KR101314872B1 - Double floor with vibration isolator - Google Patents

Abstract

PURPOSE: A double floor including a vibration isolation device is provided to obtain a sufficient movement width in a horizontal direction as the interference of a cable is excluded. CONSTITUTION: A double floor including a vibration isolation device comprises a double floor frame (10), a vibration isolation unit (20), an upper panel (30), and a horizontal control unit (40). A plurality of horizontal frames and a plurality of vertical frames in the double floor frame are connected by a bracket. The double floor frame is installed by being separated from the bottom of a building at a fixed interval. The vibration isolation unit is installed on the upper surface of the double floor frame, and the upper panel is installed on the upper part. The horizontal control unit is installed on the lower end of the vertical frame and controls the levelness of the double floor frame.

Description

Double Floor with Vibration Isolator

The present invention relates to a double floor provided with a seismic isolation device, and more particularly, a seismic isolation device for safely protecting these devices by preventing vibrations from being transmitted to computer equipment, communication equipment, or precision measurement equipment during an earthquake. A double floor is provided.

Expensive computing equipment, communication equipment, or precision measuring equipment are installed and used in banks, research institutes, and power plants. Since these equipments are sensitive to temperature, it is necessary to keep the temperature of the space where these equipment is installed at an appropriate temperature. For this purpose, after installing a double floor, a computer equipment is installed in the upper part of the double floor, and a duct connected to an air conditioner is installed in the lower part of the double floor to control the room temperature.

 However, even when the floor is installed in this way, if the vibration from the outside of the building, such as an earthquake, damage to the computer equipment or measurement equipment, etc., in this case can lead to serious paralysis.

Accordingly, by additionally installing an isolating device on the double floor, various devices have been developed to protect the equipment installed on the upper floor even when an external force such as an earthquake is applied. As one example, it is disclosed in Korean Patent No. 1178870. Double floor isolator.

As shown in FIG. 1, the double floor isolating device disclosed in the patent document has an upper frame 100 installed at a lower portion of the upper panel 100 so as to support the upper panel 100 and the upper panel 100. And, it is composed of a plurality of struts 300 are installed in the vertical direction in combination with the respective corners of the upper frame 200 and the base isolation driving unit 400 is installed at the bottom of each strut 300, the upper panel 100 Height adjustment column 500 is installed between the upper frame 200 and the upper frame 200 to maintain the horizontal level of the upper panel 100. In case of an earthquake, the base isolation driving unit 400 slides in the horizontal direction and is isolated. Perform the function.

However, the seismic isolator disclosed in the patent document, since the width that the seismic isolation driving unit 400 which performs the seismic isolation function is limited to 10 to 20 cm to secure an installation space such as a cable tray, If an earthquake (usually about 19 cm of movement of the base isolation driving unit 400 for an earthquake of magnitude 6) is applied, not only a smooth base isolation function can be secured, but also the base isolation driving unit 400 serves as a stopper. This may increase the damage of the equipment.

In addition, the seismic isolator of the patent document is because the seismic isolation unit 400 is installed on the floor of the building, there is a fear of interference with a communication line, a power cable, a cable tray or a duct, etc. installed on the floor, as described above. ) Interferes with the cable, etc., further restricts movement in the horizontal direction.

In addition, even when the earthquake is blocked by the base isolation driving unit 400, generally fine vibration is transmitted to the upper portion of the base isolation driving unit 400, the upper panel 100 is installed, the computer equipment in the patent document is the upper Because the frame 200 and the support 300 are spaced apart from the base vibration driving unit 400 in the vertical direction to a considerable extent, even if the minute vibration is transmitted, the fine vibration is amplified by the spaced apart vertical distance, so effective isolation cannot be expected. there is a problem.

In addition, since the height adjustment column 400 that adjusts the horizontal level of the upper panel is installed on the upper part of the upper frame rather than the floor of the building, the base is installed on the floor when the floor surface where the double floor is installed is not horizontal. It is not possible to adjust the level of the drive unit, in this case the operation of the seismic isolation unit is not made smoothly.

The present invention has been devised to solve the problems of the double floor with the conventional seismic isolation function, it is possible to ensure a sufficient moving width in the horizontal direction by eliminating interference with the cable, etc. It is an object to provide an isolated raised floor that can be achieved.

In another aspect, the present invention is to provide an isolating double floor that can more robustly support the load by computing equipment, communication equipment or precision measurement equipment installed on the upper floor.

An object of the present invention as described above is made of a double floor, a plurality of horizontal frames and a plurality of vertical frames are coupled by a plurality of brackets, double floor frame is installed spaced apart from a certain height from the floor; A plurality of base isolation units installed on an upper surface of the double floor frame; An upper panel installed on an upper surface of the plurality of base isolation units and having a computing device installed thereon; Installed on each lower end of the vertical frame and made of a horizontal adjustment unit for adjusting the horizontality of the double floor frame, wherein the horizontal adjustment unit includes a support plate installed on a building floor; A screw shaft installed vertically in the center of the support plate; The screw is coupled to the screw shaft, the height adjustment member for adjusting the height by supporting the bottom of the vertical frame, the plurality of base isolation units are formed in the upper and lower concave curved guide grooves are formed symmetrically with each other A damping panel; It is achieved by the ball member is installed between the upper, lower isolation panel and rolled along the guide groove.

At this time, the height adjustment member is made of a structure in which a plurality of wings protruding, it is preferable to be installed in contact with the bottom of the vertical frame.

In addition, the upper and lower isolation panels are provided with a plurality of coupling protrusions, each of which is cut in the top and bottom surfaces thereof, and bent in a vertical direction. The lower isolation panel is fixed to the raised floor frame by screws or bolts coupled to the coupling protrusion. The upper panel is preferably fixed to the screw or bolt is coupled to the coupling protrusion of the upper isolation panel.

In addition, the bracket and the first coupling portion is coupled to the horizontal frame or the vertical frame in a vertical direction; A second coupling part formed to intersect the first coupling part to form a “T” shape in a vertical direction, and the horizontal frame or the vertical frame is coupled in a horizontal direction; The third coupling part is formed to cross the second coupling part in a horizontal direction to form a "T" shape, and the horizontal frame or the vertical frame is composed of a third coupling part coupled in a horizontal direction, and the first and third coupling parts are formed in the horizontal frame or It is more preferable that the cross-sectional shape is formed in a "c" shape so as to surround the outer circumferential surface of the vertical frame, and the second coupling portion is formed in a "b" shape.

And it is more preferable that the bracket is installed symmetrically so that the two brackets face each other in a pair.

In the present invention, since the seismic isolator which blocks the vibration due to the earthquake is not installed on the floor of the building but is spaced apart from the floor by a predetermined distance, the movement width of the seismic device is not limited, and also the interference with the cable and / or the cable tray. This eliminates the guarantee of smooth seismic function.

In addition, the present invention is coupled to the upper panel and the base isolation unit through the coupling protrusion, it is possible to easily and simply combine the upper panel and the base isolation unit without installing a bracket separately and at the same time can maintain a strong coupling.

And the present invention can be easily rotated by the horizontal adjustment unit even when the user is difficult to access the horizontal adjustment unit is made of a structure in which the height adjustment member is formed with a plurality of wings protruding.

1 is a perspective view showing an example of a conventional double floor isolating device,
Figure 2 is a perspective view of a base isolation double floor according to the present invention,
Figure 3 is a side view of Figure 2,
Figure 4 is a perspective view showing an example of the raised floor frame according to the present invention,
5 is a perspective view showing an example in which a horizontal frame and a vertical frame are coupled by a bracket according to the present invention;
Figure 6 (a, b) is a perspective view showing an example of the bracket according to the present invention,
Figure 7 is an exploded perspective view showing an example of the base isolation unit according to the invention,
Figure 8 (a, b) is a cross-sectional view showing an example of the sliding operation of the upper isolation panel of the isolation base unit according to the present invention;
Figure 9a is a perspective view showing an example in which the lower isolation panel is coupled to the raised floor frame according to the present invention,
Figure 9b is a perspective view showing an example of the upper panel coupled to the upper isolation panel according to the present invention,
10 (a, b) is a perspective view and a cross-sectional view showing an example of the horizontal control unit according to the present invention, respectively.

Hereinafter, the structure and operation of the present invention will be described in more detail with reference to the accompanying drawings, which show preferred embodiments.

The present invention relates to a base isolation double floor that can easily and accurately adjust the horizontal level while ensuring a sufficient moving width in the horizontal direction to perform the base isolation function stably, the base isolation double floor according to the present invention is shown in FIGS. As shown is made of a double floor frame 10, the base isolation unit 20, the upper panel 30 and the horizontal control unit (40).

The raised floor frame 10 functions as a frame for forming a double floor, and the raised floor frame 10 is made of a section steel having a square or rectangular shape as shown in FIGS. 4 and 5, It is installed to be spaced apart from the floor by a certain height, for this purpose, the raised floor frame 10 is a plurality of horizontal frame 11 and the vertical frame 12 and a plurality of coupling the horizontal frame 11 and the vertical frame 12 with each other It consists of a bracket (13).

At this time, the horizontal frame 11 is joined to cross the cross shape in a crisscross shape at regular intervals corresponding to the area of the floor surface on which the raised floor frame 10 is installed, and thus one horizontal frame 11 and At the position where the other horizontal frame 11 is in contact with each other, the vertical frame 12 is coupled in the vertical direction so that the upper surface of the horizontal frame 11 is spaced apart from the floor by a certain height.

Since the vertical frame 12 supporting the load of computer equipment and the like may be weak against external force in the horizontal direction, as shown in FIG. 5, the vertical frame 12 and the vertical frame 12 below the vertical frame 12. ) Is further provided with a reinforcing frame 14 to connect each other in the horizontal direction, even if an external force is applied to the vertical frame 12 in the horizontal direction by such a reinforcing frame 14 is not easily collapsed and installed more strongly vertically maintain.

On the other hand, the horizontal frame 11 and the vertical frame 12 and the reinforcing frame 14 are coupled to each other by the bracket 13, the bracket 13 according to the present invention is shown in Figure 6 the first coupling portion 13A, the second coupling portion 13B, and the third coupling portion 13C.

At this time, the horizontal frame 11 or the vertical frame 12 is coupled to the first coupling portion 13A in the vertical direction, and the second coupling portion 13B is the "T" letter in the vertical direction with the first coupling portion 13A. The horizontal frame 11 or the vertical frame 12 is combined in a horizontal direction so that the third coupling part 13C forms a "T" shape in the horizontal direction with the second coupling part 13B. The cross frame is formed so that the horizontal frame 11 or the vertical frame 12 is coupled in the horizontal direction.

A plurality of through holes (not shown) are formed in the first, second, and third coupling parts 13A, 13B, and 13C, and the coupling members are connected to the first, second, and third coupling parts 13A, 13B. , 13C) is assembled and fixed through the side of the horizontal frame 11 and the vertical frame 12 and the reinforcing frame (14).

In addition, the bracket 13 is formed to be separated into a pair having a symmetrical shape with each other is installed facing the horizontal frame 11, the vertical frame 12 and the reinforcing frame 14, a pair of brackets (13) facing each other The first and third coupling parts 13A and 13C are formed to have a "C" cross-sectional shape so as to surround the outer circumferential surfaces of the horizontal frame 11, the vertical frame 12, and the reinforcement frame 13. The two coupling parts 13B are formed to have a "b" shaped cross-sectional shape.

At this time, the second coupling part 13B is formed by the second coupling part 13B which is symmetrically opposed to each other to form a "c" shape by the "b" and inverse "b" shape.

By the coupling structure of the bracket 13, the horizontal frame 11, the vertical frame 12 and the reinforcement frame 14 can be maintained in a rigidly coupled state by vertically intersecting each other at 90 ㅀ, thus the present invention The double ridge frame 10 according to the present invention can more firmly support the load caused by computer equipment installed on the upper portion thereof, and also does not cause deformation such as being easily collapsed or inclined even when an external pressure occurs in the horizontal direction.

When an external force such as an earthquake is applied, the seismic isolation unit 20 sliding in the horizontal direction is installed and fixed on the upper surface of the double floor frame 10, and the structure thereof is as shown in FIG. 7. It is composed of a base isolation panel 22 and the ball member (23).

The bottom of the upper isolation panel 21 is formed with a guide groove (H) curved concave toward the center as shown in Figure 8 (a, b), the upper isolation of the upper isolation of the lower isolation panel 22 The guide grooves H 'are curved to be curved toward the center so as to be symmetrical with the guide grooves H of the panel 21.

And the ball member 23 is installed in the space formed by the guide groove (H, H ') formed in the upper isolation panel 21 and the lower isolation panel 22, respectively, when the earthquake occurs, the cloud of the ball member 23 By operation, the position is maintained without being moved to the upper isolation panel 21, whereby the position of the computer equipment and the like located thereon is also maintained. At this time, the ball member 23 is made of steel (steel) having a certain strength so that the shape can be maintained as it is even if a load by the computer equipment is applied to the ball member (23).

In addition, it is preferable to form a round step (without reference numeral) at the edges of the guide grooves H and H 'formed of the concave grooves so that the ball member 23 is not separated from the concave grooves by the step. Do.

When the earthquake occurs due to the structure of the guide grooves H and H 'as described above and the ball member 23, the lower base isolation panel 22 of the base isolation unit 20 slides in the horizontal direction together with the bottom surface of the building. Then, when the external force caused by the earthquake is extinguished, the ball member 22 is moved back to the center of the guide grooves (H, H ') by the inclined surfaces of the guide grooves (H, H') to return to the initial installation position.

At this time, the diameter of the guide groove (H, H ') is formed to a size that can ensure a sufficient moving width even for a large-scale earthquake, as shown in Figure 8, the present invention is a base isolation unit 20 as described above It is installed on the upper part of the raised floor frame 10, and thus free from cables, cable trays and ducts, it is possible to install a base isolation unit 20 having guide grooves (H, H ') of a sufficient diameter. As a result, the design freedom of the base isolation unit 20 is greatly improved.

Meanwhile, the base isolation unit 20 according to the present invention may further include a ball stopper for fixing the upper and lower base isolation panels 21 and 22 so as to slide only at a predetermined vibration or more.

The seismic isolation unit 20 is fixed to the double floor frame 10 at fixed intervals, and then the upper panel 30 is seated and fixed on the upper surface thereof, and the upper and lower isolation panels 21 of the present invention for this purpose. , 22) is provided with a plurality of engaging projections (21A, 22A) are respectively bent in the vertical direction by the top and bottom surfaces are partially cut.

Due to such a structure, the base isolation unit 20 is spaced apart at regular intervals so that the horizontal frame 12 of the raised floor frame 10 is positioned at a corner portion where the horizontal frame 12 of the double floor frame 10 abuts 90 °. Coupling and fixing to the horizontal frame 12 of the raised floor frame 10 by coupling the screw or bolt to the engaging projection 22A of the panel 22, the upper panel 30 is the engaging projection of the upper isolation panel 21 A screw or bolt is coupled to and fixed to 21A.

As a result, the plurality of base isolation units 20 are fixed to the raised floor frame 10 without being coupled and fixed to each other, thereby supporting the loads firmly, and also fixing the upper panel 30 to the upper base isolation panel 21. It can be fixed simply without using a separate bracket.

The upper panel 30, in which structures such as computer equipment, communication equipment, or precision measuring equipment are installed on the upper part, functions as an upper floor of the double floor, and a panel frame made of a section steel having a rectangular cross section at the edge of the upper panel 30. 31 is installed along the perimeter.

And the upper panel 30 is supported by the base isolation unit 20 is located at the bottom, the upper panel 30 is coupled to each other to operate integrally with the base isolation unit 20 when an earthquake occurs, To this end, as shown in FIG. 9B, the upper surface of the base isolation panel 21 of the base isolation unit 20 is partially cut to form a plurality of coupling protrusions 21A bent in the vertical direction, and the coupling protrusions 21A are formed. The panel frame 31 of the upper panel 30 is coupled to each other using screws or bolts, and the upper panel 30 and the base isolation unit 20 are easily and simply coupled to each other without installing a bracket by the coupling structure. Can also maintain a strong bond.

Horizontal control unit 40 is installed at the bottom of the vertical frame 12 of the raised floor frame 10 to achieve a horizontal level by easily adjusting the horizontal of the raised floor frame 10, respectively, such a horizontal control unit 40 As shown in Figure 10 (a, b) is a support plate 41 fixed to the floor of the building, a screw shaft 42 is installed vertically in the center of the support plate 41, screw shaft 42 The screw is coupled to the) is made of a height adjusting member 43 for adjusting the height of the vertical frame 21 by rotating while supporting the bottom of the vertical frame 12, wherein the bottom of the vertical frame 12 is a height adjusting member The structure is supported by the height adjusting member in contact with the upper surface of the 43, when the user rotates the height adjusting member 43 by this structure, the height adjusting member 43 moves up and down along the screw shaft 42. Vertical frame 12 installed in contact with the height adjusting member 43 ) Is also moved up and down to adjust the height.

In the present invention, the fixed block 44 is installed on the bottom of the vertical frame 12 as described above, so that the fixed block 44 has a structure in which the upper surface of the height adjusting member 43 is in contact with the height adjusting member ( 43, the vertical load is applied, and as a result, even if a minute vibration is applied to the upper panel by the user's movement, the height adjustment member 43 is not rotated to maintain the position of the top panel to maintain the position Can be.

And the horizontal adjustment unit 40 is installed near the floor of the building, the horizontal adjustment by the horizontal adjustment unit 40 is usually the double floor frame 10 and the base isolation unit 20 and the upper panel 30 and the like. Because it is made in the installed state, it may be difficult for the user to approach the horizontal adjustment unit 40, according to the present invention, the height adjustment member 43 is formed in a structure in which a plurality of wings protrude as shown in FIG. By this structure, the user can rotate the blade of the height adjusting member 43 using a separate pipe or bar even at a long distance, and thus can easily adjust the horizontal.

As described above, the present invention can effectively protect computer equipment from external forces caused by earthquakes and the like by providing a base isolation device on the double floor, and the base isolation device is not installed on the floor of the building but is spaced apart from the floor by a predetermined distance. For this reason, the movement width of the paper sheet device is not limited, and the interference with the cable and / or the cable tray is eliminated, and smooth seismic effect can be expected.

10: raised floor frame 11: vertical frame
12: horizontal frame 13: bracket
13A: first coupling portion 13B: second coupling portion
13C: third coupling portion 14: reinforcement frame
20: isolation unit 21: upper isolation panel
21A, 22A: engaging protrusion 22: lower isolation panel
23: ball member 30: upper panel
31: panel frame 40: leveling unit
41: support plate 42: screw shaft
43: height adjustment member 44: fixed block
H, H ': Guide groove

Claims (5)

A plurality of horizontal frames 11 and a plurality of vertical frames 12 are combined by a plurality of brackets 13, and a double floor frame 10 installed spaced apart from a certain height by a floor;
A plurality of base isolation units 20 installed on an upper surface of the double floor frame 10;
An upper panel 30 installed on an upper surface of the plurality of base isolation units 20 and having computer equipment installed thereon;
Installed at the lower end of the vertical frame 12, respectively, made of a horizontal adjustment unit 40 for adjusting the horizontal of the raised floor frame 10,
The horizontal adjusting unit 40 and the support plate 41 is installed on the building floor; A screw shaft 42 installed vertically in the center of the support plate 41; Is screwed to the screw shaft 42, and is composed of a height adjusting member 43 for adjusting the height by supporting the bottom of the vertical frame 12,
The plurality of base isolation units 20 includes upper and lower base isolation panels 21 and 22, each of which has concave curved guide grooves H and H ′ symmetrically up and down; The double floor provided with the base isolation device, characterized in that consisting of the ball member 23 is installed between the upper, lower base isolation panels (21, 22) and the cloud moving along the guide groove (H, H ').
The method according to claim 1,
The height adjustment member 43 is made of a structure in which a plurality of wings protruding, the double floor with a base isolation device, characterized in that installed in contact with the bottom of the vertical frame (12).
The method according to claim 1 or 2,
The upper and lower isolation panels 21 and 22 are provided with a plurality of coupling protrusions 21A and 22A, respectively, in which an upper surface and a bottom surface are partially cut and bent in a vertical direction.
The lower isolation panel 22 is screwed or bolted to the engagement protrusion 22A and fixed to the raised floor frame 10, and the upper panel 30 is the engagement protrusion of the upper isolation panel 21. Double floor provided with a seismic isolation device characterized in that the screw or bolt is coupled to and fixed to (21A).
The method according to claim 1 or 2,
The bracket 13 includes a first coupling part 13A to which the horizontal frame 11 or the vertical frame 12 is coupled in a vertical direction;
A second coupling part (13B) formed to intersect the first coupling part (13A) to form a "T" shape in a vertical direction, and the horizontal frame (11) or the vertical frame (12) is coupled in a horizontal direction;
The third coupling part 13B is formed to intersect with the second coupling part 13B in a horizontal direction to form a “T” shape, and the horizontal frame 11 or the vertical frame 12 is formed as a third coupling part 13C coupled in the horizontal direction. under,
The first and third coupling parts 13A and 13C may have a cross-sectional shape having a “C” shape to surround the outer circumferential surface of the horizontal frame 11 or the vertical frame 12.
The second coupling part (13B) is a double floor with a base isolation device, characterized in that the cross-sectional shape is formed in the "b" shape.
The method of claim 4,
The bracket (13) is a double floor with a base isolation device, characterized in that the two brackets (13) are installed in a pair symmetrically facing each other.

Images