KR102377258B1 - Acces floor with earthquake-proof performance system - Google Patents

Abstract

The present invention relates to an access floor, and more particularly, to an access floor to which a seismic isolation system that prevents vibrations caused by earthquakes from being transmitted to equipment installed on the access floor is applied.

Description

Access floor with earthquake-proof performance system

The present invention relates to an access floor, and more particularly, to an access floor to which a seismic isolation system that prevents vibrations caused by earthquakes from being transmitted to equipment installed on the access floor is applied.

In recent years, with the rapid development and generalization of telecommunication technology, computer rooms are often operated not only in professional communication facilities but also in general commercial buildings, officetels, apartments and buildings, and in these computer rooms, numerous cables connected to computer equipment can be efficiently used. In addition to management, an access floor is installed to secure an organized office space or activity space.

The conventional access floor consists of a floor 10 on which equipment is installed, and a support 20 installed on the floor surface of the building to support the floor 10, as shown in FIG. 1 , and between the floor and the floor 10 Various cables are placed in the space of

At this time, the floor 10 is equipped with heavy computing equipment and is formed with sufficient strength so that several people can stand on it. It is generally molded in a rectangular panel shape as shown in FIG. 2, and by combining the floor 10, the computer room make up the floor

The support 20 for supporting the floor 10 is provided with a support 21 in close contact with the floor surface of the building as shown in FIG. A head 22 to be adjusted is installed so that the head 22 supports the floor 10 .

The conventional access floor configured as described above has a problem in that, when an earthquake occurs, the equipment installed on the floor 10 easily falls and is damaged.

That is, vibration or shock caused by an earthquake is still transmitted to the floor 10, and the computer equipment on the floor 10 shakes and eventually falls down and the computer equipment is damaged.

As the computer equipment is overturned, greater secondary damage may occur due to the destruction of the computer equipment or the interruption of power and communication.

Therefore, in recent years, the frequency and intensity of domestic earthquakes are continuously increasing, and considering the fact that related laws such as earthquakes are being strengthened, there is an urgent need for an access floor in which the equipment installed on the access floor does not overturn even if an earthquake occurs. In addition, various types of access floors have been proposed to prevent equipment from overturning even in the event of an earthquake.

However, the conventional access floor, which prevents equipment from falling even during an earthquake, has problems in that the configuration is complicated, the installation cost is high, and it cannot be applied to the access floor that has been installed in the prior art.

Document 1. Korean Intellectual Property Office Registered Patent Publication No. 10-1997196, "Floor hinge device with adjustable damping force" Document 2. Korean Intellectual Property Office Registered Patent Publication No. 10-1497144, "Seismic reinforcing device for computing equipment installed on the access floor and its construction method" Document 3. Korean Intellectual Property Office Registration Patent Publication No. 10-1205809, "Seismic Isolation System for Access Floor" Document 4. Korean Intellectual Property Office Registration Patent Publication No. 10-0980387, "Seismic Isolation Structure of Access Floor"

The present invention has been devised to solve the above problems, and it is an object of the present invention to provide an access floor to which a seismic isolation system that can effectively prevent various equipment installed on the floor from falling even when an earthquake occurs.

In addition, it is an object of the present invention to provide an access floor to which a seismic isolation system capable of reducing installation costs and having a simple structure.

In addition, it is an object of the present invention to provide an access floor to which a seismic isolation system that can be used as a seismic isolation access floor simply by replacing the head of the support without the need to replace all of the conventional access floor.

In order to achieve the above object, the access floor to which the seismic isolation system according to the present invention is applied is a floor 10; Base 101 in close contact with the building floor surface; a pipe-shaped support 102 installed on the base 101; a screw rod 111 inserted into the support 102; a lower plate 108 in the form of a plate having a lower surface coupled to the screw rod 111; an upper plate 104 installed on top of the lower plate 108 and on which the floor 10 is mounted; and a slide guide for sliding the upper plate 104 with respect to the lower plate 108 so that the upper plate 104 slides with respect to the lower plate 108 to absorb displacement when an earthquake occurs.

At this time, the slide guide portion includes a bearing groove 106 formed in the form of a groove on the lower surface of the upper plate 104 or the upper surface of the lower plate 108; and a spherical bearing (107) inserted into the bearing groove (106).

In addition, it characterized in that it further comprises a; displacement limiting device for limiting the amount of displacement of the upper plate (104) with respect to the lower plate (108).

In addition, the displacement limiting device is a plate spring 110 having a predetermined width, one end of which is fastened to the rim of the upper plate 104 and the other end of which is fastened to the rim of the lower plate 108 , and the plate spring 110 includes the upper and lower plates. It is characterized in that it is radially fastened to (104, 108).

In addition, it is installed between the floor 10 and the wall of the building, a buffer 200 for absorbing the displacement of the floor 10 or the building; characterized in that it is configured to further include.

In addition, the buffer 200 includes a first cover 201 in which a pin 202 is formed in the opening direction, and a spring 203 is inserted into the pin 202; a second cover 205 in which a rod 206 is formed in the direction of the opening, and a long pin groove 207 is formed in the rod 206 in the axial direction; ) and the first and second covers 201 and 205 are coupled so that the spring 203 is in close contact with the inner surface of the first cover 201 and the end of the rod 206 .

In the present invention configured as described above, when an earthquake occurs, the support of the access floor absorbs the shaking displacement caused by the earthquake so that the equipment installed on the upper part of the floor does not shake, effectively preventing the equipment from being overturned.

In addition, the access floor according to the present invention has a simple structure and is the same as the conventional access floor installation process without a separate additional process, so the access floor to which the seismic isolation system is applied can be installed at a low cost.

In addition, the access floor to which the seismic isolation system is applied can be easily configured by replacing only the head of the support without replacing all the already installed access floors.

1 is a view showing a conventional access floor.
Figure 2 is a perspective view showing a conventional access floor configuration.
Figure 3 is a perspective view showing a support constituting the access floor of the present invention.
Figure 4 is an exploded perspective view showing an exploded view of the support constituting the access floor of the present invention.
5 is a cross-sectional view showing the configuration of the head portion of the support.
6 is a plan view showing the head of the support.
Figure 7 is an exploded perspective view showing an exploded view of the buffer constituting the access floor of the present invention.
8 is a cross-sectional view showing a buffer constituting the access floor of the present invention.
9 is a view showing an access floor of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to preferred embodiments of the present invention and the accompanying drawings.

In the detailed description or claims of the invention, when it is said that any one component 'includes' another component, it is not construed as being limited to only the component unless otherwise stated, and other components are not It should be understood that more may be included.

The access floor to which the seismic isolation system according to the present invention is applied is composed of a floor 10 and a support 100 supporting the floor 10 .

As shown in FIG. 3, the support 100 includes a base 101 in contact with the building floor, a pipe-shaped support 102 installed on the base 101 and having a lifting nut 103 formed thereon, and an outer surface It is composed of a screw rod 111 having a screw thread formed therein and screwed with the lifting nut 103 to be inserted into the support 102 , and a head 112 formed on the screw rod 111 .

The support 100 according to the present invention is configured to absorb the displacement generated by the earthquake in the head 112 .

The head 112 is configured by stacking a plate-shaped upper plate 104 and a lower plate 108 under the upper plate 104, and a slide guide is provided between the upper plate 104 and the lower plate 108. By being configured, the upper plate 104 is configured to slide with respect to the lower plate 108 by the slide guide.

That is, when an earthquake occurs, the base 101 of the support 100, the support 102, the screw rod 111, and the lower plate 108 fastened to the screw rod 111 vibrate and displacement occurs. The upper plate 104 on the lower plate 108 slides with respect to the lower plate 108 and absorbs the vibration displacement generated by the earthquake, thereby preventing the equipment installed on the floor 10 from falling.

In the slide guide, as shown in FIG. 4, a ball bearing 107 is inserted between the upper plate 104 and the lower plate 108, and the upper plate 104 is horizontally moved from the lower plate 108 by the bearing 107. The slide is configured to move.

Looking at this in more detail, a predetermined number of bearing grooves 106 are radially formed on the lower surface of the upper plate 104 as shown in Figs. is inserted

As the upper plate 104 configured as described above is placed on the lower plate 108 , when an earthquake occurs, the upper plate 104 slides horizontally from the lower plate 108 by the bearing 107 .

At this time, in order to prevent the upper plate 104 from deviating from the lower plate 108 , the leaf spring 110 is radially fastened to the edge of the upper plate 104 and the lower plate 108 as shown in FIGS. 4 and 5 .

As shown in FIG. 5 , the upper end of the leaf spring 110 is fastened to the rim of the upper plate 104 with a fastening bolt 109 , and the lower end of the leaf spring 110 is fastened to the rim of the lower plate 108 with a fastening bolt 109 . do.

When the upper plate 104 and the lower plate 108 are fastened with the leaf spring 110 as described above, the leaf spring 110 operates as a displacement limiting device of the upper plate 104 with respect to the lower plate 108, and an earthquake occurs. Prevents the 104 from deviate from the lower plate 108 and allows the upper plate 104 to be positioned at the center of the lower plate 108 due to the elasticity of the leaf spring 110 .

In the embodiment of the present invention, the bearing groove 106 is formed on the lower surface of the upper plate 104 and the bearing 107 is inserted into the bearing groove 106, but the bearing groove is located on the upper surface of the lower plate 108. (106) may be formed, and the bearing 107 may be inserted into the bearing groove 106 of the lower plate 108.

And, it is preferable to attach a gasket 104a having a locking protrusion 105 formed on the upper surface as shown in FIG. 5 .

When the floor 10 is installed, the corner portion of the floor 10 is caught on the clasp 105 to guide the construction of the floor 10 at the correct location, and the gasket 104 keeps the floor in close contact with the support 100 . let it be built

The base 101 of the support 100 configured as described above, the support 102, and the lifting nut 103 are the same as the conventional support without a conventional seismic isolation function. Therefore, it is possible to use by fastening the head 112 of the present invention by separating only the head from the support already installed in the prior art.

And it is preferable to install the buffer 200 on the edge of the floor coupled to lift the floor (10).

When an earthquake occurs, the floor and wall of the building vibrate, whereas the floor 10 fastened to the top plate 104 of the support 100 that absorbs the above-described earthquake displacement does not vibrate, whereas the wall of the building is resistant to earthquakes. vibrated by

Therefore, the wall vibrates and collides with the floor 10 in contact with the wall and the floor 10 is damaged, or the vibration of the wall is transmitted to the computer equipment through the floor 10 and the computer equipment may be conducted. In order to prevent this, the floor (10) It is preferable to install the buffer 200 between the assembled floor surface and the wall of the building.

As shown in FIG. 7 , the buffer 200 is configured by combining the first cover 201 and the second cover 205 in the form of a hexahedron having one side open and a space formed therein.

As shown in FIG. 7 , a predetermined number of pins 202 are formed in the direction of the opening of the first cover 201 , and a spring 202 is inserted and fastened to the pins 202 .

A predetermined number of rods 206 are formed in the direction of the opening of the second cover 205 , and pin grooves 207 are formed in each rod 206 in the form of a long hole.

As described above, the first cover 201 and the second cover 202 are fastened to form the buffer 200, and as shown in FIG. 8, the pins 202 of the first cover 201 are connected to the second cover 205 ) of the rod 206, the first and second covers 201 and 205 are coupled to be inserted into the pin groove 207.

When the first and second covers 201 and 205 are coupled as described above, one end of the spring 203 is in close contact with the inner wall of the first cover 201 , and the other end of the spring 203 is of the second cover 205 . It is in close contact with the end of the rod 206 .

The buffer 200 configured as described above is installed as shown in FIG. 9 , one side of the buffer 200 is in close contact with the building wall, and the other side of the buffer 200 is configured to be in close contact with the floor 10 .

When an earthquake occurs in this state, the building shakes and vibrates, and the floor 10 does not vibrate or vibrates with a greatly reduced amplitude. ) as the rod 206 is inserted or drawn into the pin groove 207, displacement is absorbed to prevent the floor 10 from being damaged.

And when the seismic vibration is finished, the spring 203 elastically pushes or pulls the second cover 205 to move the floor 10 in close contact with the second cover 205 to a predetermined position.

It is difficult to insert and install the buffer 200 between the floor and the wall due to the tension of the spring 102. As shown in FIG. 8, the fixing groove 204 of the first cover 201 and the second cover 205 It is preferable to insert the stopper 209 in the form of a pin into the fixing groove 208 to easily install the buffer 200 in a state in which the spring 203 is compressed and fixed.

In the present invention configured as described above, when an earthquake occurs, the support of the access floor absorbs the shaking displacement caused by the earthquake so that the equipment installed on the upper part of the floor does not shake, effectively preventing the equipment from being overturned.

In addition, the access floor according to the present invention has a simple structure and is the same as the conventional access floor installation process without a separate additional process, so the access floor to which the seismic isolation system is applied can be installed at a low cost.

In addition, it is possible to configure the access floor to which the seismic isolation system is applied by replacing only the head of the support without the need to replace all the already installed access floors.

The technical idea of the present invention has been reviewed through the above-described embodiments.

It is apparent that those of ordinary skill in the art to which the present invention pertains can variously modify or change the above-described embodiments from the description of the present invention.

In addition, even if not explicitly shown or described, a person of ordinary skill in the art to which the present invention pertains may make various modifications including the technical idea according to the present invention from the description of the present invention. is self-evident, which still falls within the scope of the present invention.

The above embodiments described with reference to the accompanying drawings have been described for the purpose of explaining the present invention, and the scope of the present invention is not limited to these embodiments.

10: floor
100: support
101: base
102: support
103: lifting nut
104: top plate
104a: gasket
105: jamming jaw
106: bearing groove
107: bearing
108: lower plate
109: fastening bolt
110: leaf spring
111: screw rod
112: head
200: buffer
201: first cover
202: pin
203: spring
204: fixed groove
205: second cover
206 : load
207: pin groove
208: fixed groove
209 : stopper

Claims (6)

floor 10;
Base 101 in close contact with the building floor surface;
a pipe-shaped support 102 installed on the base 101;
a screw rod 111 inserted into the support 102;
a lower plate 108 in the form of a plate having a lower surface coupled to the screw rod 111;
an upper plate 104 installed on top of the lower plate 108 and on which the floor 10 is placed;
One end is fastened to the rim of the upper plate 104, and the other end is a leaf spring 110 of a predetermined width fastened to the rim of the lower plate 108 is radially fastened to the upper and lower plates 104 and 108, so that the upper plate with respect to the lower plate 108 a displacement limiting device configured to limit the horizontal displacement amount of the upper plate 104 while applying elasticity to the 104 and elastically return the upper plate 104 to the center of the lower plate 108 with elasticity;
A plurality of bearing grooves 106 radially formed in a hemispherical shape on the lower surface of the upper plate 104 or the upper surface of the lower plate 108, and a spherical bearing 107 inserted into the plurality of bearing grooves 106. a slide guide configured to slide the upper plate 104 with respect to the lower plate 108;
A first cover 201 in which a pin 202 is formed in the direction of the opening and a spring 203 is inserted into the pin 202 , and a rod 206 is formed in the direction of the opening, and is attached to the rod 206 . It consists of a second cover 205 having a long pin groove 207 in the axial direction, and the pin 202 is inserted into the pin groove 207 so that the spring 203 is connected to the inner surface of the first cover 201 and the rod. (206) The first and second covers (201, 205) are coupled so as to be in close contact with the ends, the buffer 200 is installed between the floor 10 and the building wall to absorb the displacement of the floor 10 or the building;
a fixing groove 204 of the first cover 201 which is provided in the buffer 200 and into which a pin-shaped stopper 209 is inserted to facilitate installation of the buffer 200; and a fixing groove 208 of the second cover 205;
Consisting of, the upper plate 104 slides relative to the lower plate 108 when an earthquake occurs, and an access floor to which a seismic isolation system configured to absorb displacement is applied.
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