JP2009142143A - Aseismatic reinforcing structure to switchboard attached on access floor which has become high without movement or power break - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an aseismatic reinforcing structure to a switchboard attached on an access floor which has become high without switchboard movement or power break. <P>SOLUTION: The aseismatic reinforcing structure for a power supply switchboard or a distribution board attached on an access floor system which has become high in order to reinforce an aseismatic capability is disclosed. More specifically, the aseismatic reinforcing structure is attached even to the existing and operating switchboard or distribution board having the aseismatic capability without need of the movement of the operating switchboard or distribution board or the power break. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a seismic reinforcing structure attached to a power distribution board or distribution board for reinforcing the seismic capacity. More particularly, the present invention can be attached to an existing operating distribution board or distribution board having seismic capability without the need for transfer or power interruption of the operating distribution board or distribution board. It relates to seismic reinforcement structure.

  Generally, when installing power supply equipment such as distribution boards, or other equipment provided in monitoring signal boards, switchboards, communication panels, protection panels, control rooms, communication control lines, computing devices, etc. Such equipment will be installed on a raised access floor system by adding another removable floorboard to the existing floor of the building. This raised access floor system is formed by mounting pedestals on a concrete slab floor at regular intervals using epoxy adhesive, and the removable floorboard is mounted on the slab floor by support pedestals .

  The various facilities described above, including distribution boards and switchboards, are installed on the removable floorboard. In this case, if the equipment such as a distribution board is heavy, the distribution board uses anchor nails in two of the four holes formed on the removable floorboard. Fixed. A cushion pad is then placed on the upper part of the head. An upper part positioning support is connected to the respective support pedestal via each side and is secured by bolts, thus forming a frame. Next, removable floorboards are connected through each side to accommodate the depression of the cushion pad, thereby completing the raised floor system. Regarding the material of the detachable floor board, a steel floor board (610 mm × 610 mm, thickness 32 mm) is conventionally used. Recently, however, composite polyurethane / particle board floor plates (600 mm × 600 mm, thickness 40 mm) that overcome the defects of steel floor plates are commonly used.

In such a conventional raised floor system, the pedestal has a height of about 20-40 cm and the allowable bearing load of the removable floorboard is basically 1.5 ton / m ² . When reinforced by the supporting pedestal, the allowable supporting load is 3.5 tons / m ² .

  Since the weight of the switchboard is generally in the range of 100-800 kg, the raised access floor system can fully support the switchboard.

  However, because each corner of the raised access floor system basic structure described above has a rigid frame structure rather than a complete fixed end, this system has the negative effects of lateral forces and vibrations. Very easy to receive. As a result, a switchboard overturn failure is unavoidable in the event of an earthquake.

  At the same time, if various facilities or equipment are installed inside a building or structure that uses a seismic system before the raised floor system is installed, it is placed in a predetermined position and anchored. A stringer having a size corresponding to a removable floor board of equipment or equipment such as a switchboard fixed to a floor slab is prepared. The raised access floor system is then constructed by attaching a removable floorboard above the rest space and a control cable is attached and connected. Finally, the assembly of the raised access floor system is completed by connecting the removable floorboards. Therefore, the construction process of the conventional raised access floor system is very complicated. Furthermore, many costs are required for the production of stringers.

  Furthermore, in the conventional raised access floor system described above for installation of distribution boards or distribution boards, the seismic retrofit structure is only applicable to newly constructed facilities or buildings. That is, it is almost impossible to apply the seismic reinforcement structure to the existing equipment because power interruption or movement of the existing equipment is required during operation of the equipment.

  Therefore, the present invention is configured in view of the above-mentioned problems, and the object of the present invention is on an access floor system that is raised by vibration when an earthquake occurs or when an external impact is applied. It is possible to reinforce the seismic capacity in order to prevent overturning failure or damage of installed equipment and ensure stable seismic capacity, while at the same time moving existing equipment or shutting off power supply And providing a seismic reinforcement structure for switchboards mounted on raised access floors without moving or power interruption, which can be installed even on existing equipment in operation, without the need for operational interruption .

  In the present invention, the above-described object and other objects are provided such that the removable floor board is attached to the floor slab at a distance via the fixing member of the supporting pedestal, and is fixed to the removable floor board. A seismic reinforcement structure that can be attached to the switchboard without moving or shutting off the power distribution board to ensure stable seismic capacity by being configured in such a way that the switchboard is fixed on the mounting bracket. And, in this seismic reinforcement structure, the detachable floor plate and the mounting bracket are clamped and fixed to each other by an L-shaped bracket, a horizontal bolt and a vertical bolt. And the square pipe is fixed to a vertical bolt penetrating the L-shaped bracket and the removable floor plate at a distance from the removable floor plate. , And turnbuckle attached to a floor slab anchor bracket is coupled to the shackle of the anchoring bolt which is fastened to the L-shaped steel.

  The foregoing and other objects and features and other advantages of the invention will be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings.

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

  FIG. 1 is a cross-sectional view of a seismic reinforcement structure for a switchboard mounted on a raised access floor that does not require switchboard movement or power interruption according to an embodiment of the present invention. 2 and 3 are partially enlarged views of FIG. 4 is a side sectional view of FIG.

  In the following description, the equipment includes a distribution board, a distribution board, a control board, a monitoring signal board, a communication / control line in a press conference room or a control room, a computer, and the like. In particular, the switchboard is chosen as a typical embodiment and will be described below, but the invention is applicable to all of these facilities.

  The present invention prevents the switchboard 100 from being overturned or damaged by an earthquake or vibration when the switchboard 100 is already installed on the removable floor board 4 of the raised access floor system. Reinforcing structures can be added to the operating switchboard 100 without the need to move the power switchboard 100 or interrupt power to reinforce the seismic capacity of the switchboard 100.

  As shown in FIGS. 1 to 4, the detachable floor plate 4 is attached at a distance from the floor slab 1 by the fixing members 3 of the plurality of vertical support legs 2. Subsequently, the switchboard 100 is installed on a mounting bracket 5 secured to the removable floor plate 4, thereby ensuring a stable seismic capacity, according to this embodiment of the invention. Complete the seismic reinforcement structure. In this seismic reinforcement structure, the detachable floor plate 4 and the mounting bracket 5 are fastened and fixed to each other by an L-shaped bracket 6, a horizontal bolt 7a, and a vertical bolt 7b. A square pipe 8 is connected to a vertical bolt 7 b penetrating the L-shaped bracket 6 and the detachable floor plate 4 at a distance from the detachable floor plate 4. The square pipe 8 is fastened and fixed to the supporting leg 2 by an L-shaped steel material 9 a using a U-shaped bolt 10 and a fixing bolt 11. A shackle 12 of a fixing bolt 11 fastened and fixed to the L-shaped steel material 9a is connected to a turnbuckle 14 attached to an anchor bracket 13 of the floor slab 1.

  In this case, since a spacing spring 15 is inserted between the removable floor plate 4 and the square pipe 8 and is connected to the vertical bolt 7b, the impact exerted on the connecting member. Can be mitigated if the load path is changed.

  In addition to this, the L-shaped steel material 9 connected to the square pipe 8 has a structure for preventing the fall of the switchboard 100 in case the vertical support pedestal 2 is toppled due to an earthquake or vibration. Are arranged alternately in the horizontal direction.

  In the following, the seismic reinforcement structure according to this embodiment of the invention will be described in more detail.

  When the mounting bracket 5 attached to the switchboard 100 is connected to the detachable floor plate 4 by the horizontal bolt 7a and the vertical bolt 7b, the L-shaped bracket 6 is previously drilled so as to form a hole. . A vertical bolt 7b is inserted into the hole of the L-shaped bracket 6 so that the hole of the removable floor plate 4 and the hole of the square pipe 8 are aligned with each other. Next, the nut 16 is fastened and fixed from the lower part of the square pipe 8.

  In the gap between the detachable floor plate 4 and the square pipe 8, the interval holding spring 15 made of metal is connected to the vertical bolt 7 b, the detachable floor plate 4 and the square pipe 8 all together. Has been inserted so that. Therefore, the impact caused by the change of the load path can be reduced.

  The L-shaped steel material 9 connected to the vertical support pedestal 2 is fixed through a U-shaped bolt 10. Further, the L-shaped steel material 9 fixed to the pedestal 2 is fastened and fixed to the end of the square pipe 8 forming the fall prevention structure by the fixing bolt 11. An eye connection part of the turnbuckle 14 is connected by being inserted into a hole of the shackle 12 attached to the lower end of the fixing bolt 11.

  Another ring-shaped connecting part arranged on the other side of the turnbuckle 14 is connected to an anchor bracket 13 fixed to the floor slab 1 by anchor bolts 17 in order to apply a strong tension to the turnbuckle 14. Has been.

  Next, an earthquake-proof reinforcement structure according to another embodiment of the present invention will be described with reference to FIG. During the drilling operation of forming a hole for tightening and fixing a bolt to the removable floor plate 4 and the mounting bracket 5 on which the switchboard 100 in operation is fixed, vibrations generated from the drilling operation are: This may cause malfunction of the relay of the switchboard 100. In this case, welding the L-shaped bracket 6 to the mounting bracket 5 or mounting the hinge connecting plate 19 will be performed to prevent the malfunction. More specifically, in this embodiment, the mounting bracket 5 and the hinge connecting plate 19 are bonded to each other using a strong industrial adhesive 20 and the rotating link ( The rotary link) 21 is connected to a vertical bolt 7 b that passes through the detachable panel 21 and the square pipe 8. In this case, another spacing spring 15a is inserted between the head of the vertical bolt 7b and the removable floor plate 4.

  By using an industrial adhesive with excellent adhesion for the adhesive 20, the bolt connection so that the hinge connection plate 19 and the mounting bracket 5 withstand the forces exerted in the lateral and vertical directions; It can be bonded with a similar strong force. The rotating link 21 of the hinge connecting plate 19 can turn by a predetermined angle when receiving an earthquake or vibration, thereby transmitting a load.

  Since the other structures of this embodiment are the same as the other structures of the above-described embodiment described in conjunction with FIGS. 1-4, a detailed description of this other structure will be omitted. FIG. 6 shows a seismic reinforcement structure according to still another embodiment of the present invention, and this seismic reinforcement structure is applied to a movable switchboard 100 a that is moved by a wheel 101. In the seismic reinforcement structure according to this embodiment, the stopper supporter 102 of the movable switchboard 100a and the detachable floor plate 4 are interconnected by the bending bracket 22 and the vertical bolt 7b. Other structures and features are the same as those described in the above embodiment.

  7 and 8 show the configuration of the turnbuckle shape utilizing the embodiment of the present invention. More specifically, in addition to this, another turnbuckle 14a is attached at right angles to the turnbuckle 14 shown in FIG.

  In accordance with an embodiment of the present invention, a seismic reinforcement structure for a switchboard mounted on a raised access floor without movement or power interruption is attached to an existing operating switchboard by adjusting the distance using a turnbuckle. It is possible to be Therefore, this seismic strengthening structure can reinforce the seismic capacity without having to stop the operation of the switchboard, that is, without moving the switchboard or shutting off the power.

  While preferred embodiments of the invention have been disclosed for purposes of illustration, those skilled in the art will recognize that various modifications and changes can be made without departing from the scope and spirit of the invention as disclosed in the appended claims. You will understand that additions and substitutions are possible.

FIG. 1 is a cross-sectional view of a seismic reinforcement structure for a power distribution board mounted on a raised access floor without requiring the power distribution board to be moved or interrupted according to an embodiment of the present invention. FIG. 2 is a partially enlarged cross-sectional view of FIG. FIG. 3 is another partial enlarged cross-sectional view of FIG. 4 is a side sectional view of FIG. FIG. 5 is a cross-sectional view of a seismic reinforcement structure according to another embodiment of the present invention. FIG. 6 is a cross-sectional view of a seismic reinforcement structure according to still another embodiment of the present invention. FIG. 7 is a partially enlarged view of FIG. 1 showing the structure of the seismic reinforcement structure according to still another embodiment of the present invention. FIG. 8 is a plan view showing a configuration of a turnbuckle using the seismic reinforcement structure shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Floor slab 2 Vertical support pedestal 3 Fixed member 4 Detachable floor board 5 Mounting bracket 6 L-shaped bracket 7a Horizontal bolt 7b Vertical bolt 8 Square pipe 10 U-shaped bolt 11 Fixed bolt 12 Shackle 100 Distribution board

Claims (6)

A seismic reinforcement structure for a switchboard mounted on a raised access floor without moving the switchboard or shutting off the power,
A form in which a detachable floor board is attached at a distance from a floor slab via a fixing member of a support pedestal, and the switchboard is fixed on a mounting bracket fixed to the detachable floor board. In the seismic reinforcement structure that ensures stable seismic capacity by being configured in
The detachable floor plate and the mounting bracket are fastened and fixed to each other by an L-shaped bracket, a horizontal bolt and a vertical bolt,
A square pipe is fixed to a vertical bolt penetrating the L-shaped bracket and the removable floor plate at a distance from the removable floor plate; and
A seismic reinforcement structure in which a turnbuckle attached to an anchor bracket of the floor slab is connected to a shackle of a fixing bolt that is fastened and fixed to an L-shaped steel material.   A spacing spring is inserted between the removable floor plate and the square pipe so that the impact on the connecting member when the load path is changed can be reduced; and The seismic reinforcement structure according to claim 1, wherein the seismic reinforcement structure is fastened and fixed to the vertical bolt.   The seismic reinforcement structure according to claim 1, wherein the square pipe and the L-shaped steel material are alternately arranged in a horizontal direction, thereby realizing a fall prevention structure.   The seismic reinforcement according to claim 1, wherein the vertical bolts that penetrate the detachable floor plate and the pipes are connected to a rotating link of a hinge connecting plate attached to the mounting bracket by welding or an adhesive. Construction.   The seismic reinforcement structure according to claim 4, wherein the spacing spring is inserted between a head of the vertical bolt and the detachable floor plate.   The seismic reinforcement structure according to claim 1, wherein the vertical bolt of the detachable floor plate is attached by a bent bracket connected to a stopper support of a movable switchboard.

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