KR101538989B1 - Walk-in-type substation with seismic - Google Patents

Abstract

The present invention provides a walk-in substation having earthquake resistant capacity which minimizes damages or deformation by a corrugated panel composing a substation and a simple connection structure without an additional, complex earthquake resistant means when an earthquake in a magnitude of 7 or lower on the Richter scale occurs, and wherein a corrugated valley of the corrugated panel composing the walk-in substation has an inclined surface (a) with a bending angle of 60° and a length of 40 to 45 mm and a horizontal surface (b) with a length of 65 to 75 mm which are repeatedly formed when bending a base metal, and the corrugated panel is welded on a frame. Accordingly, the walk-in substation can secure high safety, reduce manufacturing costs for assembling the substation, be conveniently installed, and have earthquake resistant capacity without an additional earthquake resistant means to be economically beneficial.

Description

[0001] Walk-in type substation with seismic < RTI ID = 0.0 >

More particularly, the present invention relates to a work-in-type transformer having an earthquake-proof performance, and more particularly, to a transformer having an earthquake- And more particularly, to a work-in type transformer room having a seismic performance capable of minimizing damage or deformation even when an earthquake of 7 or less occurs.

In general, the switchboard accommodates various electric devices such as a breaker or a small generator and prevents exposure to the outside. The switchboard can be largely divided into a switchboard installed indoors and an switchboard installed outdoors.

When installed indoors, the cabinet is made of a small cabinet, and various electric or electric devices are installed in the cabinet. When installed outdoors, a roof is formed at the upper part of the switchboard to prevent the rainwater from being introduced into the switchboard So as to prevent electric leakage and fire caused by flooding.

However, existing outdoor switchboards are left in the harsh environment of the outside without building of the transformer room, so that deterioration due to deterioration of equipment and parts is rapidly proceeding, and the service life of the equipment is short, and there are disadvantages such as equipment accident and malfunction. In addition, there are structural problems such as a rapid increase in maintenance and repair costs from the elapse of five years or more after installation. In addition, due to on-site circumstances, when working in bad weather, there is a serious danger to the safety of workers, and it is complicated and costly and time-consuming to expand and install in future.

In order to overcome the limitations of existing outdoor switchboards, a walk-in type transformer room has been proposed. Such a work-in type transformer room is composed of a roof for protecting the switchboard from snow, rain, wind and the like, a base frame for supporting the switchboard, an angle frame constituting the framework, and a panel attached to the angle frame do. This type of transformer room has the advantages of being able to inspect and manage the switchboard while a person is moving as a transformer room of the house concept by mounting the switchboard therein.

Prior art related to the above-mentioned work-in type has been disclosed in Korean Patent No. 10-0579908, Korean Patent No. 10-0739857, and Korean Patent No. 10-1061861.

However, in the case of such a work-in type transformer room, a problem has arisen which is caused by a collapse or deformation due to natural disasters such as typhoons which are becoming frequent recently, especially earthquakes.

In order to solve such a problem, a technique such as an enclosure for a switchboard having an earthquake-resistant frame structure has been proposed as disclosed in Korean Patent No. 10-1027917 (hereinafter referred to as "Patent Document 1").

Also, as disclosed in Korean Patent No. 10-1042577 (hereinafter referred to as "Patent Document 2"), an earthquake-resistant stopper, a tension member, or the like for fixing a cube- A technique for preventing the deformation of the position of the switchboard due to the deformation of the switchboard is proposed.

Also, as disclosed in Korean Patent No. 10-1081571 (hereinafter referred to as "Patent Document 3"), there has been proposed a technique for protecting various equipment provided inside from an earthquake by installing an earthquake-resistant spring.

Also, as disclosed in Korean Patent No. 10-1254091 (hereinafter referred to as "Patent Document 4"), there has been proposed a technique of protecting various equipments by canceling vibrations and shocks caused by earthquakes by elastic force.

Korean Patent No. 10-1027917 Korean Patent No. 10-1042577 Korean Patent No. 10-1081571 Korean Patent No. 10-1254091

However, in the above-described Patent Documents 1 and 2, in order to have an earthquake-proof performance, not only an additional structural change but also a complicated structure is required. In addition, it is possible to prevent a certain degree of equipment from being damaged in a weak earthquake with a small scale, It is not effective for earthquake of size 3 or more and has the disadvantage that it breaks or damages the equipment itself as well as the switchboard itself.

SUMMARY OF THE INVENTION The main object of the present invention is to solve the above-mentioned problems of the prior art by providing a wrinkle board panel itself and a simple connection structure constituting a transformer room without additional complicated earthquake- In type having an earthquake-proof performance that minimizes damage or deformation even when an earthquake occurs.

Another object of the present invention is to minimize the deformation on the connection portion where the wrinkle frame panel and the wrinkle frame panel are connected.

According to an aspect of the present invention, there is provided a floor panel comprising a roof, a base frame supporting the switchboard, an angle frame constituting a framework, and a plurality of corrugated panels attached to the angle frame to form a wall, Wherein the wrinkle corrugation of the corrugated panel of the corrugated panel of the wrinkle corrugated panel has a curved angle of 60 degrees and a length of 40 degrees of the inclined surface when the base material is formed by bending the corrugated panel, And the length of the horizontal surface (d) is 65 to 75 mm. The frame frame of the corrugated panel, which is in contact with the rim of the corrugated panel, is welded and fixed.

Wherein the upper and lower ends of the corrugated panel are entirely welded and fixed to portions of the frame frame that are in contact with the upper and lower frames, and both sides of the corrugated panel are welded to a plurality of points Welded and fixed.

The corrugated troughs are repeatedly formed such that the angle of curvature of the inclined surface is 60 DEG, the length of the inclined surface (c) is 40 mm, and the length of the horizontal surface (d) is 70 mm.

The roof and the base frame, which are in contact with the inner side surfaces of the upper and lower frames of the wrinkle frame panel, are bolted and fixed by a connecting member, and the upper and lower frames are bolted to the roof and the base frame.

A buffer pad is interposed between the corrugated web panels and between the angle frame and the corrugated web panel to be bolted and fixed.

And a plurality of reinforcing members arranged at predetermined intervals are bolted to the bottom surface of the lower frame of the wrinkle-rib panel.

The thickness of the corrugated panel is 2.3 mm, the thickness of the upper, lower, left and right frames of the frame frame is 3.3 mm, and the corrugated panel is a galvanized steel plate having a strength of 205 Mpa.

According to the present invention, it is possible to minimize breakage or deformation even when an earthquake having a magnitude (intensity) of 7 or less is generated by the wrinkle board itself constituting the transformer room and the simple connection structure without a separate complicated earthquake- It is possible to secure the high safety and to reduce the production cost due to the assembly of the substation and to easily install it.

Further, by minimizing the deformation on the connecting portion where the wrinkle-stiffening panel and the wrinkle-stiffening panel are connected, there is an effect that the safety against vibration or impact due to the earthquake is further enhanced.

1 is a front view and a cross-sectional view of a work-in transformer room for explaining the present invention,
FIG. 2A is an enlarged sectional view of a portion A according to FIG. 1,
FIG. 2B is an enlarged cross-sectional view of a portion B according to FIG. 1,
2C is a partially enlarged sectional view of the CC line in Fig. 1,
3 is a perspective view and a cross-sectional view of a wrinkle-rib panel according to FIG. 1,
FIG. 4 is a table showing results of strength simulation according to FIG. 2,
5C to 5C are a simulation for explaining a state where a load is applied to the wrinkle-rib panel,
FIG. 6 is a table showing results of strength simulation of a work-in transformer room,
7A to 7D are simulations for explaining a state in which a load is applied to the work-in transformer room according to FIG.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The present invention is not limited to the embodiments.

1 is an enlarged cross-sectional view of a portion A according to Fig. 1, Fig. 2b is an enlarged cross-sectional view of a portion B according to Fig. 1, and Fig. 2 Fig. 3 is a perspective view and a cross-sectional view of the corrugated panel according to Fig. 1, Fig. 4 is a result chart showing the results of the simulation of strength shown in Fig. 2, and Figs. 5c to 5c are cross- Fig. 6 is a simulation chart for explaining a state in which a load is applied to the corrugated panel; Fig. 6 is a result chart showing results of strength simulation of a work-in substation room; Figs. 7A to 7C are cross- This is a simulation for explaining a state where a load is applied to a substation room.

As shown in the figure, a roof 110 for protecting various equipment such as a switchboard built in from natural environment factors such as rain and snow, a base frame 120 supporting the switchboard as the built-in equipment, A work-in type transformer (100) for preventing breakage or deformation due to an earthquake, comprising a frame (130) and a plurality of corrugated panel (140) attached to the angle frame (130) .

The present invention minimizes damage or deformation even when an earthquake of at least a magnitude (intensity) of 7 or less is generated by the wrinkle board itself constituting the transformer room and the simple connection structure without having a separate complicated earthquake-resistant means have.

The corrugated trough of the corrugated panel 142 of the corrugated panel 140 constituting the wall of the transformer chamber according to the present invention is formed such that the angle of curvature of the inclined surface when the base material is formed by bending is 60 °, And the length of the horizontal surface d is 65 to 75 mm. The frame frame of the corrugated panel, which is in contact with the rim of the corrugated panel, is fixed by welding. At this time, the base material of the corrugated panel is an ordinary galvanized steel plate having a strength of 205 Mpa, a thickness of 2.3 mm, a width of 1,219 mm and a length of 2,438 mm.

Accordingly, as shown in the result table of FIG. 4, when the inclination angle is 60 °, c is 40 to 45 mm, and d is 65 to 75 mm, when the loss of the base material is minimized, have.

In other words, the most ideal condition is when the length c of the inclined surface c when the loss of the base material is smallest is 45 mm. That is, when c is 40 mm, the strength against the load may be high, but the loss of the base material is partially generated, and when c is 35, the loss rate of the base material is considerably high.

In addition, when the length (d) of the horizontal plane is also 70 mm, it can have the most ideal strength.

Meanwhile, a simulation result of the wrinkle-rib panel 140 having the above-described conditions and the wrinkle panels fixed to the frame frame will be described as follows.

The wrinkle frame panel 140 having the seismic performance has a frame frame 144 composed of upper, lower, left and right frames bent in a rectangular shape; A corrugated panel 142 formed with a corrugation by bending so as to be coupled to the frame frame 144 by welding or the like; An inner cover 146 which is welded to the rear of the frame frame 144 or coupled with screws or bolts; And a conventional thermal insulator 145 provided between the corrugated panel 144 and the inner cover 146. At this time, when the length of the inclined surface is 45 mm or more, a space for filling the heat insulating material between the corrugated panel and the inner cover can not be secured. The upper, lower, left, and right frames, which are the frame frame 144, are formed by a conventional method using a base material having a thickness of 3.3 mm.

The upper and lower ends of the corrugated panels 142 are welded to the upper and lower frames of the frame frame 144 by welding and the upper and lower ends of the corrugated panel 142 are welded to both sides of the corrugated panel 142. [ Are fixed to the left and right frames of the frame frame 144 by a plurality of spot welding at a predetermined interval of about 300 mm.

As shown in the simulation of Figs. 5A to 5C, the wrinkle-relief panel 140 has a curved shape with respect to the load applied in the horizontal direction (load 1), the vertical direction (load 2) 40 mm, and d is 70 mm, the wrinkle bone panel at the intensity of 7 or more indicates a time when the frame is deformed or damaged.

As shown in FIG. 5A, when the load 1 is applied, it can be confirmed that the deformation starts at the cell number 902 of the red portion, that is, at the portion where the frame frame and the corrugated panel are in contact with each other. At this time, the load is 4,548 kg.

When load 2 is applied as shown in FIG. 5B, it can be seen that deformation occurs in cell number 324 of the red color portion, that is, the portion where the vertical frame and the horizontal frame of the frame frame come into contact with each other. At this time, the load is 79 kg.

When the load 3 is applied as shown in FIG. 5C, it can be seen that deformation occurs in cell number 12 of the red color portion, that is, the portion where the vertical frame and the horizontal frame of the frame frame come into contact with each other. At this time, the load-bearing capacity is 110 kg.

As a result of experimenting with a wrinkle board including a wrinkle panel having a seismic performance in a frame frame as in the load 1 to 3, the seismic performance can be further improved.

Therefore, even when an earthquake having a magnitude (intensity) of 7 or less is generated, it is not required to have a separate earthquake-resistant means and it is possible to prevent damage or damage to the wrinkle-

The roof frame 110 and the base frame 120 which are in contact with the inner side surfaces of the upper and lower frames of the wrinkle frame panel 140 are fixed to the normal bolts and nuts by the connecting member 10, And the upper and lower frames are bolted to the respective roofs 110 and the base frame 120 by means of ordinary bolts and nuts. Therefore, it is possible to minimize the occurrence of damage or deformation due to vibrations or shocks caused by earthquakes, as it has a higher clamping and clamping force with the base frame as well as the wrinkle frame panel and the roof.

Between the corrugated web panels 140 and between the angle frame 130 and the corrugated web panel 140, there is provided a buffer having a buffering force such as rubber, silicone, urethane, etc. so as to absorb vibrations or shocks due to earthquakes. And the pad 20 is interposed therebetween and fixed by bolts and nuts by means of ordinary bolts and nuts. Therefore, the vibration absorbing pad absorbs vibrations or shocks caused by an earthquake by the cushioning pads interposed between the corrugated panel and each other, thereby minimizing damage or deformation.

In addition, a plurality of reinforcing members 30, which are arranged at predetermined intervals, are bolted and fixed to the bottom surface of the lower frame of the base frame 120 and the wrinkle frame panel 140 by ordinary bolts and nuts. The reinforcing members are arranged at intervals of about 500 mm to support the base frame or the wrinkle-ribbed panel against the earthquake. That is, since the base frame and the wrinkle-stiffening panel are formed to have a relatively large area, it is possible to minimize the distortion due to the high strength against the earthquake. Thereby making it possible to further minimize damage or deformation of the work-in transformer room.

The earthquake-proof performance simulation is performed on the work-in power transforming room 100 of the present invention assembled with the wrinkle crest panel 140 constituting the wall with the roof 110, the base frame 120, and the angle frame 130 as described above 6 and the simulations of FIGS. 7A to 7D will be described as follows.

The corrugated panel 142 welded to the frame 144 of the corrugated panel 140 has an angle of curvature of 60 degrees for the inclined surface and a length of 40 mm for the inclined surface c, Mm, and the X-axis and Y-axis have been experimented with a strength of at least 7 on the scale.

As shown in the experimental result table and simulation, from the edge portion of the base frame 120 where the edge portion of the frame under the frame frame 144 of the wrinkle frame panel 140 located at the corner portion of the wall is in contact with the edge portion of the lower frame It can be seen that deformation starts.

In other words, when the displayed cell number 42383 of the base frame 120 indicated in the simulation and the lower frame cell number 26029 of the corrugated panel 140 in contact with the base frame 120 are subjected to a strength of 7 or more on the Richter scale, Can be confirmed. At this time, the seismic performance (g) of the X axis is 0.678 g and the seismic performance (g) of the Y axis is 0.793 as shown in the result table.

As described above, in the case of the transformer room of the present invention, it can be clearly seen that breakage or deformation occurs from corners of the corrugated panel and the base frame at a strength of 7 or more on the scale of scale.

Thus, the present invention is not limited to the separate seismic means, but the angle of bend of the inclined surface of the corrugated panel of the corrugated panel is 60, the length of the inclined surface c is 40 mm, and the length of the horizontal surface d is 70 mm It can be confirmed that even with a simple connecting structure at each connecting portion, the seismic performance is sufficient even with a strength of 7 or more on the scale of the Richter scale.

As a result, it is possible to sufficiently cope with an earthquake frequently occurring in recent years, so that the condition for safely using the work-in substation room is provided.

In addition, it is possible to prevent breakage or deformation even at the intensity of a scale of 7 with the components constituting the transformer room in the process of making the transformer room have seismic performance in the work-in transformer room, It also has excellent conditions.

10: connecting member 20: cushion pad
30: reinforcement member 100: transformer room
110: roof 120: base frame
130: Angle frame 140: Wrinkle corrugated panel
142: corrugated panel 144: frame frame
145: Insulation material 146: Inner cover

Claims (7)

A roof frame, a base frame for supporting the switchboard, an angle frame constituting a framework, and a plurality of corrugated panel panels attached to the angle frame to form a wall, to prevent breakage or deformation due to an earthquake As a type of transformer room,
The corrugated ribs of the corrugated panel of the wrinkle corrugated panel are formed such that the angle of curvature of the inclined surface is 60 °, the length of the inclined surface (c) is 40 to 45 mm and the length of the horizontal surface (d) is 65 to 75 mm Wherein the upper and lower ends of the corrugated panel of the corrugated panel panel which are in contact with the corners of the corrugated panel are welded to and fixed to the upper and lower frames of the frame frame, An inner cover fixed to the frame at a predetermined interval by a plurality of spot welding and fixed to the frame at a predetermined interval, the inner cover being coupled to the rear of the frame frame, and a heat insulating material provided between the corrugated panel and the inner cover,
The roof and the base frame, which are in contact with the inner side surfaces of the upper and lower frames of the wrinkle frame panel, are bolted and fixed to prevent breakage or deformation from vibration or impact by the connecting member. And bolted to prevent breakage or deformation from vibration or impact,
A buffer pad having a buffering force is inserted between the corrugated web panels and between the angle frame and the wrinkle corrugated panel so as to absorb vibrations and shocks,
Wherein a bottom surface of the lower frame of the wrinkle-rib panel is bolted to a plurality of reinforcing members arranged at predetermined intervals to prevent the lower frame from being warped. delete The method according to claim 1,
Wherein the corrugated trough is repeatedly formed so as to have a bending angle of 60 degrees on the inclined surface, a length of 40 mm on the inclined surface (c), and a length of 70 mm on the horizontal surface (d) Substation of. delete delete delete The method according to claim 1,
Wherein the thickness of the corrugated panel is 2.3 mm, the thickness of the upper, lower, left and right frames of the frame frame is 3.3 mm, and the corrugated panel is a galvanized steel plate having a strength of 205 Mpa. Type substation.

Images