KR101497144B1 - Aseismic constructing method and aseismic device of computation equipment on the access floor - Google Patents

Abstract

The present invention relates to a seismic retrofit device for computation equipment installed on an access floor that can absorb vibration and impact on occurrence of earthquake not to the computation equipment from being fallen, and can reinforce a resistance to earthquake without temporarily moving the computation equipment installed previously or turning off the power, and a construction method thereof. The seismic retrofit device includes: an earthquake-proof frame (10) having a lower frame (10b) fixed to a floor of a building and an upper frame (10a) engaged tot eh lower frame (10b) in a floating manner; a plurality of vibration-proof pads (20) provided in the earthquake-proof frame (10) to absorb the vibration transferred between the lower and upper frames (10b, 10a); a plurality of base members (30) installed on the earthquake-proof frame (10) and having a height adjusting member (35); and a support frame (40) installed on an upper end of the base member (30) to support a lower portion of a connecting frame (700) formed on an access floor and fastened to a lower portion of the computation equipment (S).

Description

TECHNICAL FIELD [0001] The present invention relates to an earthquake-proof reinforcement apparatus for an earthquake-

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and method for installing an earthquake-proofing apparatus in an access floor, and more particularly, The present invention relates to an earthquake-proofing apparatus for an earthquake-proof earthquake and an earthquake-proofing performance of an earthquake-proof earthquake.

In recent years, due to the rapid development and popularization of telecommunication technology, a computer room is often operated not only in specialized communication facilities but also in general commercial buildings, office buildings, apartments, and buildings. In such a computer room, An access floor is installed to secure an office space or an activity space in addition to the manager. Hereinafter, a configuration of a general access floor will be described with reference to FIGS. 1 and 2. FIG.

The conventional access floor includes an upper plate 100 on which a computer is installed and a support member 500 installed on the bottom surface of the building to support the upper plate 100. The access floor includes a space between the bottom surface of the building and the upper plate 100 Make sure that the cable of the computer (S) is located.

At this time, the upper plate 100 is formed to have a sufficient strength so that a plurality of people can be lifted up, and a plurality of upper plates 100 are combined to form a bottom of the computer room. .

The support member 500 is integrally formed with a lower pedestal 510 which is in close contact with the bottom surface of the building and a pipe type support 520 on the upper side of the lower pedestal 510, And a height adjuster 550 for adjusting the height.

An upper support 600 for supporting one side edge of the upper plate 100 is formed at the upper end of the support 520 including the height adjuster 550 and an upper support 600 And a plurality of connection frames 700 for supporting the side edges of the upper plate 100. [

On the other hand, as shown in FIG. 2, the computerized equipment S installed in the access floor having the above-described configuration is placed on the upper plate 100, and the lower end of the computerized equipment S is additionally attached to the upper plate 100, .

However, in the case of the computer system S installed in the conventional access floor as described above, there is a problem that the computer system S is easily turned on when an earthquake occurs. Specifically, vibration or shock due to an earthquake, The load of the computer equipment S is alternately concentrated in the direction in which the loads of the computer equipment S are tilted on both sides and the center of gravity is moved irregularly so that the access floor that is organically combined with each other is balanced as a whole And the supporting member 500 of the access floor for supporting the load of the computer equipment S collapses from the fragile portion in a chain so that the upper plate 100 of the access floor collapses, (S) is conducted.

That is, even if the vibration transmitted directly to the computer S from the occurrence of the earthquake does not reach the level enough to conduct the computer S, the collapse of the access floor is promoted due to the shaking of the computer S, And thus the computer S installed on the access floor has a problem of being easily conducted when an earthquake occurs.

Furthermore, even if the primary damage caused by the earthquake is slight, the second secondary damage may occur due to the interruption of power and communication due to the conduction of the computer (S) In recent years, the incidence of domestic earthquakes has continuously increased, and earthquakes with a magnitude of 5 or more have also occurred periodically. On the other hand, related laws such as the Natural Disaster Countermeasures Law and the Earthquake Disaster Countermeasures Law have been strengthened. It is urgent to develop and disseminate earthquake resistant and vibration isolation reinforcement devices for the computer equipment S installed in the access floor.

However, in the case of a conventional earthquake-proof apparatus, it is impossible to apply the earthquake-proof apparatus to the existing computer equipment S of the access floor, or to install the computer equipment S ) Is temporarily installed at another place or is to be constructed while the operation is interrupted, so that the work is cumbersome and inconvenient and can not be widely spread.

Registration No. 10-0919686 (issued October 10, 2009)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a computerized system that prevents computer equipment installed on an access floor of a computer room from being conducted due to natural disasters such as earthquakes, The earthquake resistance and vibration isolation performance of the earthquake-proof system and the earthquake-proof earthquake-proof earthquake can be reinforced without temporarily stopping the operation of the computer equipment. The present invention has been made to solve the above problems.

According to an aspect of the present invention, there is provided an earthquake-proof reinforcement apparatus for computer equipment installed on an access floor, comprising: a lower frame fixed to a floor of a building; and an upper frame, A plurality of vibration damping pads formed in the inner frame to absorb vibrations transmitted between the lower frame and the upper frame, a plurality of support members provided on the upper side of the vibration damping frame and having height adjusting means, An earthquake-proof reinforcement of computer equipment installed in an access floor, which includes a support frame installed on a sphere and supporting a lower side of a connection frame formed on an access floor, and a support frame fastened to a lower portion of a computer equipment.

According to another aspect of the present invention, there is provided a vibration damping pad comprising: an upper plate and a lower plate each having a space portion; a pair of bearings formed on the space portions of the upper and lower plates, A shaft divided at both ends of the pair of bearings so as to interpose a connection spring at an intermediate portion thereof, an elastic tube inserted between the both sides of the shaft and inserted into the elastic tube, And a plurality of tension springs interconnecting the upper and lower play portions.

Further, according to the present invention, a plurality of bases are fixedly installed on a floor of a building below an access floor, and an earthquake-resistant frame having a plurality of vibration-proof pads therein to absorb vibration is installed on the base, A support frame is provided on the support hole so that the support frame is brought into close contact with the lower portion of the connection frame of the access floor using the height adjusting means of the support hole, The bracket is attached to the lower part of the computer equipment or the installed computer equipment, and the bracket and the support frame are firmly fixed with the fastening bolt, so that the newly installed computer equipment as well as the already installed computer equipment can be installed Installed in an 'access floor' to reinforce the earthquake and vibration isolation performance There are different features in the method of construction of seismic strengthening device of computer equipment.

According to the present invention having the above-described structure, the vibration and shock generated when an earthquake occurs are absorbed and buffered by the vibration-proof pads of the earthquake-proof frame. As a result, conduction of the computer equipment can be prevented as a result, Even when the access floor collapses, the present invention is applied to the computer equipment installed in the computer room as well as the computer equipment is not transferred regardless of the collapse of the access floor because the computer equipment is supported by the bottom surface of the building by the seismic- Since there is no need to install or shut down the computer equipment in its operation, the operation is simple and inexpensive, which ultimately has the effect of facilitating the improvement of the weak earthquake resistance and visibility of the existing computer room.

1 is a perspective view showing a general access floor;
2 is a state diagram showing a computer equipment installed in a conventional access floor
3 is an explanatory drawing showing the state of use of the seismic retrofitting apparatus according to the present invention
4 is a perspective view showing an anti-seismic reinforcement apparatus according to the present invention.
5 is an exploded perspective view of the seismic retrofitting apparatus according to the present invention.
6 is an exploded perspective view showing an anti-vibration pad of an anti-seismic device according to the present invention.
7 is an operational state diagram showing the seismic strengthening apparatus according to the present invention.

3 and 8, the same parts as those of FIG. 1 and FIG. 2 are referred to as duplication of the description. FIG. 3 is a perspective view of a seismic retrofitting apparatus for a computer system installed in an access floor according to a preferred embodiment of the present invention. They are denoted by the same reference numerals.

First, the structure of the seismic strengthening apparatus 1 according to the present invention is applied to the seismic frame 10, the dustproof pad 20, the support 30, the support frame 40, the bracket 50 and the fastening bolts 60 The earthquake-proof frame 10 comprises a lower frame 10b fixed to the floor of the building and an upper frame 10a connected to the lower frame 10b in fluid communication with the lower frame 10b. Preferably, The upper frame 10a and the upper frame 10b are formed to have different sizes from each other so that the lower frame 10b and the upper frame 10a are different from each other in size. 10a are fluidly coupled.

A plurality of fastening holes 15a and 15b are formed in the upper and lower frames 10a and 10b of the seismic frame 10 so as to form the plurality of vibration pads 20 provided inside the seismic frame 10, It is possible to freely set the position of the upper frame 10a as well as to provide a receiving hole 30 through a fastening hole 15a formed in the upper frame 10a and a fastening hole 15b formed in the lower frame 10b, An earthquake-resistant frame 10 is provided on the bottom surface of the frame. In this case, the lower frame 10b may be installed directly on the floor of the building. However, as shown in FIG. 7, a separate base 5 is firmly installed on the floor of the building, (10b).

The vibration damping pad 20 absorbs and buffs vibrations and shocks transmitted between the lower frame 10b and the upper frame 10a as shown in the structure of the vibration damping pad 20 provided inside the vibration damping frame 10. [ The upper plate 21a fastened to the upper frame 10a and the lower plate 21b fastened to the lower frame 10b are provided with upper and lower plates 21a and 21b, A pair of bearings 23 each formed in a hemispherical shape is divided and inserted into each of the space portions 22 so that the bearings 23 are covered with the covers 24 ).

The shaft 25 is connected to the pair of bearings 23 at both side ends of the shaft 25 by dividing the intermediate portion and interposing a connecting spring 26 in the divided intermediate portion, It is possible to absorb and cushion vibrations and impacts in the vertical direction, and in addition, even when an external force in the horizontal direction is applied, the restoring force of the connecting spring 26 acts after the shaft 25 is vertically bent, So as to absorb and cushion vibration and shock.

An elastic tube 27 made of urethane is formed between the covers 24 on both sides of the upper and lower plates 21a and 21b so that the shaft 25 is inserted into the inner peripheral surface of the elastic tube 27, A compression spring 28 having a relatively strong elastic force is provided between the upper and lower plates 21a and 21b so that the elastic tube 27 inserted with the shaft 25 is inserted into the center of the compression spring 28 And on the other hand by forming a plurality of tension springs 29 interconnecting the upper and lower play pieces 21a and 21b with the shaft 25 having the connecting spring 26 in the vertical and horizontal directions Vibration and impact acting on the elastic tube 27, the compression spring 28 and the tension spring 29 are absorbed and buffered.

The lower part of the support frame 30 is fixed to the fastening hole 15a formed in the upper frame 10a of the seismic frame 10 by means of bolts And the height adjustment means 35 is formed on the upper portion of the support hole 30. The height adjustment means 35 is formed of a screw shaft 36 and a nut 37, The support frame 40 installed on the support frame 30 is supported by the nut 37 so that the height of the support frame 40 can be adjusted according to the degree of unscrewing and tightening of the nut 37.

The support frame 40 installed on the support hole 30 is closely attached to the lower side of the connection frame 700 formed on the access floor to support the connection frame 700, The bracket 50 is fastened to the computer equipment S provided in the access floor and the through hole is formed in the upper plate 100 of the access floor And the bracket 50 and the support frame 40 are firmly fixed to each other by the fastening bolts 60 inserted into the through holes so that the existing computer equipment S can be installed or operated without interruption The computerized equipment S can be supported by the seismic strengthening apparatus 1 according to the present invention.

A method of constructing an anti-seismic reinforcement device according to a preferred embodiment of the present invention will be described. First, an access floor on which a computer S is installed or a plurality of bases The upper frame 10b of the earthquake-resistant frame 10 is fastened and fixed on the base 5 after the upper frame 5 is firmly fixed using an anchor bolt or the like, The earthquake-resistant frame 10 is installed on the base 5 by assembling the upper frame 10a such that the vibration-proof pad 20 is provided.

A plurality of support holes 30 are fastened and fixed on the upper frame 10a of the seismic frame 10 and then the nut 37 of the height adjustment means 35 provided on the support hole 30 The nut 37 as the height adjusting means 35 is loosened or tightened so that the upper surface of the support frame 40 is brought into close contact with the lower portion of the connection frame 700 provided on the access floor. do.

The bracket 50 is attached to the lower end of the computer equipment S or the computer equipment S installed in the access floor and the bracket 50 and the support frame 40 are fastened with the fastening bolts 60 It is possible to reinforce the earthquake-proof and vibration-isolating performance by firmly securing the computer equipment S to the seismic retrofitting apparatus 1 of the present invention.

On the other hand, when the computer equipment S is newly installed, the upper plate 100 of the access floor in which the through holes (not shown) are formed in advance is used. When the computer equipment S is installed in the access floor, (Not shown) to be inserted into the upper plate 100 can be installed or operated in the case of the computer apparatus S of the newly installed computer room as well as the already installed computer equipment S It is possible to reinforce the earthquake-proof and the vibration-isolating performance without interruption.

When the vibration, shock or vibration due to the earthquake occurs, the connection spring 26, the elastic tube 27, the compression spring 28, the tension spring 29, etc. of the vibration pad 20 The vibration damping device (1) of the present invention is equipped with a plurality of different types of elastic bodies to absorb vibrations and shocks, which are transmitted in various forms, As a result, it is possible to prevent the computer equipment (S) from being conducted.

In addition, even if the access floor of the computer room, which is susceptible to vibration and shocks when the earthquake occurs, is collapsed, the present invention allows the computerized equipment S to be supported on the floor of the building by the seismic strengthening device 1, The computer (S) is not turned on.

Particularly, when applied to a pre-installed computer system (S), there is no need to install or suspend the computer system (S) unlike the prior art. Ultimately, Improvement can be promoted.

1: Seismic strengthening device 5: Base
10: an earthquake-proof frame 10a:
10b: Lower frame 15a, 15b:
20: dustproof pad 21a: upper plate
21b: lower plate 22:
23: Bearing 24: Cover
25: shaft 26: connecting spring
27: elastic tube 28: compression spring
29: tension spring 30:
35: height adjusting means 36: screw shaft
37: nut 40: support frame
50: bracket 60: fastening bolt
S: Computing equipment

Claims (3)

delete (10) composed of a lower frame (10b) fixed to a bottom surface of a building and an upper frame (10a) fluidly coupled to the lower frame (10b);
A plurality of anti-vibration pads 20 formed inside the anti-vibration frame 10 to absorb vibration transmitted between the lower frame 10b and the upper frame 10a;
A plurality of support holes 30 provided above the seismic frame 10 and having height adjusting means 35;
And a support frame (40) mounted on the support (30) and supporting the lower side of the connection frame (700) formed on the access floor and being fastened to the lower part of the computer (S)
The vibration damping pad 20 is inserted into each of the space portions 22 of the upper and lower plates 21a and 21b and the upper plate 21a and the lower plate 21b having respective space portions 22, A pair of bearings 23 formed so as not to be separated by the cover 24 and a shaft 25 which is fastened to both ends of the pair of bearings 23 and is divided into a middle portion by a connecting spring 26, And an elastic tube 27 inserted between the side covers 24 and inserted into the shaft 25. The elastic tube 27 is inserted between the upper and lower plates 21a and 22b, A spring 28 and a plurality of tension springs 29 connecting the upper and lower plates 21a and 21b to each other. delete

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