KR20110001776A - Earth quake-proof reinforcement structure installed for operating electric panel anticipating without moving and interruption of power supply - Google Patents

Abstract

PURPOSE: An earth quake-proof reinforcement structure installed for operating an electric panel anticipating without moving and interruption of power supply are provided to prevent damage to a switchboard support by blocking vibration from earth quake in an X-axis direction and an Y-axis direction. CONSTITUTION: An upper support plate(130) is installed on a bottom slab by a plurality of support bars. The switchboard(100) is supported on the upper support plate by a support panel. First and the second reinforcing members(150) are fixed in lower part of the upper support plate to reinforce the upper support plate. One end of first and second turnbuckles is connected to the bottom slab. The other end of the first and the second turn buckle is connected to the first and second reinforcing member.

Description

Earthquake-proof reinforcement structure installed for operating electric panel anticipating without moving and interruption of power supply}

The present invention relates to a reinforcing structure for reinforcing seismic performance in a switchboard, which is a power supply equipment. In particular, the seismic reinforcing member is installed in a switchboard in an uninterruptible and non-separable state to provide a seismic performance due to an earthquake or vibration. The present invention relates to a seismic reinforcing structure that is installed without a relocation.

In general, the equipment of the switchboard or relay panel is installed in a double-floor seismic reinforcement structure by installing a new floor plate on the building floor to reinforce the seismic performance. This switchboard double bottom seismic reinforcement structure, the vertical support rods on the concrete slab floor at regular intervals by applying an epoxy adhesive (Epoxy) adhesive, it is to install a new bottom plate via a plurality of vertical support rods on the concrete slab floor.

In the conventional switchboard seismic reinforcement structure, as shown in FIG. 1, the support upper plate 4 is spaced apart from the support member 3 of the vertical support rod 2 on the bottom slab 1, and the support upper plate is provided. The switchboard 100 is seated on the mounting bracket 5 fixed to (4) so that the earthquake-resistant earthquake is reinforced.

The support top plate 4 and the mounting bracket 5 are fixed to the L-shaped bracket 6 by using horizontal and vertical bolts 7a and 7b, and the L-shaped bracket 6 and the support top plate 4 are fixed. Each pipe 8 is fastened to the vertical bolt (7b) penetrating the spaced apart. The square tube 8 is fastened to the U-shaped bolt 10 and the fixing bolt 11 through the vertical support rod (2) and the L-shaped steel (9), the fixing bolt 11 is fastened to the L-shaped steel (9) Shackle 12 is to be connected to the turnbuckle 14 is installed on the anchor bracket 13 of the floor slab (1).

In the conventional switchgear seismic reinforcement structure, one end of the turnbuckle 14 is connected to the L-shaped steel 9 through the fixing bolt 11 and the other end is connected to the anchor bracket 13 of the bottom slab 1 with respect to the Y axis. It is designed to have seismic force in seismic motion, but it is weak in seismic motion on X axis. Therefore, the structure supporting the switchboard may be damaged by the earthquake movement transmitted to the X-axis due to the earthquake, etc., and thus, the seismic safety is deteriorated.

Accordingly, an object of the present invention has been devised to solve the above-described problems, seismic power is installed in the switchboard so as to increase the seismic safety by having a seismic force in the earthquake movement sheared on the X-axis and the Y-axis to be installed in an uninterrupted and no seismic To provide a reinforcing structure.

In order to achieve the above object, the present invention, the support slab installed on the bottom slab spaced apart through a plurality of support rods, a switchboard supported by a support panel on the upper portion of the support upper plate, and the state in close contact with the lower support plate First and second reinforcement to be fixed to the reinforcing the support top plate, and the first and second turnbuckle connected to one end of the bottom slab and the other end to the first and second reinforcement, the second reinforcement To the first reinforcing material and the support bar is fixed to the bowl with a support bracket inserted between the support rod and the second reinforcing material has a structure to reinforce the earthquake resistance in the X-axis and Y-axis direction.

With the L-shaped brackets against the support top plate and the support panel, the support top plate and the first reinforcement are simultaneously fixed in the vertical direction while fixing the support panel in the horizontal direction using a bolt.

The support panel may be replaced with a gap adjusting member, and the support bracket and the first reinforcement may be simultaneously fixed by using a bolt on the bending bracket while the bending bracket is fitted to the gap adjusting member.

The supporting rods, the second reinforcing material, and the supporting brackets disposed between the supporting rods and the second reinforcing materials, respectively, have a structure in which the bolts are integrally coupled to each other.

One end is coupled to the second reinforcement and provided with a third reinforcement coupled to the other end of the anchor bracket connecting the support rod, it may be a structure to reinforce the force load and the buckling load of the support rod.

The first turnbuckle is installed between the bottom slab and the first reinforcing material, the second turnbuckle is installed between the bottom slab and the second reinforcing material, it is preferable to be disposed relatively lower than the first turnbuckle on the basis of the floor slab. Do.

The first and second turnbuckles are respectively installed on the bottom slab via an anchor bracket.

When the lower slab is installed lower on the support plate, the second turnbuckle may be replaced by a flat bar.

According to the seismic reinforcement structure installed in the switchboard according to the present invention in an uninterruptible and non-separable manner, the first turn buckle is connected to the first reinforcement and connected to the floor slab via the anchor bolt of the anchor bracket to prevent seismic movement in the X-axis direction. On the other hand, the second turn buckle is connected to the second reinforcement and connected to the floor slab via the anchor bolt of the anchor bracket to prevent seismic movement in the Y-axis direction. As a result, the support of the switchboard is able to minimize the damage caused by the earthquake movement and to increase the seismic safety much more than before.

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

2 is a cross-sectional view showing a switchgear seismic reinforcing structure according to the present invention, Figure 3 is a cross-sectional view shown in one direction of FIG.

In the switchgear seismic reinforcing structure according to the present invention, as shown in Figures 2 and 3, the support top plate 130 is installed on the bottom slab 110 via a plurality of support rods 120, the support top plate ( The switchboard 100 is supported by the support panel 102 on the upper portion of the 130, and the first and second reinforcing materials 140 and 150 are installed in close contact with the lower portion of the support upper plate 130, and the floor slab 110 is provided. One end is connected to the first and second turnbuckles 160 and 170 are connected to the other end is connected to the first and second reinforcement (140,150).

The switchboard 100 has a structure in which a lower portion thereof is supported through the support panel 102 installed on the support upper plate 130. Here, the support panel 102 and the support top plate 130 is coupled to the L-shaped bracket 104 butt. That is, the L-shaped bracket 104 is configured to be coupled to the side surface of the support panel 102 by using the bolt 103 in the horizontal direction, and the support upper plate 130 by using the bolt 105 in the vertical direction. The first reinforcing material 140 is to be coupled at the same time.

When the supporting panel 102 performs a drilling operation to fasten the bolt 103 to the switchboard 100 in operation, an acceleration amplitude of more than a nodal frequency (55Hz to 60Hz) is prevented to prevent contact malfunction of the switchboard 100. It is preferable to use a special low vibration drilling machine so that it can be drilled within the KS vibration regulation prescribed at 0.5g.

Meanwhile, as shown in FIG. 4, the switchboard 100 may be changed to a structure supported by the support upper plate 130 using the gap adjusting member 106 and the bending bracket 108. That is, the gap adjusting member 106 is disposed below the power distribution plate 100, one end of the bending bracket 108 penetrates the gap adjusting member 106, and the other end is the bolt 105 to support the upper plate 130. And the first reinforcing material 140 can be changed to a structure for fixing at the same time.

The support rod 120 has a lower end portion fixed to a plurality of points at predetermined intervals on the bottom slab 110 to support the support upper plate 130. That is, the support rod 120 has a lower end portion fixed to the bottom slab 110 by an anchor bolt 124 through an anchor bracket 122, and an upper end portion of the first reinforcing material 140 supporting the support upper plate 130. And the second reinforcing material 150, and the second reinforcing material 150 is fixed in the horizontal direction using the bolt 126.

Here, the anchor bolt 124 and the second reinforcement 150 of the anchor bracket 122 serves to prevent seismic movement in the Y-axis direction.

The support rod 120 is coupled to the support upper plate 130 by using the fitting member 128 at the upper end.

 The first reinforcing material 140 is coupled to the support top plate 130 at the same time through the bolt 106 to the L-shaped bracket (104).

As shown in FIGS. 4 and 5, the second reinforcing material 150 has an L-shaped structure and is disposed on both sides of the support rod 120, and is fixed through the bolt 126. The second reinforcing material 150 has a support bracket 152 inserted therebetween, and the support bracket 152 is fixed together with the bolt 126 in the horizontal direction.

Meanwhile, as shown in FIGS. 6A and 6B, one end of the second reinforcement 150 is coupled to one side of the second reinforcement 150, and the third reinforcement of the C-shaped structure having the other end coupled to the anchor bracket 122. It can be installed to reinforce the support rod (120).

Here, the third reinforcing material 180, but the weight of the switchboard 100 is generally 100 ~ 800 Kg or so, the holding rod 120 is to be installed to prevent the occurrence of development or buckling by excessive load.

As shown in FIG. 3, the first turnbuckle 160 is connected to the first reinforcing material 140 through a connecting pin 162, and a lower portion of the first turnbuckle 160 is connected to the bottom slab 110. 123 is connected to the anchor bracket 121 is fixed by the connecting pin 164.

In this case, the first turn buckle 160 is connected to the first reinforcing material 140 and connected to the bottom slab 110 by the anchor bolt 123 of the anchor bracket 121 to vary the length of the X-axis Prevents earthquake movement in the direction.

As shown in FIGS. 2 and 3, the second turn buckle 170 has an upper bracket connected to the second reinforcement 150 and a lower bracket fixed to the bottom slab 110 with an anchor bolt 124. And to be connected with 122.

Here, the second turn buckle 170 is disposed relatively lower than the first turn buckle 160 based on the floor slab 110. In addition, the second turn buckle 170 is connected to the second slab 150 and the bottom bracket 110 by the anchor bolt 124 of the anchor bracket 122, the length thereof is variable in the Y-axis direction Prevents earthquake movements

On the other hand, if the overall height of the support top plate 130 is installed too low in the floor slab 110, it is difficult to install the second turn buckle 170, and replaced with the flat bar (11a) as shown in FIG. can do. The flat bar 11a has an upper portion connected to the second reinforcing member 150 and a lower portion connected to the bottom slab 110 with an anchor bolt 124 of the anchor bracket 122.

As described above, the present invention has been described based on the preferred embodiments, but is not limited to the specific embodiments, it can be changed within the scope described within the claims by those skilled in the art.

1 is a cross-sectional block diagram showing a switchgear seismic reinforcing structure according to the prior art,

Figure 2 is a cross-sectional configuration showing a switchgear seismic reinforcement structure according to the present invention,

3 is a cross-sectional configuration view shown in one direction of FIG.

4 is a view showing a portion A of FIG. 2 changed to another structure;

5 is a combined state of the support rod and the second reinforcing material is coupled,

6a and 6b is a combined state of the support rod and the second and third reinforcement,

FIG. 7 is a view showing another structure modification of part B of FIG. 3.

Explanation of symbols on the main parts of the drawings

100: switchboard 110: floor slab

120: support rod 130: support top plate

140: first reinforcing material 150: second reinforcing material

160: first turn buckle 170: second turn buckle

180: third reinforcement 190: flat bar

Claims (8)

A support top plate spaced apart from the plurality of support rods on the floor slab, A switchboard supported by a support panel on an upper portion of the support upper plate; First and second reinforcing members fixed in a state of being in close contact with a lower portion of the support upper plate, and reinforcing the support upper plate; A first and second turnbuckle connected to the bottom slab at one end thereof and connected to the first and second stiffeners at the other end thereof; The second reinforcing material against the first reinforcing material and the support bar and the support bracket inserted between the support rod and the second reinforcing material is fixed to the bowl and the structure to reinforce seismic resistance in the X-axis and Y-axis direction uninterrupted and Seismic reinforcement structure installed in a no-separation manner. The method of claim 1, A switchboard characterized in that the support top plate and the support panel to the L-shaped bracket in the state, while fixing the support panel in the horizontal direction using a bolt while fixing the support top plate and the first reinforcement in the vertical direction at the same time Earthquake-proof reinforcement structure installed in an uninterruptible and no relocation method in the The method of claim 1, The support panel is replaced with a gap adjusting member, and the support bracket and the first reinforcement are simultaneously fixed by using a bolt on the bending bracket while the bending bracket is fitted to the gap adjusting member. And a seismic reinforcement structure installed in a no-separation manner. The method of claim 1, The support rods, the second reinforcement and the support brackets disposed between the support rods and the second reinforcement, respectively, are seismic reinforcement installed in an uninterruptible and non-separable manner in a switchgear, characterized in that the structure is to be integrally coupled by penetrating the bolt. rescue. The method of claim 4, wherein One end is coupled to the second reinforcing material and having a third reinforcing material is coupled to the other end to the anchor bracket connecting the support rod, the switchboard characterized in that the structure to reinforce the force load and the buckling load of the support rod Earthquake-proof reinforcement structure installed in an uninterruptible and no relocation method in the The method of claim 1, The first turnbuckle is installed between the floor slab and the first reinforcement, The second turn buckle is installed between the floor slab and the second reinforcement, seismic reinforcement structure is installed in the uninterrupted and non-separable manner in the shipboard, characterized in that disposed relative to the lower slab relative to the first turn buckle relative to the first slab. . 7. The method according to claim 1 or 6, The first and second turn buckle is seismic reinforcement structure is installed in an uninterruptible and no relocation method on the switchboard, characterized in that installed on the floor slab through the anchor bracket. 7. The method according to claim 1 or 6, The seismic reinforcement structure is installed in an uninterruptible and non-removable manner in a switchboard, characterized in that when the lower slab is installed on the support top plate, the second turnbuckle is replaced by a flat bar.

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