a first attenuator (20) on a bottom surface of a case (11) and supporting a transformer (13) with an anti-vibration frame (17). The system comprises: support frames (30) disposed on both sides of the anti-vibration frame (17) inside of the case (11); and a second attenuator (40) coupled to both ends of the support frame (30) inside the case (11) and implementing vertical, horizontal, and inclined motion. Accordingly, there is an effect of effectively attenuating external high-intensity seismic force applied to the distributing board installed in various facilities as well as internal excitation force, thereby preventing damage to the distributing board and increasing operation reliability.

Description

Earthquake-resistant reinforcement system for distributing board}

The present invention relates to seismic and dustproofing of a switchboard, and more specifically, to a seismic reinforcement system of a switchboard for securing the functionality and stability of distributing power from various facilities to a load side.

Typically, the switchboard accommodates transformers, switches, relays, instruments, etc. to operate or control electric/electronic devices including electric motors in facilities by collecting power produced by power plants and substations. Because dangerous components such as transformers that carry high-voltage current are concentrated inside such switchboards, they must not be damaged or deformed even by strong impacts such as earthquakes. In particular, for facilities with relatively poor accessibility, such as tunnels, it is important to secure the seismic and vibration resistance of the switchboard.

As prior art documents related to the seismic and vibration resistance of the switchboard, reference may be made to Korean Patent Publication No. 1868910 (Prior Document 1), Korean Patent Publication No. 2009703 (Prior Document 2), and the like.

Prior Literature 1 prevents damage to internal and external components due to impacts, primary damage to housing damage, and secondary damage such as power failure and fire due to the flow of components when an impact such as an earthquake or mechanical vibration occurs. Separation/replacement should be performed smoothly along with the inspection of the dustproof part.

Prior Literature 2 shows that the main spring installed vertically between the switchboard and the ground suppressed the vibration generated in the vertical direction, and one or more auxiliary springs installed around the main spring suppressed the vibration generated in the horizontal direction. In addition to actively blocking the generated vibration, it is not limited to a location, and it can be easily installed in various locations.

However, according to the above-described prior literature, the vibration damping by the high-strength seismic force and the internal excitation source is insufficient due to the seismic structure to the outside of the switchboard as the main body.

Korean Patent Publication No. 1868910 "Intelligent switchgear with seismic and dustproof functions" (Publication date: 2018.07.23.) Korean Patent Publication No. 2009703 "A shock absorber structure in which a plurality of springs each reacting to vertical and horizontal vibrations are integrally formed" (Publication date: 2019.08.12.)

It is an object of the present invention to provide a seismic reinforcement system for a switchboard for effectively attenuating internal excitation forces as well as external high-strength seismic forces applied to switchboards installed in various facilities. .

Another object of the present invention is to easily reinforce the seismic performance of main components such as a transformer in a pre-installed switchboard.

In order to achieve the above object, the present invention provides a seismic reinforcement system of a switchboard for supporting a transformer with a vibration-proof frame having a first attenuator on a bottom surface of a case, comprising: a support frame disposed inside the case on both sides of the vibration-proof frame; And a second attenuator coupled to both ends of the support frame inside the case and implementing vertical, horizontal, and inclined motions.

According to the detailed configuration of the present invention, the support frame is characterized in that it further includes a bent portion to form a step at a symmetrical position in the center.

According to the detailed configuration of the present invention, the support frame is characterized in that it includes a rubber cushion in a region in contact with the vibration-proof frame and in a region in contact with the second attenuator.

According to the detailed configuration of the present invention, the second attenuator is configured by connecting a main spring, a sub-spring, an elastic tube, and a connecting spring between the upper and lower mounts, and a cradle wrapped in a vertical two-segment structure to limit excessive displacement of the mount. It characterized in that it further comprises.

As a modified example of the present invention, the second attenuator is characterized in that it further includes an adjustment unit on the mounting table to change the elastic force of the sub-spring and the connection spring.

As described above, according to the present invention, there is an effect of effectively attenuating the internal excitation force as well as the external high-strength seismic force applied to the switchboard installed in various facilities, thereby preventing damage to the switchboard and improving the linear motion reliability.

1 is a block diagram showing the overall system according to the present invention
2 is a block diagram showing the main parts of the system according to the present invention
3 is a schematic diagram showing an operating state of the attenuator of FIG. 2
4 is a block diagram showing a modified example of the attenuator according to the present invention
5 is a test report related to the system according to the present invention

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

The present invention proposes a seismic reinforcement system of a switchboard having a first attenuator 20 on the bottom of the case 11 and supporting the transformer 13 with a vibration-proof frame 17.

Referring to FIG. 1, the switchboard 10 mounts main components including a transformer 13 inside a case 11 equipped with a door 12. The transformer 13 is exemplified by a structure in which the iron core and the winding are not immersed in insulating oil, but insulated with a resin such as epoxy. The transformer 13 is integrally coupled with the bed frame 14 and is fixed to the bottom surface of the case 11 through the vibration-proof frame 17. A rubber cushion 15 is interposed between the transformer 13, the bed frame 14, the dustproof frame 17, and the case 11. The case 11 of the switchboard 10 is supported through the first attenuator 20 as a whole.

The first attenuator 20 is disclosed in Korean Patent Publication No. 2009703 of Prior Document 2 by the present applicant. The first attenuator 20 has a structure in which the upper and lower mounts 22 are connected by a main spring 24 and a sub spring 26. The main spring 24 is disposed in the center of the mounting base 22 as a compression spring, and the sub-spring 26 is disposed around the main spring 24 as a tension spring. The first attenuator 20 is fixed using a buried groove formed in the bottom of the space in which the switchboard 10 is accommodated.

The first attenuator 20 having such a structure exhibits a damping function for vertical and vertical vibrations. However, it is somewhat insufficient to solve the problem caused by the high-strength seismic force applied from the outside or the self-vibration of the transformer 13.

According to the present invention, the support frame 30 forms a structure in which the support frame 30 is disposed on both sides of the vibration-proof frame 17 in the case 11. When the transformer 13 is supported by two anti-vibration frames 17, the support frame 30 is disposed so as to intersect the two anti-vibration frames 17 at one end and the other end of the anti-vibration frame 17. Referring to the switchboard 10 of FIG. 1, the support frame 30 is disposed on the front side and the rear side of the case 11.

In addition, according to the present invention, the second attenuator 40 is coupled to both ends of the support frame 30 inside the case 11, and it is characterized in that it implements vertical, horizontal, and inclined motion. The second attenuator 40 is disposed to support the transformer 13 through the support frame 30 in the case 11. The high-strength seismic force is transmitted to the transformer 13 in a greatly attenuated state through the first attenuator 20 and the second attenuator 40.

According to the detailed configuration of the present invention, the support frame 30 is characterized in that it further includes a bent portion 31 to form a step at a symmetrical position in the center.

Referring to FIG. 2, the support frame 30 is bent to form a step in the upper direction through the bent portions 31 on one side and the other side. The step structure of the support frame 30 performs a height adjustment function corresponding to the vibration-proof frame 17 as well as a vibration-proof function by elastic deformation. Anchor portions 32 are provided at both ends of the support frame 30 bent. The anchor part 32 includes an anchor bolt and an anchor bolt mounting hole.

According to the detailed configuration of the present invention, the support frame 30 is characterized in that it includes a rubber cushion 35 in a region in contact with the vibration-proof frame 17 and in a region in contact with the second attenuator 40.

1 and 2, a rubber cushion 35 is installed on the upper surface of the vibration-proof frame 17 and the lower surface of the support frame 30, and rubber on the lower surface of the support frame 30 and the upper surface of the second attenuator 40 A cushion 35 is installed. The rubber cushion 35 may be applied in the form of a pad having a thin thickness and may additionally include a shim for height adjustment. It is good to select the material and frequency characteristics of the rubber cushion 35 in consideration of the specifications of the rubber cushion 15 previously installed on the bed frame 14 and the vibration-proof frame 17. In addition, the vibration characteristics according to the load change of the transformer 13, which is an internal excitation source of the switchboard 10, are also considered.

According to the detailed configuration of the present invention, the second attenuator 40 connects the main spring 44, the sub spring 46, the elastic tube 45, and the connection spring 47 between the upper and lower mounting tables 42. It is configured, and characterized in that it further comprises a cradle 41 wrapped in a top and bottom two-segmented structure to limit excessive displacement of the mounting table 42.

In FIG. 2, the second attenuator 40 has a structure in which the upper and lower mounts 42 are connected to the main spring 44 and the sub-spring 46 like the first attenuator 20. The second attenuator 40 further includes an elastic tube 45 and a connection spring 47 in addition to the structure of the first attenuator 20. The elastic tube 45 and the connection spring 47 are disposed concentrically inside the main spring 44. The elastic tube 45 is fixed to the mounting table 42 through the shaft at the upper and lower ends, and the connection spring 47 is coupled to the shaft from the inside of the elastic tube 45 to the upper and lower ends. Like the sub-spring 46, the elastic tube 45 and the connection spring 47 provide a restoring force in response to the elastic deformation of the main spring 44.

At this time, the second attenuator 40 constitutes a structure entirely enclosed by the cradle 41. The cradle 41 is a box-shaped structure with at least one open surface and accommodates all of the mounting table 42, the main spring 44, the sub spring 46, and the like. The cradle 41 is formed in a size that excludes interference between the second attenuator 40 and the anchor bolt. The upper cradle 41 has an opening downward, and the lower cradle 41 has an opening upward. The upper and lower cradles 41 are differentiated in size to allow vertical, horizontal, and inclined motion of the second attenuator 40 and prevent damage or breakage of the second attenuator 40 in response to excessive external force. The vertical, horizontal, and inclined motion of the second attenuator 40 means an omnidirectional attenuation corresponding to an external seismic force and an internal excitation force.

Referring to FIG. 3, a state in which the second attenuator 40 is accommodated in the cradle 41 and implements vertical, horizontal, and inclined motion is somewhat exaggerated and illustrated. 3(a) shows a state in which the second attenuator 40 is buckling vertically and horizontally. The main spring 44 is buckling and the elastic tube 45 induces stable buckling, and the sub-spring 46 causes the restoration of the main spring 44, and the connection spring 47 causes the restoration of the elastic tube 45. .

3(b) shows a state in which the second attenuator 40 is inclined to one side. While the main spring 44 implements an oblique motion, the surrounding sub-springs 46 expand and contract with different lengths. The elastic tube 45 and the connection spring 47 may act as a restoring force in connection with the sub-spring 46 and at the same time implement some degree of buckling.

As a modified example of the present invention, the second attenuator 40 is characterized in that it further includes an adjustment unit 48 on the mounting table 42 to change the elastic force of the subspring 46 and the connection spring 47 do.

Referring to FIG. 4, an adjustment part 48 is formed above the bracket 46s supporting the subspring 46. The same adjustment part 48 may be added to the upper side of the shaft supporting the elastic tube 45 and the connection spring 47. The adjustment unit 48 may be configured by connecting an adjustment bolt to the bracket 46a. That is, the bracket 46a is supported on the mounting table 42 so as to move up and down, and the bracket 46a is connected to the lower end of the adjustment bolt so as to enable relative movement. Accordingly, the position of the bracket 46a and the elastic force of the subspring 46 vary according to the degree of tightening and loosening the adjustment bolt. This is applied to the process of determining the attenuation characteristics of the second attenuator 40 in parallel with the operation of determining the material and frequency characteristics of the rubber cushion 35 described above.

5, the first attenuator 20 and the second attenuator 40 of the present invention are applied with a seismic test and a resonance search result, in addition to the operation of the main parts, resonance, separation, deformation, cracks, breaks, etc. You can confirm that this is not issued

It is apparent to those of ordinary skill in the art that the present invention is not limited to the disclosed embodiments, and that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, such variations or modifications will have to belong to the scope of the claims of the present invention.

10: switchboard 11: case
12: door 13: transformer
14: bed frame 15: rubber cushion
17: anti-vibration frame 20: first attenuator
22: mount 24: main spring
26: subspring 30: support frame
31: bend part 32: anchor part
35: rubber cushion 40: second attenuator
41: cradle 42: mount
44: main spring 45: elastic tube
46: subspring 47: connecting spring
48: adjuster

Claims (5)

In the seismic reinforcement system of a switchboard having a first attenuator 20 on the bottom of the case 11 and supporting the transformer 13 with a vibration-proof frame 17:
A support frame 30 disposed on both sides of the vibration-proof frame 17 in the case 11; And
A seismic reinforcement system for a switchboard comprising: a second attenuator 40 coupled to both ends of the support frame 30 inside the case 11 and implementing vertical, horizontal, and inclined motions. The method according to claim 1,
The support frame (30) is a seismic reinforcement system of a switchboard, characterized in that it further comprises a bent portion (31) to form a step in a symmetrical position in the center. The method according to claim 1,
The support frame (30) is a seismic reinforcement system of a switchboard, characterized in that it comprises a rubber cushion (35) in the region in contact with the vibration-proof frame (17) and the region in contact with the second attenuator (40). The method according to claim 1,
The second attenuator 40 is configured by connecting the main spring 44, the sub-spring 46, the elastic tube 45, and the connection spring 47 between the upper and lower mounts 42, and the mount 42 ) Seismic reinforcement system of the switchboard, characterized in that it further comprises a cradle (41) enclosing the upper and lower two-divided structure to limit excessive displacement. The method of claim 4,
The second attenuator (40) is a seismic reinforcement system of a switchboard, characterized in that it further comprises an adjustment unit (48) on the mount (42) to change the elastic force of the sub-spring (46) and the connection spring (47).

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