JP2003221924A - Fall preventive device of electronic appliance - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a lightweight fall preventive device for an electronic appliance, used when it is put on a double-structural floor, capable of coping with the change of the height of the double-structural floor. <P>SOLUTION: A set of electronic appliance is provided with a plurality of fixing members 30. Each fixing member is formed of a support 31 fixed to a floor face 10 and a bolt member 33 connected to a panel 20 to be able to adjust the height between the support 31 fixed to a floor face 10 and the fixing tool in accordance to the change of the distance of the double-structural floor and penetrated upward through the panel 20 and the electronic appliance is fixed by the bolt member. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fall prevention device for electronic equipment, and more specifically, a large computer, various other electronic equipment, electronic equipment, etc. are fixedly installed on a floor having a double floor structure. The present invention relates to a fall prevention device for an electronic device.

[0002]

2. Description of the Related Art Conventionally, a computer room in which a large computer device and other electronic devices are installed has a double floor structure, and a space between a floor surface of a building and a panel board,
That is, many signal cables and power cables are wired in the underfloor space in an overlapping manner. An electronic device is installed on the floor of the double floor structure, and a signal cable and a power cable are connected to the electronic device.

In this type of electronic equipment, measures are taken to prevent the electronic equipment from tipping over in order to prevent the electronic equipment from tipping over due to shaking when an earthquake or the like occurs.

FIG. 1 is a perspective view showing an example of a conventional fall prevention device for electronic equipment. In this conventional example, an electronic device 1 to be installed is provided with a dedicated mount 2. This pedestal 2 has a planar outer shape corresponding to the bottom surface of the electronic device 1, and
It has a height corresponding to the height of the double floor. And this mount 2 is installed as follows.

(1) The pedestal 2 is fastened and fixed to the floor surface 10 of the building with anchor bolts 3 and nuts 4.

(2) The bottom of the electronic device 1 and the gantry 2 are fastened and fixed to each other by bolts 5 and nuts 6.

(3) The mount 2 has a height corresponding to the height of the double floor (the height from the floor of the building to the upper surface of the panel plate of the free access floor 20) as described above, and A device having a planar outer shape corresponding to the planar size of the bottom of the electronic device is used.

(4) When the floor 20, particularly the floor 20 for free access, is used, the top surface of the gantry 2 is removed, and the free access floor 20 is displaced or dropped at the end portion adjacent to the gantry 2. Auxiliary support (not shown)
Or, reinforce with a frame (not shown). The free access floor 20 is formed of a rectangular panel plate, and the four corners of each rectangular panel plate are supported by the columns 21 to form an underfloor space having a necessary gap with the floor surface 10 of the building.

Such a conventional fall prevention device for an electronic device has the following problems and needs to be improved. That is, (1) the pedestal 2 has a size corresponding to the size of one electronic device 1 and a height corresponding to the height of the double floor, and a dedicated one corresponding to each electronic device 1 is prepared. It is necessary to prepare many types of gantry in advance.

(2) The pedestal is heavy and not easy to carry and handle.

(3) Floor (free access double floor structure)
As for the above, it is necessary to remove the part of the pedestal on which the electronic equipment is mounted, and to make that part an opening corresponding to the gantry, but with the processing of the panel board of the free access floor,
A structure that supports the end surface of the opening is required.

(4) Although depending on the shape of the mount, in the case of the frame-shaped mount as shown in FIG. 1, it is difficult to process the wiring of the signal cable, the power cable, etc. when the electronic equipment is relocated or laid out.

The price of the mount and the construction cost are high.

[0014]

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems in the above-described conventional fall prevention device for electronic equipment, and it is possible to reduce the size of the electronic equipment and the height of the double floor. An object of the present invention is to provide a fall prevention device for an electronic device that can flexibly respond to changes, achieve weight reduction, easily support an end surface of a floor (in the case of a free access floor), and easily handle a cable. And

[0015]

In order to achieve the above object, according to the present invention, a space having a predetermined height is formed between a lower first floor surface and the first floor surface. In the fall prevention device for an electronic device used when installing the electronic device on the floor of the double floor structure consisting of the upper second floor that is fixed as Each fixture comprises a first fixing part fixed to the first floor surface,
A second fixing portion coupled to a panel forming the second floor surface so that a height position between the first fixing portion and the second fixing portion can be adjusted according to a change in the space of the double floor; Provided is an overturning prevention device for an electronic device, which is a part that penetrates upward and includes a third fixing part that fixes the electronic device. A plurality of fixtures is installed and fastened to one electronic device at a plurality of locations (for example, four corner positions of the device) corresponding to the positions where the lower part of the electronic device is fixed.

The first fixing portion fixed to the first floor surface of each of the fixtures is fixed to the floor portion forming the first floor surface so as to project upward in the vertical direction of the first floor surface. It is characterized by comprising at least two anchor bolts and a flange portion of a column fixed to the floor surface by the at least two anchor bolts. Anchor bolts are fixedly installed in advance at a position on the first floor surface corresponding to a plurality of fixing positions for a specific electronic device during foundation work on the floor surface.

The flange portion of the pillar has at least two fixing holes on the diagonal of the plane through which the anchor bolt penetrates, and the pillar is fixed by fastening a nut to each anchor bolt. Characterize.

The column is integrally formed with the flange portion and the flange portion, extends vertically upward from a center position on the plane of the flange portion, and has a tap hole formed inside the upper portion. A bottom surface of a panel plate, which includes a shaft portion and is fastened and fixed to a shaft portion of the column so that the height of the bolt member is fitted in the tap hole, and the bolt member forms the second floor surface. Is fixed and the electronic device is fastened and fixed to the upper surface of the bolt member which penetrates the panel plate.

As another aspect, the column comprises the flange portion and a shaft portion formed integrally with the flange portion and extending vertically upward from a center position on a plane of the flange portion. A screw portion is formed on the outer side of the upper portion of the shaft portion, and a contact plate that abuts the lower surface of the panel plate forming the second floor surface is fastened and fixed to the screw portion, and the screw portion is It is characterized in that the electronic device is fastened and fixed at a portion that penetrates the panel plate in the vertical direction.

In still another aspect, the support column includes the flange portion and a screw portion formed integrally with the flange portion and extending vertically upward from a center position on a plane of the flange portion. , A fastening plate that abuts the lower surface of the panel plate is fastened and fixed to the threaded portion, and an electronic device is fastened and fixed at a portion of the threaded portion that penetrates the panel board forming the second floor surface in the vertical direction. It is characterized by

The plurality of fixtures are provided at the bottom of the electronic device,
The electronic device is arranged in at least four corners.

The fixing of the flange portion of the column to the anchor bolt, the fixing of the contact plate to the bolt member or the bolt portion, and the fixing of the electronic device to the bolt or the bolt portion are performed on the bolt member or the bolt portion. It is characterized in that it is performed by using a nut to be fitted and, if necessary, a flat washer or a spring washer.

A plurality of floor fixing plates are attached to the electronic device, and these floor fixing plates are fixed to the upper surface of the panel plate via a buffer layer. As a result, the cushioning effect of the electronic device can be obtained even in the event of an earthquake or the like.

The buffer layer is a rubber plate.

An insulating bush is arranged around the bolt member or the bolt portion, and the floor fixing plate is fixed to the bolt member or the bolt portion via the insulating bush.

[0026]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

FIG. 2 is an exploded perspective view of a fall prevention device for an electronic device according to the present invention. 3 (a) is a perspective view showing an embodiment in which the fixing tool of the fall prevention device of the present invention is attached to the foot (floor fixing plate) of the electronic device, and FIG. 3 (b) is B of FIG. 3 (a). It is a partial side view of the part shown.

In these figures, the floor surface 10 of the building,
A double floor structure is formed by the free access floor (panel plate) 20 that is fixed so as to form a predetermined height gap with the floor surface. As is well known, the free access floor 20 is composed of a plurality of panel boards, each panel board having four corners supported by pillars 21 and laid in a plane, and a double floor between the floor surface 10 and the building. Forming a structure. This point is similar to the conventional example.

In the present invention, the floor surface 10 of the building and the electronic device 1
A plurality of the same fixtures 30 are used for one electronic device to fasten between and. The lower end of each fixture 30 is fastened and fixed to the floor surface 10 of the building, and the upper end thereof penetrates the panel plate 20 of the double floor upward, and is fixed to this panel plate 20 and penetrates above the panel plate 20. It is fastened to the bottom of the electronic device 1 at the portion.

A plurality of such fixtures 30 are, for example,
It is arranged at four corners of the lower region of the electronic device 1.

Each fixture 30 has a pillar 31 fixed to the floor 10 of the building by anchor bolts 3, and the pillar 31.
A bolt member 33 fixed to the, a nut 32, and a cover plate 34. The embodiment of the fixture 30 shown in FIG.
Since this corresponds to the embodiment shown in FIGS. 7 and 10, it will be described in detail later.

On the electronic device 1 side, a floor fixing plate 7 as a metal fitting is fixed along the lower edge thereof. A rubber plate 8 as an insulating member is interposed between the floor fixing plate 7 and the panel for free access.

Next, as three types of embodiments of the fixture of the present invention, three types of fixtures 30, 40, 50 according to the height from the floor surface 10 of the building to the panel floor surface 20 of the double floor. To prepare. The structure of each fixture and the method of using the fixture are as described below.

4, 7, and 10 show a first embodiment of the present invention. In this embodiment, the floor surface 10 of the building is
When the height from the upper surface of the double-floor panel 20 is relatively large, for example, from the floor surface 10 of the building to the double-floor panel 2
It is suitable to use when the height from 0 to the upper surface is, for example, 180 to 540 mm. The panel 20
Has a thickness t of 40 mm.

As described above, the fixture 30 according to the first embodiment has a pillar 31 fixed to the floor surface 10 of the building by the anchor bolt 3, a bolt member 33 fixed to the pillar 31, and a nut 32. And a backing plate 34.

The support column 31 is a flat board or a flange portion 31a which is fixedly contacted with the floor surface 10 of the building, and a shaft which is integrally fixed by welding so as to project upward at the center position on the plane of the flange portion. The part 31b. Flange part 3
1a is, for example, a substantially rectangular shape as shown in FIG. 10, has two holes 31c at diagonally symmetrical positions on a plane, and the anchor bolts 3 fix the columns 31 to the floor surface 10 of the building. Used for. Inside the shaft portion 31b is the tap hole 3
1d (for example, M20).

The flange 31a of the column 31 is
With a hexagon nut 3a (for example, M10) and accompanying flat washers 3b (M10) and spring washers 3c (M10)
Thus, it is fixed to the anchor bolt 3 which is fixed at a predetermined position on the floor surface 10 of the building. Anchor bolt 3
Depending on the outer shape of the specific electronic device 1, for example, the electronic device 1
Are embedded and fixed in advance on the floor surface 10 of the building by known methods at the four corner positions.

The bolt member 33 has a pillar 31 at the bottom thereof.
Screw part 33a fitted in the tap hole 31d of the shaft part 31b
(M20), a screw part 33b (M16) for fixing the side of the electronic device 1 to the upper part, and a flange part 33c that abuts the lower surface of the double-floor panel 20 via the contact plate 24 in the middle. Are integrally formed. The bolt member 33 is fixed to the support column 31 by fitting the threaded portion 33a of the bolt member 33 into the tap hole 31d of the support column 31 and fastening it with a nut (double nut as shown in the drawing if necessary) 32. Fixed. In this case,
The dimension from the lower surface of the flange 31a of the support column 31 to the upper surface of the contact plate 34 that contacts the flange 33c of the bolt member 33 defines a predetermined interval corresponding to the height of the double floor.

The double-floor panel 20 has a hole for allowing the upper screw portion 33b of the bolt member 33 to pass therethrough, and the electronic device 1 is sandwiched by the rubber plate 8 on the upper surface of the panel 20.
The floor fixing plate 7 is fastened and fixed. When concluding this,
The insulating bush 9 is used, and the plain washer 35b (M16) and the spring washer 35c (M1 are used by the nut 35a (M16).
6) is used.

In the illustrated embodiment, the floor fixing plate 7 of the electronic device 1 is a member having an L-shaped cross section, and is fixed to the lower outer wall of the electronic device (eg, server rack) 1 in the horizontal direction.
The rubber plate is a belt-shaped and flat plate, and has a size corresponding to this floor fixing plate.

The fastening of the bolt member 33 and the electronic device 1 is
The upper screw portion 33b of the bolt member 33 is passed through the hole of the contact plate 34, and further through the hole of the panel 20 of the double floor,
The floor fixing plate 7 is pulled out above the panel 20, and the floor fixing plate 7 is fixedly fastened with the rubber plate 8 sandwiched on the upper surface of the panel 20.

As a result, the support column 31 and the bolt member 32 are provided.
The fixture 30 composed of the above and other parts is the floor surface 10 of the building.
Thus, the double-floor panel 20 and the electronic device 1 are fastened and fixed.

In the first embodiment, since the height can be adjusted while the support 31 and the bolt member 33 are adjusted by screw fitting, the floor 10 of the building and the double-floor panel 20 can be tightened. Even if the height between and changes, the height of the screw shaft portion 33b for fixing the bolt member 33 protruding above the panel 20 can always be made constant.

In the bolt member 33 used in this first embodiment, the diameter (M20) of the lower screw portion 33a is larger than the diameter (M16) of the upper screw portion 33b. As a result, the strength required for the integral connection between the bolt member 33 and the support column 31 is maintained, and at the same time, the holding strength of the electronic device 1 having earthquake resistance is maintained.

FIG. 5, FIG. 8 and FIG. 11 show a second embodiment of the present invention. This second embodiment is preferably used when the height from the floor surface 10 of the building to the upper surface of the double-floor panel 20 is, for example, 100 to 190 mm. The thickness t of the panel 20 is 30 mm.

The fixture 40 according to the second embodiment comprises a pillar 41 fixed to the floor surface 10 of the building by the anchor bolt 3.
And nuts 32 and a contact plate 34.

The support column 41 is composed of a flange portion 41a which is fixedly contacted with the floor surface 10 of the building, and a shaft portion 41b which is fixed to the center position of the flange portion by welding so as to project upward. The shape and structure of the flange portion 41a itself is the same as that of the first embodiment. For example, as shown in FIG.
The two holes 41c on the diagonal line are used to fix the columns 41 to the floor surface 10 of the building by the anchor bolts 3. The lower portion of the shaft portion 41b has a diameter of, for example, 20 mm, and the upper portion is formed with a screw portion 41d (M16) on the outside.

As in the case of the first embodiment, the support column 41 is fixed to the floor surface 10 of the building by the hexagonal nut 3a (M10) and the flat washers 3b (M10) and spring washers 3c (M10) attached thereto. It is fixed to the anchor bolt 3 which is fixed at a predetermined position.

The double-floor panel 20 has a screw portion 4 on the upper portion of the shaft portion.
The panel 2 has a hole for penetrating 1d.
A rubber plate 8 is sandwiched on the upper surface of the floor fixing plate 7 of the electronic device 1.
Are fastened and fixed. At the time of this fastening, the insulating bush 9 is used, and it is fastened by using a plain washer and a spring washer with a nut, but the floor fixing plate 7 and the rubber plate 8 of the electronic device 1 are used.
The etc. and the fixing method thereof are the same as in the case of the first embodiment.

As a result, the floor 40 of the building, the double-floor panel 20, and the electronic device 1 are fastened and fixed by the fixtures 40 including the columns 41 and other parts.

In the second embodiment, the height is adjusted by fixing the position of the contact plate 34 fixed to the screw portion 41d of the support column 41 by the nut 32 (double hexagon nut M16), so that the floor surface 10 of the building can be adjusted. When the height between the double-floor panel 20 and the double-floor panel 20 changes, the height of the screw shaft portion 41c of the pillar 41 protruding above the panel 20 also changes accordingly.

FIGS. 6, 9 and 12 show a third embodiment of the present invention. This third embodiment is suitable for use when the height from the floor surface 10 of the building to the upper surface of the double-floor panel 20 is, for example, 68 to 100 mm. The thickness t of the panel 20 is 30 mm.

The fixture 50 according to the third embodiment is a pillar 51 fixed to the floor surface 10 of the building by the anchor bolt 3.
And nuts 32 and a contact plate 34.

The support column 51 is a flange portion 51a which is fixed in contact with the floor surface 10 of the building, and a screw shaft portion 51 which is fixed to the center position of the flange portion by welding so as to project upward.
It consists of b. The two holes 51c on the diagonal line of the flange portion 51a are used to fix the pillar 51 to the floor surface 10 of the building by the anchor bolt 3. Screw shaft 51
The diameter of b is, for example, 16 mm (M16).

As with the first and second embodiments, the support column 51 is an anchor bolt fixed to a predetermined position on the floor surface 10 of the building by the nut 32 and the accompanying spring washers and flat washers. It is fixed at 3.

The double-floor panel 20 is formed with a hole for penetrating the upper part of the screw shaft portion 51b.
The floor fixing plate 7 of the electronic device 1 is fastened and fixed on the upper surface of the electronic device 1 with the rubber plate 8 interposed therebetween. Insulation bush 9
Is used and is fastened with a nut using a flat washer and a spring washer, but the floor fixing plate and the rubber plate of the electronic device 1 are the same as in the first and second embodiments.

Further, similarly to the second embodiment, the screw shaft portion 51b of the support column 51 is passed through the hole of the contact plate 34, further passed through the hole of the panel 20 of the double floor, and pulled out above the panel 20. The screw shaft portion 51b is directly fastened to the floor fixing plate 7 with the rubber plate 8 interposed therebetween. As a result, the floor surface 10 of the building is fixed by the fixtures 50 including the columns 51 and other parts.
Thus, the double-floor panel 20 and the electronic device 1 are fastened and fixed.

In the third embodiment, as in the case of the second embodiment, the height is adjusted by adjusting the position of the contact plate 34 fixed to the screw shaft portion 51b of the support column 51 to the nut 32 (double hexagon nut). Since it is fixed by M16), when the height between the floor surface 10 of the building and the panel 20 of the double floor changes, the pillars 5 protruding above the panel 20 accordingly.
The height of the first screw shaft portion 51b also changes.

In each of the above-described embodiments, the height of the double floor is changed by adjusting the relative fixing positions of the support column and the bolt member or by changing the position of the bolt portion of the support column. By adjusting with the nut, it becomes possible to cope with it very easily.

Further, with respect to changes in the outer shape of electronic equipment,
This can be dealt with by changing the mounting position of the columns, that is, by changing the mounting position of the anchor bolts that are fixed in advance on the floor of the building.

FIG. 13 is a diagram for explaining the strength of the electronic device overturn prevention device against an earthquake. The fall prevention device of the present invention is required to have a strength capable of withstanding horizontal and vertical seismic forces applied to an electronic device during an earthquake. (1) Pull-out force from the floor of the anchor bolts that fix the columns to the floor of the building, shearing force of the anchor bolts (2) Bending stress and tensile stress of the columns are strong enough to withstand the seismic force. no problem.

When performing seismic design of electronic equipment, in general,
Strength design based on seismic design standards. There are the following seismic design standards. Seismic Design Standards "Comprehensive Seismic Planning Standards for Government Facilities and Commentary" According to this, horizontal and vertical design seismic forces are calculated using standard seismic intensity for design.

The design standard seismic intensity is calculated by the floor response acceleration when the floor response acceleration is indicated by the seismic response analysis or the like, and is calculated by the local seismic intensity method in principle when the floor response acceleration is not indicated.

The design seismic force is obtained by multiplying the design horizontal seismic intensity or the design vertical seismic intensity by the weight of the equipment. When these forces act on the center of gravity of the equipment at the same time, the equipment does not move or fall. Fix it to prevent it from happening.

[0065]   Design horizontal seismic force (FH)         FH = KH × W FH: Horizontal seismic force for design (N)                               KH: Horizontal seismic intensity for design         KH = Z × KS KS: Standard horizontal seismic intensity for design                               Z: Regional coefficient (in principle, 1.0)                               W: Equipment weight   Vertical seismic force (FV) for design         FV = KV × W FV: Vertical seismic force for design (N)         KV = 1/2 × KH KV: Vertical seismic intensity for design

[0066]

[Table 1]

In FIG. 13, each parameter is defined as follows.

G: Center of gravity of the equipment L1: Center of gravity distance from the short side direction of the equipment L2: Height of the center of gravity of the equipment from the floor l: Bolt span viewed from the direction to be examined ht: Number of bolts to be pulled N: Equipment Total number of columns fixed to the floor According to this, the pulling force and shearing force of the anchor bolt are as follows.

Pull-out force of anchor bolt R ₆ = {FH
× L ₂ − (W−F _v ) × L ₁ } / lnt Shearing force of anchor bolt Q = FH / N Therefore, the pulling out force and shearing force of the anchor bolt thus calculated satisfy the above design criteria. It will be good.

Although some embodiments of the present invention have been described with reference to the accompanying drawings, the present invention is not limited to the above embodiments, and various embodiments within the spirit and scope of the present invention. , Deformation, modification, etc. are possible.

For example, in the above first and second embodiments, the double floor structure is a free access (FA) floor, and each rectangular panel 20 has a layout of signal cables and power cables in the double floor space. Although it has been described that it can be appropriately removed due to changes or the like, the present invention is not limited to such a free access floor.
The present invention can be applied to a double-floor called a floor having a low space (third embodiment) and any other double-floor.

Free access (FA) shown in FIG.
On the floor, a portion indicated by reference numeral 22 of the panel 20 is a dent portion for reducing the weight of the panel 20 made of, for example, an aluminum material, and when the contact plate 34 is located at this portion, the adjustment plate 24 or the like is appropriately used. It is used to adjust the thickness of the panel 20. (Supplementary Note 1) The plurality of fixtures are provided at the bottom of the electronic device.
The electronic device is arranged at positions corresponding to at least four corners of the electronic device. (Supplementary Note 2) The fixing of the flange of the pillar to the anchor bolt, the fixing of the contact plate to the bolt member or the screw portion, and the fixing of the floor fixing plate of the electronic device to the bolt member or the screw portion are performed as described above. It is characterized in that it is carried out by using a nut fitted to a bolt member or a screw part and, if necessary, a plain washer or a spring washer. (Supplementary Note 3) The electronic device is fixed by fixing a fixing plate that is integral with the electronic device to the bolt or the bolt portion. (Supplementary Note 4) The fixing plate is fixed to the upper surface of the panel plate through a buffer layer. (Supplementary Note 5) The buffer layer is a rubber plate. (Supplementary Note 6) An insulating bush is arranged around the bolt member or the screw portion, and the floor fixing plate of the electronic device is fixed to the bolt member or the screw portion via the insulating bush. (Supplementary Note 7) The column includes the flange portion and a screw portion that is integrally formed with the flange portion and that extends vertically upward from a center position on a plane of the flange portion. It is characterized in that the contact plate that abuts the lower surface of the panel plate that forms the second floor surface is fastened and fixed, and that the electronic device is fastened and fixed at the portion of the screw portion that penetrates the panel plate in the vertical direction. .

[0073]

As described above, according to the fall prevention device for an electronic device of the present invention, it is possible to easily cope with changes in the size of the electronic device and the height of the double floor, and at the same time, achieve weight reduction and install the device. In this case, the floor (free access floor) can be processed only by drilling, the end face portion can be easily supported, and the signal cable and the power cable can be easily treated. As a result, it is possible to obtain a fall prevention device for electronic devices, which is easy and inexpensive to manufacture and construct parts, and has excellent earthquake resistance.

[Brief description of drawings]

FIG. 1 is an exploded perspective view of a conventional fall prevention device for an electronic device.

FIG. 2 is an exploded perspective view of a fall prevention device for an electronic device of the present invention.

3A is a perspective view showing an embodiment in which a fall prevention unit is attached to a foot of an electronic device, and FIG. 3B is a partial side view of FIG. 3A.

FIG. 4 is a diagram showing a first embodiment of a fall prevention device for an electronic device according to the present invention, of a portion where a metal fitting (floor fixing plate) is attached to the electronic device and fixed with a fixture.

FIG. 5 is a diagram showing a second embodiment of a fall prevention device for an electronic device according to the present invention.

FIG. 6 is a diagram showing a third embodiment of a fall prevention device for an electronic device according to the present invention.

FIG. 7 is a perspective view and an assembly view showing a state in which the fall prevention device according to the first embodiment of the present invention is disassembled on the free access floor.

FIG. 8 is a perspective view and an assembly view showing a state in which the fall prevention device according to the second embodiment of the present invention is disassembled on the free access floor.

FIG. 9 is a perspective view and an assembly view showing a state where the fall prevention device according to the third embodiment of the present invention is disassembled on the OA floor.

FIG. 10 is an exploded perspective view showing a pillar and a bolt member when the height adjustment range for the free access floor is the largest.

FIG. 11 is an exploded perspective view showing a column having a relatively large height adjustment range for a free access floor.

FIG. 12 is an exploded perspective view showing a column having a relatively large height adjustment range for an OA floor.

FIG. 13 is a diagram for explaining the strength of an electronic device overturn prevention device according to the present invention against an earthquake.

[Explanation of symbols]

1 ... Electronic device 3 ... Anchor bolt 6 ... Nut 7. Metal fittings (floor fixing plate) 8 ... Insulator (rubber plate) 9 ... Insulation bush 10 ... Floor 20 ... Free access floor 21 ... Support for panel board 30 ... Fixing tool 31, 41, 51 ... Posts 32 ... Nut 33 ... Bolt member 34 ... Plate 40, 50 ... Fixing device

Continued front page    (72) Inventor Hiroaki Mori             6-22-7 Minamioi, Shinagawa-ku, Tokyo Fuji             Tsu Network Solutions Co., Ltd.             Within (72) Inventor Toshiro Kubo             6-22-7 Minamioi, Shinagawa-ku, Tokyo Fuji             Tsu Network Solutions Co., Ltd.             Within

Claims (5)

[Claims] 1. A double floor consisting of a lower first floor surface and an upper second floor surface fixed so that a predetermined height interval is formed between the first floor surface and the first floor surface. In a fall prevention device for an electronic device used when installing an electronic device on a floor of a structure, a plurality of fixing devices are provided for one electronic device, and each fixing device is
The second floor surface is formed so that the height position between the first fixed portion fixed to the first floor surface and the first fixed portion can be adjusted according to the change in the distance between the double floors. An overturning prevention device for an electronic device, comprising: a second fixing part engaged with a plate member; and a third fixing part that penetrates the plate member upward and fixes an electronic device. 2. A first fixing portion fixed to the first floor surface of each of the fixtures is fixed to a floor portion forming the first floor surface so as to project upward in the vertical direction of the first floor surface. 2. The device according to claim 1, comprising at least two anchor bolts and a flange portion of a column fixed to the first floor by the at least two anchor bolts. 3. The flange portion of the column has at least two fixing holes on the diagonal of the plane through which the anchor bolt passes, and the column is fixed by fastening a nut to each anchor bolt. The device according to claim 2, wherein: 4. The pillar is integrally formed with the flange portion and the flange portion, extends vertically upward from a center position on the plane of the flange portion, and has a tap hole formed inside the upper portion. And a bolt member fitted into the tap hole, the height of the bolt member is fastened and fixed to the shaft portion of the column, and the bolt member forms the second floor surface. 4. The device according to claim 3, wherein a contact plate that abuts a lower surface of the bolt is fastened and fixed, and an electronic device is fastened and fixed to an upper surface of the bolt member that penetrates the panel plate. 5. The pillar comprises the flange portion and a shaft portion formed integrally with the flange portion and extending vertically upward from a center position on a plane of the flange portion,
A threaded portion is formed on the outer side of the upper portion of the shaft portion, and a contact plate that abuts the lower surface of the panel plate forming the second floor surface is fastened and fixed to the threaded portion, and the panel of the threaded portion is also fixed. The device according to claim 3, wherein the electronic device is fastened and fixed at a portion that penetrates the plate in the vertical direction.