KR200468857Y1 - The stand with anti-earthquake structure - Google Patents

Abstract

The present invention relates to a steel frame having a seismic structure, and more particularly, to a mount having one or more layers to align a large capacity battery, and having a seismic structure that can be protected from external shock or vibration. .
A first embodiment of the present invention protrudes so as to protrude upward from the ground to form a plane; At least one upright frame spaced apart from each other at a predetermined interval to form a group, and an upright frame fixed to the ground by forming one row for each group; One or more horizontal frames fixed to the upright frame and extending in directions crossing each other to form a bottom surface on which one or more batteries are aligned; And a support frame extending and fixed to be inclined from the upright frame to an upper surface of the protruding end to fix the upright frame, wherein the upright frame is formed in one or more groups, and each row is formed in each group. Is fixed to an upright frame positioned on the outside of each group is extended to be inclined to the ground is fixed at the bottom of the upright frame located on the outermost and is fixed to an extension bracket extending in close contact with the upper surface of the protruding end do.

Description

The stand with anti-earthquake structure

The present invention relates to a steel frame having a seismic structure, and more particularly, to a mount having one or more layers to align a large capacity battery, and having a seismic structure that can be protected from external shock or vibration. .

In general, several battery-powered power supplies are constructed for use as emergency power sources in power plants or other large buildings. Many of these batteries are aligned and supported by mounts.

The mount is generally a structure in which a plurality of vertical and horizontal frames are interconnected to support a panel forming a bottom surface.

This conventional mount is a structure that overlaps in order to align a plurality of batteries to be aligned rather than fixed, the situation in which the collapse of the mount in the event of an earthquake or the battery is detached from the mount to supply power in an emergency. This may occur.

That is, the conventional battery mount was not designed to be earthquake-resistant, and when installed in a facility such as a power plant, secondary damage due to an earthquake could occur, so it was very urgent to install the mount having a seismic structure. .

The present invention is devised to solve the conventional problems as described above, the object of the present invention is a seismic structure for accommodating the battery having a firm coupling force that can be maintained even if the earthquake or other external shock or vibration is applied In providing a mount having a.

The present invention includes the following embodiments in order to achieve the above object.

A first embodiment of the present invention protrudes so as to protrude upward from the ground to form a plane; At least one upright frame spaced apart from each other at a predetermined interval to form a group, and an upright frame fixed to the ground by forming one row for each group; One or more horizontal frames fixed to the upright frame and extending in directions crossing each other to form a bottom surface on which one or more batteries are aligned; And a support frame extending and fixed to be inclined from the upright frame to an upper surface of the protruding end to fix the upright frame, wherein the upright frame is formed in one or more groups, and each row is formed in each group. Is fixed to an upright frame positioned on the outside of each group is extended to be inclined to the ground is fixed at the bottom of the upright frame located on the outermost and is fixed to an extension bracket extending in close contact with the upper surface of the protruding end do.

In a second embodiment of the present invention, the horizontal frame comprises at least one first horizontal frame connected to at least one upright frame forming each column; And at least one second horizontal frame extending from and fixed to any one of the last rows in the upright frame of the first row on the upper side of the first horizontal frame to form a bottom surface on which the battery is seated.

In a third embodiment of the present invention, it is preferable that the mount forms one or more layers by the first horizontal frame and the second horizontal frame.

In the fourth embodiment of the present invention, the mount is fixed to extend to the upright frame of each row, the upright surface is fixed so as to be in contact with the side of the battery seated on the horizontal frame to face the inside aligned with the battery A first fixed frame; At least one second fixing frame extending in a direction intersecting with the first fixing frame in a first row and fixed to an upright frame in any one row of upright frames in a last row to press and close the front and rear surfaces of the battery; The first fixing frame and the second fixing frame are formed to have an upright surface to be in close contact with the side, front and rear surfaces of the battery, respectively, and the upright surface is fixed to face the inside.

In a fifth embodiment of the present invention, it is preferable that one or more of the batteries are grouped and fixed so as to be in close contact with each other.

In the sixth embodiment of the present invention, the upright frame preferably further includes a bending groove formed in a 'c' shape, and a reinforcing plate tightly fixed in a shape corresponding to the bending groove.

According to the present invention, a plurality of batteries can be grouped and pressurized and fixed in each group as described above, so that the alignment of the batteries can be maintained even when external shocks or vibrations are applied, and the upright frame is provided at a protruding end projecting from the ground. It can be fixed from the outside by a fixed support frame has a stronger bonding force has an effect that is not damaged even during external shock or vibration.

1 is a front view showing a mount having a seismic structure according to the present invention,
Figure 2 is a side view showing the mount having a seismic structure according to the present invention,
3 is a partially enlarged plan view of the upright frame in a mount having a seismic structure according to the present invention.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the mount having a seismic structure according to the present invention will be described in detail.

1 is a front view showing a mount having a seismic structure according to the present invention, Figure 2 is a side view showing a mount having a seismic structure according to the present invention.

1 and 2, the mount 1 having a seismic structure according to the present invention includes a first to third upright frames 111 to 113 that are aligned in the same direction, respectively. (11), a first frame for pressing and fixing the horizontal frame (141, 142) that is fastened to the upright frame (11) to form a bottom surface to align the battery, and the battery (2) aligned to the mount 1 The fixed frame 161 and the second fixed frame 162, the upright frame 11 and the horizontal frame are fastened to be inclined to the first upright frame 11 to the third upright frame 113 and the first horizontal frame ( 141 to 2, 2 and 2, the connecting frames 121 and 122 for supporting the second horizontal frame 142, and to be inclined from the outer surface of the first upright frame 111 and the third upright frame 113 to an upper surface of the protruding end. The support frame 15 is fixed, and a flat plane protrudes from the top surface to protrude from the ground 3 so that the mount 1 is installed. And a protruding end 4.

The protruding end 4 protrudes upward from the ground 3 to form a space in which the mount 1 is seated. Therefore, it is preferable that the protruding end 4 is installed to have an area considering the area of the mount 1.

Here, since the protruding end 4 protrudes more than a predetermined height from the ground, it is possible to mitigate the impact of the ground distortion, depression or vibration during the earthquake. Since the seismic effect according to the structure of the protruding ground is generally known, the detailed description thereof is omitted.

The first to third upright frames 111 to 113 are arranged in order from the first upright frame 111 to the third upright frame 113 to form a row, and the first to third upright frames ( A plurality of rows 111 to 113 are fixed to the upper surface of the protruding end.

The first horizontal frame 141 and the second horizontal frame 142 are fixed to the upright frame 11 to form a bottom surface of the mount 1 on which the battery 2 is seated.

Here, the first horizontal frame 141 is connected to the first upright frame 111, the second upright frame 112 and the third upright frame 113 in each column, the second horizontal frame 142 is The upright frame 11 of the first row extends and is fixed to any one row of the upright frames 11 of the last row. That is, the first horizontal frame 141 and the second horizontal frame 142 extend in a direction crossing each other and are fixed to the upright frame 11.

The first horizontal frame 141 extends from the first upright frame 111 to the third upright frame in each column, and the second horizontal frame 142 is located above the first horizontal frame 141. Extending in a direction crossing the first horizontal frame 141 may form a bottom surface on which the battery 2 is seated.

In addition, the present invention forms a bottom surface on which the battery 2 is aligned through the second horizontal frame 142 supported by the first horizontal frame 141 as described above, but may be installed in a single layer or a two-layer. .

1 and 2 show that the bottom surface on which the battery 2 is aligned is formed in two layers. To explain this, the bottom surface of the first floor is formed with the first horizontal frame 141 and the second horizontal frame 142 on the lower side, the first to third upright frame of each row in the upper side of the bottom surface of the first floor. By the first horizontal frame 141 connected to the upper side of the 113, and the second horizontal frame 142 connected to the upright frame 11 of any one column of the upright frame 11 of the last column in the first row. Form two layers.

The first fixing frame 161 extends from the first upright frame 111 forming a row to the third upright frame 11 and is fixed to be positioned at a middle height of each layer (see side view of FIG. 2). The two fixed frames 162 are fixed between upright frames to extend between rows (see front view of FIG. 1).

The first fixing frame 161 extends and is fixed from the first upright frame 111 to the third upright frame 113 in each row, and the upright surface of the first fixing frame 161 may be in close contact with the side surface of the battery 2. 2) is fixed to face the inside that is aligned. Preferably, the first fixing frame 161 is formed in a 'b' shape and the upright surface is pressed against the side surface of the battery 2.

The second fixing frame 162 is formed in a 'b' shape so as to be in close contact with the front and rear of the battery (2) aligned in each layer extending laterally in the first row to the last row. The second fixing frame 162 is fixed to face inward so that the upright surface may be in close contact with the front or rear surface of the battery.

That is, the first fixing frame 161 presses the side of the battery 2 to be aligned, and the second fixing frame 162 is in close contact with and fixed to the front and rear of the battery 2.

The connecting frames 121 and 122 extend from one side of the bracket protruding from the outer surface of the first to third upright frames 111 to 113 (collectively referred to as upright frames 11) to be inclined to be inclined. It is fixed to the lower end of the second fixing frame 162 located in. Here, the connection frames 121 and 122 are fastened to reinforce the coupling force between the upright frame 11 and the fixed frame. Preferably, the first horizontal frame 141 or the second horizontal frame 142 is connected to the upright frame 11, but also the upright frame 11 of the mount frame 1 composed of a horizontal frame and a fixed frame Strengthen the bond.

The first to third upright frames 111 to 113 further include a bending groove 111a bent as a 'c'-shaped beam and a reinforcement plate 111b for reinforcing rigidity inside the bending groove 111a. This is as shown in Figure 3 below. 3 is a partially enlarged plan view of the upright frame 11 in the mount 1 having the seismic structure according to the present invention.

Referring to FIG. 3, the first to third upright frames 113 according to the present invention are installed such that the bent groove 111a is directed toward the outside as a 'c' shaped beam. At this time, the reinforcing plate (111b) is in close contact with the inner surface of the bending groove (111a) is formed to extend vertically.

The reinforcing plate (111b) is formed in the bending groove (111a) of the first upright frame (111) to the third upright frame (113) to strengthen the rigidity to withstand the impact of vibration or shock caused by earthquakes or other pressure Strengthen the rigidity so that.

The support frame 15 extends from the outer surfaces of the first upright frame 111 and the third upright frame 113 to be inclined to the top surface of the protruding end 4 to support the mount 1.

At this time, the support frame 15 is fastened to an extension bracket 1113 extending in close contact with the upper surface of the protruding end 4 at the lower ends of the first upright frame 111 and the third upright frame 113 and the ground (3). It is fixed to). In addition, the upper end of the support frame 15 is fixed to the outer surface of the first upright frame 111 and the third upright frame 113, respectively.

The support frame 15, the first upright frame 111 and the third upright frame 113 may be formed by fixing a screw hole corresponding to each other on the outer surface to be fixed as screws, bolts and washers, by welding or bracket Can be fixed by screwing.

The present invention is configured as described above to maintain a state in which a plurality of batteries (2) are electrically connected in a power plant or other facilities that require the input of a large capacity power source. Hereinafter will be described the operation achieved through the configuration as described above.

Protruding end to protrude from the ground (3) to assemble a strong mount (1) that can withstand a number of batteries (2) selected to obtain a large amount of power from the impact or pressure caused by earthquake, fire or collision accident (4) is formed.

At this time, the protruding end 4 has a protruding end so as to form a flat surface in consideration of the area including the position of the support frame 15 extending and inclined from the outside of the mount 1 and the mount 1. 4) form.

Then, the worker arranges the upright frames 11 at regular intervals from each other to form rows and rows to fix them. That is, each column is composed of the first upright frame 111, the second upright frame 112, and the third upright frame 113 and spaced apart at regular intervals.

Thereafter, when the upright frame 11 is fixed to the protruding end 4, the worker fixes the first horizontal frame 141 at the lower side of the upright frame 11 in each row. In addition, the worker extends the second horizontal frame 142 horizontally from the upper side of the first horizontal frame 141 to be fixed to the upright frame 11 of each row to form a bottom surface on which the battery 2 is seated. .

In this order, the first horizontal frame 141 and the second horizontal frame 142 may be sequentially formed on the upright frame 11 in consideration of the height of the battery 2 to form two layers.

Then, the worker connects and fixes the first fixing frame 161 as the height of the lower half of the upright frame 11 of each row. In this case, the first fixing frame 161 may be fixed to the first to third upright frames 113 of each row by welding or bolts and screws.

In addition, the operator positions the second fixing frame 162 to be in close contact with the first upright frame 111 of the last row from the first upright frame 111 of the first row and then fixed by bolts, screws or welding. Similarly, the second upright frame 112 of the last row in the second upright frame 112 of the first column. The second fixing frame 162 is connected to each other in the direction of the third upright frame 113 of the last row from the third upright frame 113 of the first row to fix each other.

Accordingly, one side of the battery 2 aligned with the mount 1 is pressed by the first fixing frame 161, and the front and rear surfaces of the battery 2 are fixed by the second fixing frame 162.

Herein, the batteries 2 may be supported by the first fixing frame 161 and the second fixing frame 162 in a group of four. For example, two batteries 2 located at one side of the four batteries 2 are aligned with each other so that one surface thereof is in close contact with each other. The second fixing frame 162 is closely attached to and fixed to the rear surfaces of the two batteries 2 positioned at the front and rear of the battery 2, respectively. As such, the present invention divides and supports the battery 2 into a small number of groups, so that even when an earthquake or other impact is applied, the alignment state can be maintained firmly.

In addition, the connecting frames 121 and 122 are connected to be inclined between the first fixing frame 161 and the second fixing frame 162 in the first upright frame 111 to further strengthen the coupling force.

In addition, the worker connects the extension bracket 1113 so as to be in close contact with the upper surface of the protruding end 4 at the lower end of the first upright frame 111 and the third upright frame 113 in each row, the extension bracket ( Fasten the lower end of the support frame 15 at one end of the 1113. And the upper end of the support frame 15 is fixed to the upper end of the first upright frame 111 and the third upright frame 113 in the inclined direction, respectively.

As such, the present invention can support the battery 2 by dividing the battery 2 into a small number of groups by the first fixing frame 161 and the second fixing frame 162. As supported by the support frame 15 from the outside has a strength that can withstand an impact, such as an earthquake.

Although the present invention has been described in detail with respect to the embodiments described, it will be apparent to those skilled in the art that various changes and modifications can be made within the technical spirit of the present invention, and such modifications and modifications belong to the appended utility model claims.

1: mount 2: battery
3: ground 4: protrusion
11: upright frame 111: first upright frame
111a: bending groove 111b: reinforcement plate
112: second upright frame 113: third upright frame
121, 122: connection frame 141: first horizontal frame
142: second horizontal frame 161: first fixed frame
162: second fixed frame

Claims (6)

A protruding end protruding upward from the ground to form a plane;
At least one upright frame spaced apart from each other at a predetermined interval to form a group, and an upright frame fixed to the ground by forming one row for each group;
One or more horizontal frames fixed to the upright frame and extending in directions crossing each other to form a bottom surface on which one or more batteries are aligned; And
And extending from the upright frame to be inclined to the upper surface of the protruding end includes a support frame for fixing the upright frame,
The upright frame is composed of one or more groups, each group of columns,
The support frame is fixed to an upright frame located on the outside in each group is extended to be inclined to the ground is fixed at the bottom of the upright frame located on the outermost is fixed to the extension bracket extending in close contact with the upper surface of the protruding end Stand with seismic structure. The method of claim 1, wherein the horizontal frame
At least one first horizontal frame connected to at least one upright frame forming each column; And
And a seismic structure including one or more horizontal frames extending from and fixed to any one of the last rows in the upright frames in the first row above the first horizontal frames to form a bottom surface on which the battery is seated. The method of claim 2, wherein the mount
A mount having a seismic structure of one or more layers formed by the first horizontal frame and the second horizontal frame. The method of claim 1, wherein the mount
A first fixed frame extending and fixed to an upright frame of each row, the upright surface being fixed to face the inside where the battery is aligned so as to be in close contact with the side of the battery seated on the horizontal frame;
At least one second fixing frame extending in a direction intersecting with the first fixing frame in a first row and fixed to an upright frame in any one row of upright frames in a last row to press and close the front and rear surfaces of the battery;
The first fixing frame and the second fixing frame is formed to have a surface upright so as to be in close contact with the side, front and rear of the battery, respectively, wherein the upstanding surface has a seismic structure that is fixed to face inward. The battery of claim 1, wherein the battery is
A trestle having one or more seismic structures that are grouped and fixed so that one surface is in close contact with each other. According to claim 1, wherein the upright frame is
Stand having a seismic structure further comprising a bending groove formed in the 'c' shape, and a reinforcing plate tightly fixed in a shape corresponding to the bending groove.

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