KR102031254B1 - Seismic switchboards adjustable for height - Google Patents

Abstract

The present invention relates to an earthquake-proof structure capable of adjusting the height of a switchboard by using a dual elastic body, which has an elastic body having a plurality of springs vertically stacked and different elastic forces, and a fixing bolt vertically passing through the elastic body to be disposed on an upper end of the elastic body and including an adjustment nut pressurizing the elastic body by fastening, wherein the elastic body and the fixing bolt are installed in respective corners of the switchboard and a lower frame, the height of the elastic body is adjusted by pressuring the adjustment nut according to the convexities and the curve of the surface, and the height is adjusted by pressurizing only a spring having a low elastic force, and a spring having a high elastic force is maintained to be in an initial state, thereby imparting aseismicity to the switchboard. More specifically, the earthquake-proof structure comprises: a lower frame (10) installed on the surface of the ground to guide the accommodation of a switchboard (A) and having a drilled hole (13) provided in each corner; an elastic body (20) inserted into the drilled hole (13) while at least two springs are vertically stacked, and guiding seating of the switchboard (A) by an upper end portion thereof exposed to the above of the lower frame; and a fixing bolt (30) including a bolt portion (31) embedded in the surface of the ground through the switchboard (A) and the elastic body (20), and an adjustment nut (32) installed on an upper end of the bolt portion exposed to an inner space of the switchboard such that the switchboard is fixed to the bolt portion. The present invention can safely protect a switchboard from vibration.

Description

Seismic switchboards adjustable for height}

The present invention relates to a seismic structure that can control the height of the switchgear using a double elastic body, and more particularly, an elastic body provided in a form in which a plurality of springs made up of different elastic forces are stacked up and down, and the elastic body vertically penetrating the elastic body A fixed bolt made of a control nut arranged at the top of the pressurizing elastic body by tightening is installed at each corner of the switchboard and the lower frame to press the adjusting nut according to the uneven or curved state of the ground to adjust the height of the elastic body. Only the low spring is pressed to adjust the height, the spring with a high elastic force relates to the seismic structure that can adjust the height of the switchboard by using a double elastic body to maintain the initial state to give a shockproof to the switchboard.

In general, a switchboard is a device that constantly puts and manages switches, relays, relays, etc. for the operation and control of power plants and substations, and the operation of electric motors. It protects the above devices from the same external influence.

As an example of such a switchboard, Published Utility Model Publication No. 20-0485961 discloses a switchboard enclosure door fixing device. The related art has a first magnetic member coupled to a lower portion, a ring portion formed at an upper portion thereof, and a door attachment portion attached to a front surface of the door by the first magnetic member, and a wire in which the wire is accommodated so that the wire can be wound and unwound. It consists of a housing part, a binding part which is bound to a ring part at one end of the wire, and a main body part which is attached to the switchboard case by the second magnet member. In the prior art made of the above configuration, the operator can arbitrarily adjust the opening angle of the switchgear enclosure door at the time of inspecting the switchboard so that the installation or repair work of the switchboard can be performed quickly and safely.

Since all the devices installed inside the switchboard have a high voltage current, it is preferable to use a switchboard case having durability and safety. In particular, the switchboard can be installed on a flat ground to safely protect the switchboard from vibration caused by disaster. Should be

On the other hand, as an example of a technology that can safely protect the switchboard installed on the ground from various external environmental factors, Patent Publication No. 10-1863763 "Squake-resistant switchgear with a spring coupling configuration" is published, the prior art of the switchboard The load is supported by three compression coil springs mounted inclined downwardly so that the compression coil spring attenuates the vibration in the vertical and horizontal directions, thereby preventing damage to the switchboard and especially because the switchboard is not connected to the floor. It is a technology that prevents damage to the durability of buildings by reducing shocks acting on the floor by horizontal vibration.

However, the prior art can block the vibration generated by the earthquake to be transmitted to the switchboard, but can not be installed on the ground is formed uneven or curved because the separate height adjustment function is excluded.

For example, in order to solve the above problems, there is provided a technology in which the height is adjusted by compressing the spring by installing nuts at the upper and lower ends of the spring, and tightening the nut, but the elastic force of the spring is deformed at each corner. Another problem occurred that the buffer function is lost.

therefore. It is very urgent to have a technology that can fully express the cushioning function by preventing the elastic change of the spring by pressurizing the nut while maintaining the simple function of adjusting the height of the spring by adjusting the nuts installed at the top and bottom of the spring. to be.

Korean Utility Model Publication No. 20-0485961 "Distribution board enclosure door fixing device" Korean Patent Publication No. 10-1863763 "Earth-proof Switchgear with Spring Coupling Configuration"

The present invention was created in order to more actively solve the above problems, by installing an elastic body between the switchboard and the ground to secure the switchboard from vibration in the event of an earthquake, as well as the height of the elastic body using a nut Provided to be able to easily adjust, but the main challenge is to configure so that the elastic force of the elastic body is adjusted to be different from each other to maintain the same height.

In order to achieve the above problems, the configuration of the seismic structure that can control the height of the switchgear using the double elastic body proposed in the present invention is as follows.

The seismic structure of the present invention is installed on the ground to induce the acceptance of the switchboard (A), the lower frame 10 is provided with a drilling hole 13 in each corner; and at least two springs are stacked up and down The elastic body 20 is inserted into the boring hole 13, and a part of the upper end is exposed to the upper part of the lower frame to induce the seating of the switchboard A. The ground penetrates the switchboard A and the elastic body 20. A fixed bolt 30 including a bolt portion 31 embedded in the upper portion of the bolt portion exposed to the inner space of the switchboard and an adjusting nut 32 fixed to the switchboard on the bolt portion; It is done.

In addition, the lower frame 10 is characterized in that the horizontal measuring unit 14 is further provided for each corner.

In addition, the elastic body 20 is the first elastic body 21 is inserted into the interior space of the drilling hole 13, the second elastic body is stacked on the first elastic body is exposed to the upper end of the lower frame 10 (22) and a stopper 23 disposed at the lower end of the first elastic body and the upper end of the second elastic body, respectively, and a guide 24 interposed between the first elastic body and the second elastic body to fix the first elastic body and the second elastic body. It characterized by consisting of).

In addition, the first elastic body 21 is characterized in that the pitch distance is set to be higher than the second elastic body 22, the shrinkable distance from the pressurization is extended.

In addition, the first elastic body 21 is composed of a lower elastic force than the second elastic body 22, the first elastic body is contracted when the adjustment nut 31 is pressed to induce height adjustment, the second elastic body is in an initial state It characterized in that the buffer function is expressed by maintaining.

According to the present invention having the above-described configuration, the first elastic body inserted into the drilling hole of the lower frame, and the second elastic body having a higher elastic force than the first elastic body is laminated on the upper end of the first elastic body, the second elastic body When the first elastic body with low elastic force is adjusted by tightening the adjusting nut installed at the upper end, the height is adjusted so that the second elastic body can maintain the elastic force and protect the switchboard from vibration.

In addition, the present invention has another effect that can quickly and safely install the switchboard because it can maintain the elastic function that can safely protect the switchboard, while maintaining the height adjustment of the adjustment nut system.

In addition, the present invention is expected to provide yet another advantage of providing a seismic structure having excellent functionality while being able to mass-produce at a low cost because it is composed of a plurality of elastic bodies, stoppers and bolts and nuts.

1 is a perspective view of a seismic structure capable of adjusting the height of the switchgear using a double elastic body constituted by a preferred embodiment of the present invention.
2 is an exploded perspective view of FIG.
3 is a cross-sectional view of FIG.
4 is a state diagram used in FIG.
5 is a state diagram used in FIG.
6 is a perspective view of a seismic structure capable of adjusting the height of the switchboard by using a double elastic body constituted by another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in a batch about the configuration of the present invention and its effects, effects.

Advantages and features of the present invention, and methods for achieving them will be apparent with reference to the embodiments described below in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be embodied in various different forms, and only the present embodiments are provided to make the disclosure of the present invention complete and common knowledge in the technical field to which the present invention belongs. It is provided to fully inform the person having the scope of the invention, which is defined only by the scope of the claims. And like reference numerals refer to like elements throughout the specification.

The present invention relates to a seismic structure that can control the height of the switchgear using a double elastic body.

First of all, the switchboard is composed of an elastic body provided with a plurality of springs formed of different elastic forces stacked up and down, and an adjustment bolt for pressing the elastic body by tightening the elastic body while vertically penetrating the elastic body. It is installed at each corner of the lower frame to adjust the height of the elastic body by pressing the adjusting nut according to the unevenness or bend of the ground, but only the spring with low elastic force is adjusted to adjust the height, and the spring with high elastic force maintains the initial state. It is to be noted that the present invention relates to a seismic structure that can control the height of a switchboard by using a double elastic body that imparts seismic resistance to the panel.

1 is a perspective view of a seismic structure that can adjust the height of the switchgear using a double elastic body constituted by a preferred embodiment of the present invention, Figure 2 is an exploded perspective view of FIG.

As shown in FIG. 1, the seismic structure capable of adjusting the height of the switchboard using the double elastic body of the present invention is installed on the ground to induce the acceptance of the switchboard A. The lower frame 10; It is composed of an elastic body 20 interposed between the frame and the ground to mitigate vibration; and a fixing bolt 30 to fix the lower frame to the ground.

On the basis of Figure 2 will be described each configuration above.

As mentioned above, the lower frame 10 refers to a square frame installed on the ground to induce accommodation of the switchboard A. The lower frame 10 may be manufactured in various shapes such as a polygon or a circle according to the shape of the switchboard.

The upper lower frame 10 is in close contact with the ground and guides the front panel of the bottom of the switchboard while inducing the acceptance of the switchboard A, and is vertically installed at each corner of the support panel, so that the front side of the switchboard ( It consists of a standing part 12 which supports the whole surface.

The upper lower frame 10 forms a perforated hole 13 formed up and down in each corner to induce coupling of the elastic body 20 and the fixing bolt 30 to be described below.

On the other hand, the lower frame 10 of the present invention is attached to one or more horizontal measuring unit 14 to the support portion 11 or the standing portion 12 to install the lower frame to easily adjust the horizontal even if the operator does not separately prepare a horizontal measuring instrument and It can be repaired.

As shown in FIG. 3, the elastic body 20 of the present invention is as follows.

The elastic body 20 of the present invention is configured in a form in which at least two or more springs are stacked up and down, is installed in the drilling hole 13 of the lower frame 10 to connect the ground and the lower frame, the switchboard, vibration by earthquake It actively prevents vibration from being transmitted to the switchboard when it occurs. In addition, the elastic body 20 can adjust the height of the switchboard by pressing the spring from the fixing bolt 30 to be described later.

The upper elastic body 20 performing the above role is the first elastic body 21 inserted into the drilling hole 13 of the lower frame 10, and the second elastic layer laminated on the upper end of the first elastic body exposed to the upper end of the lower frame An elastic body 22, a stopper 23 disposed at the lower end of the first elastic body and the upper end of the second elastic body, respectively, and a guide interposed between the first elastic body and the second elastic body to fix the first elastic body and the second elastic body. It consists of 24.

For example, in the present invention, the first elastic body 21 and the second elastic body 22 are represented by a coil spring, but this is only an option according to the understanding of the description and the most preferred embodiment, and is not limited to the spring, rubber or It can be replaced with any material that is given elasticity by itself.

Meanwhile, in the elastic body 20 of the present invention, the first elastic body 21 uses a spring having a low elastic force, and the second elastic body 22 uses a spring having a somewhat higher elastic force than the first elastic body.

For example, when adjusting the height of the elastic body 20 by tightening the adjusting nut 32 of the fixing bolt 30 to be described below, when the first elastic body 21 and the second elastic body 22 are composed of the same elastic force. Since the elastic forces of the first elastic body and the second elastic body are the same, the pressing force is distributed to each other, so that compression of the spring occurs in the same manner.

This phenomenon can be compared with the existing technology that uses one spring at each corner of the switchboard, and one spring can provide sufficient cushioning effect, but the height of the buffer spring is adjusted to each spring according to the curvature of the ground. Elastic strength is differentiated.

As such, switchboards with different elastic strengths for each corner cannot effectively control the vibration damping occurring in the polygons.

Therefore, in the present invention, the first elastic body 21 inserted into the punching hole 13 of the lower frame 10 is composed of a spring having a somewhat lower elastic force than the second elastic body 22 to press the adjusting nut 32. The pressing force is transmitted to the second elastic body, but only the first elastic body is compressed so that the height is controlled.

In addition, the first elastic body 21 of the present invention has a higher height than the first elastic body 22 by extending the compression range for tightening the adjusting nut 32 by setting the length somewhat higher.

6 is an exploded perspective view illustrating determining an elastic ratio according to a pitch interval of an elastic body and a coil shape of the elastic body.

In the elastic body 20 of the present invention, the first elastic body 21 has an elastic force of about 25 to 30% and the second elastic body 22 has the remaining 70 to 75% of the elastic force based on 100% of the elastic force. It is the ratio that can actively maintain the buffer function while adjusting the height.

As described above with reference to the elastic body 20, the shock absorbing structure of the present invention adjusts the height by tightening or loosening the adjusting nut installed in close contact with the upper surface of the second elastic body according to the state of the ground.

At this time, when the elastic force of the first elastic body 21 and the second elastic body 22 is the same, the first elastic body and the second elastic body are simultaneously compressed with each other by the pressing force of the adjusting nut, and conversely, the second elastic body is compared with the first elastic body. When the elastic force of the elastic body is low, the second elastic body is first compressed before the first elastic body contracts so that the width of the lower frame and the switchboard can be adjusted, and the height of the ground can not be substantially adjusted.

Therefore, in order to control the height of the seismic structure of the present invention, the contraction or tension should be applied to the first elastic body interposed between the lower frame and the ground, and for this purpose, the first elastic body should have a lower elastic force than the second elastic body. Will do.

Herein, in order to configure the first elastic body with a lower elastic force than the second elastic body, the materials may be different as mentioned above. For example, the first elastic body may use a synthetic resin having a somewhat high hardness, and the second elastic body may use synthetic steel.

Alternatively, the same material can be used to discriminate the thickness of the coil. For example, the first elastic body has a diameter of 1 mm and the second elastic body has a diameter of 3 mm. Can be.

Alternatively, the coil may be discriminated by the interval between pitches, and the first elastic body may be wound at intervals of 1 mm, and the second elastic body may be wound at intervals of 3 mm to set an elastic ratio.

Whatever method is used, it is important that the elastic ratio of the first elastic body and the second elastic body be 1: 3.

The stopper 23 is interposed at the lower end of the first elastic body 21 and the upper end of the second elastic body 22, and is provided with a hollow inner space to embrace the ends of the first elastic body and the second elastic body.

In particular, the stopper 23 is made of a rubber or urethane material not only induces pressure between the first elastic body 21 and the second elastic body 22, but also provides elastic force by itself, the first elastic body and the second elastic body It serves to strengthen the elastic performance of the elastic body.

On the other hand, the stopper 23 is disposed on the bottom of the first elastic body 21 is installed on the bottom of the lower frame 10, the lower frame in the state in which the first elastic body is inserted into the drilling hole 13 of the lower frame Another stopper 23 disposed on the upper side of the first elastic body and closely installed on the upper surface of the lower frame prevents the first elastic body inserted into the drilling hole from escaping to the upper side of the lower frame. Prevents tensioning to the upper side of the lower frame more than necessary.

In addition, the stopper 23 disposed at the bottom of the second elastic body 22 and installed closely to the upper surface of the lower frame 10 has a first elastic body when the second elastic body receives the pressing force by tightening the adjusting nut. Another stopper 23 disposed above the second elastic body to block the introduction of more than necessary by the inserted boring hole, and the control nut is restrained by the stopper 23 actively transmits the pressing force of the adjusting nut to the second elastic body while the second elastic body is on the upper side. Prevent departure to the outside area.

The guide 24 is formed in the shape of washers (Washers) are disposed in each of the two spaces between the first elastic body 21 and the second elastic body 22.

On the other hand, the guide 24 is made of steel (Steel) material and the first elastic body 21 and the second elastic body 22 to impart a driving force that can be buffered against the impact transmitted from the outside while the first elastic body and the first 2 It includes a role of fixing the initial position of the elastic body to always adhere.

The fixing bolt 30 penetrates both the elastic body 20 and the lower frame 10 to fix both the elastic body to the lower frame while fixing the lower frame to the ground, and the bolt part 31 and the bolt part ( 31 is provided on the upper end of the control nut 32 for pressing the stopper 23 disposed on the upper end of the second elastic body.

In the present invention, the upper bolt part 31 is actively recommended to use the anchor bolt, but is not limited thereto, and includes all means capable of firmly fixing the lower frame to the ground.

For example, the upper bolt portion 31 is a structure that is fastened through the elastic body 20 inserted into the drilling hole 13 of the lower frame 10, the inner diameter of the first elastic body 21 and the second elastic body 22 It is natural that the use of bolts with the same diameter can lead to a firm bond between them.

The seismic structure that can adjust the height of the switchgear using the double elastic body of the present invention having the above configuration has the first elastic body inserted into the perforation hole of the lower frame, and the second elastic body having a higher elastic force than the first elastic body is the first elastic body. As the stacking is arranged on the upper side of the second elastic body, only the first elastic body having low elastic force is pressed when tightening the adjusting nut installed on the upper side of the second elastic body, and the height is adjusted so that the second elastic body can maintain the elastic force and protect the switchboard from vibration. In addition, it is possible to install the switchboard quickly and safely because it can maintain the elastic function to safely protect the switchboard while maintaining the height of the adjusting nut method.

In addition, the present invention can provide a seismic structure of excellent functionality while being able to mass-produce at a low cost because it is composed of a plurality of elastic bodies, stoppers and bolts and nuts.

Although the present invention described above has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and various modifications and equivalent other embodiments may be made by those skilled in the art. Should be clarified. Therefore, the true technical protection scope of the present invention should be interpreted by the appended claims, and all technical ideas within the equivalent scope should be construed as being included in the scope of the present invention.

10. Underframe 11. Support
12. Entrance section 13. Hole
14. Level gauge 20. Elastic body
21. First elastic body 22. Second elastic body
23. Stopper 24. Guide
30. Fixing bolt 31. Bolt part
32. Adjusting nut
1. Seismic Structure

Claims (5)

In the seismic structure installed on the bottom of the switchboard,
A lower frame 10 installed on the ground to induce accommodation of the switchboard A, and having perforation holes 13 at each corner;
An elastic body 20 inserted into the drilling hole 13 in a state in which at least two springs are stacked up and down, and a part of the upper end of which is exposed to the upper part of the lower frame to induce the seating of the switchboard A;
The bolt 31 which is embedded in the ground by penetrating the switchboard A and the elastic body 20, and the adjustment nut 32 is installed on the upper end of the bolt exposed to the inner space of the switchboard to fix the switchboard on the bolt portion. Fixing bolt 30 including;
Consisting of ,
The elastic body 20 is the first elastic body 21 is inserted into the interior space of the drilling hole 13, the second elastic body 22 is disposed to be exposed to the upper end of the lower frame 10 is laminated on the first elastic body 22 ) And a stopper 23 disposed at a lower end of the first elastic body and an upper end of the second elastic body, respectively, and a guide 24 interposed between the first elastic body and the second elastic body to fix the first elastic body and the second elastic body. Done,
The first elastic body 21 is composed of a lower elastic force than the second elastic body 22, the first elastic body is contracted when the adjustment nut 31 is pressed to induce height adjustment, the second elastic body maintains the initial state Seismic structure capable of controlling the height of the switchgear using a double elastic body characterized in that the buffer function is expressed .
The method of claim 1,
The lower frame 10 is a seismic structure capable of adjusting the height of the switchgear using a double elastic body, characterized in that the horizontal measuring device 14 is further provided for each corner.
delete The method of claim 1 ,
The first elastic body 21 is a seismic structure capable of adjusting the height of the switchboard by using a double elastic body, characterized in that the distance that can be contracted from the pressurizing by setting a pitch interval higher than the second elastic body (22).
delete

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