KR20220095462A - Holding Reinforcement with Elastic Material - Google Patents

Abstract

A general dual floor having a poor earthquake response ability requires the securement of an earthquake response ability through dual floor support seismic reinforcement. In accordance with the present invention, a dual floor support is reinforced through a support combination reinforcement material, a diagonal reinforcement material and a horizontal reinforcement material, wherein not every support in a corresponding room is reinforced, and, instead, a support in an area excluding an equipment area is selectively reinforced. In the equipment area, there is difficulty for a person to work because most dual floor supports in the area are no more than 40cm in height. There is difficulty not only for a newly constructed dual floor but also for an existing dual floor in most cases. In accordance with the present invention, a reinforcement material is developed to basically reinforce the flange of a dual floor room to be reinforced, and, when seismic reinforcement is determined as lacking through seismic analysis, achieve sufficient seismic performance by additionally reinforcing a support column (row) in which there is no equipment. Moreover, the reinforcement material is developed to be installable on an existing dual floor without the need for the dismantlement of a support. In accordance with another characteristic of the present invention, a material with a high frictional force is applied to the reinforcement material such that the support and the reinforcement material can properly come in tight contact, which can lead to an improvement in seismic performance. As the reinforcement material has passed a test of the National Radio Research Agency 2020-1 test method (6.8 on the Richter scale) in an authorized test institution, the performance thereof is proved.

Description

Holding Reinforcement with Elastic Material

The present invention relates to a post reinforcing material having an elastic material, and more preferably, an elastic material capable of reinforcing frictional force of a post coupling reinforcing material capable of being coupled to a post of a general raised floor used in equipment rooms such as computer rooms, communication rooms, and electrical rooms. It relates to a post reinforcing material provided with an elastic material configured to be prepared for earthquakes, etc. like a general raised floor by reinforcing it with an earthquake-resistant raised floor.

A general raised floor 300 generally used in equipment rooms such as computer rooms, communication rooms, and electrical rooms, as shown in FIG. It is composed of a stringer 330 coupled to the 320 and a panel 340 installed on the stringer 330 .

The protection object 400 installed on the general raised floor 300 is installed with important things placed therein, but even when an earthquake occurs, as shown in 1b, the collapse of the post 310 is a concern.

Therefore, reinforcement of the post 310 for the newly installed general raised floor 300 as well as the already installed general raised floor 300 is emerging as a hot topic.

However, since the already installed general raised floor 300 cannot dismantle the post 310, it is a task to reinforce the earthquake resistance of the post 310 without disassembling the post 310.

In addition, it is practically difficult to reinforce the seismic resistance of the lower post 310 in the equipment area, and if the height of the post is 40 cm or less while there is a cable on the floor, it is practically very difficult for a person to go into the lower part of the post and work.

And, in the case of general post reinforcement, slip occurs due to seismic shock, and as a result, the seismic performance is weakened by twisting between the post 310 and the reinforcement or between the reinforcement and the reinforcement.

In addition, as shown in FIG. 2a , various post reinforcement methods applied in Korea have a method of reinforcing the entire post 310 . Therefore, as shown in FIG. 2B , after the general raised floor is installed, in reality, it is very difficult to reinforce the post 310 in the lower part of the raised floor in the area where the object to be protected 300 is installed.

13 is a perspective view showing an example of a conventional raised floor 100 on which equipment 113 is mounted. The main components are a raised floor panel 102 and a post 110, an upper end post 111 and a lower end post 112. is formed by connecting And the stringer 101 is connected in all directions to the head 103 that is seated on the upper end of the upper post 111 is configured. In the case where response to earthquakes is insufficient with this configuration alone, reinforcement for the posts is required.

The head 103 has a post insertion hole 127 formed in the central part, and a rectangular stringer coupling part 124 is formed on the outer peripheral surface of the post insertion hole 127 to connect the stringer 101 from all directions. , a fastening hole 124A for fastening the stringer 101 with the fastener 140 is formed in the stringer coupling part 124 . In addition, a cut-out groove 125 is formed between the stringer coupling part 124 and the stringer coupling part 124 , and a triangular stringer fixing reinforcing plate 126 is formed.

14A is a registered patent (10-1295932) for a post reinforcement material for a raised floor 100a, in which a post 110 for supporting the panel 102 on which the equipment 113 is mounted is provided with reinforcement materials 80 and 80'. ) is very strong, but it is an expensive configuration, and there are many adapters 190 and bolting fastening points, so it is difficult to construct and the construction cost increases. When this is applied, it is necessary to install the reinforcing material in a narrow work space while preventing problems from occurring in the equipment being operated when reinforcing the pre-installed poles and the burden of price, which may cause inconvenience to workers and burden due to an increase in construction cost.

14B is a registered patent (10-0919686) for a raised floor post reinforcement, which is a configuration that can only be used when newly built, and the head 210 used as a reinforcement for the raised floor post 110 is coupled with a stringer 220 A unique method is applied, and both end surfaces of the stringer 220 are not slanted, and thus have a structure suitable for the head 210 applied only to the corresponding patent. In addition, since the layer of the stringer 220 is diagonally configured, the cable tray and the cable are moved over the stringer 220 on the floor, so there is a high risk of the stringer 220 being damaged by their load, and workers are required to use the stringer on the floor If you step on (220) and try to avoid stepping on it, you will feel a lot of difficulties in the work.

Thus, the "double floor post reinforcement" of Registration Patent No. 10-1530785 was disclosed as a prior art invented and registered by the present inventor, but the above configuration is to reinforce the head, and there is a risk of the post being damaged because it cannot be elastically reinforced in the event of an earthquake. there was

Domestic Registered Patent No. 10-0919686 Domestic Utility Model Registration No. 20-0411712 Domestic Registered Patent No. 10-0919686 Domestic Registered Patent No. 10-1530785

The present invention has been devised to solve the above problems,

The purpose of this is to reinforce the already installed general raised floor without dismantling it from the earthquake.

In addition, the purpose of the present invention is to eliminate the phenomenon in which the seismic performance is weakened due to the reinforcing material twisting due to the seismic impact due to insufficient binding force between the posts of the general raised floor and the reinforcing materials for reinforcing the posts.

In order to achieve this purpose,

According to one aspect of the present invention,

As shown in FIG. 4, the configuration according to the present invention constitutes post coupling reinforcements 710 and 720 that can be coupled to the post 310 without disassembling the post 310 of the installed general moving floor 300. However, the elastic material 730 of the coating 731, strip 732, and pipe 733 capable of strengthening the frictional force between the post 310 and the post coupling reinforcement 700 is applied to the inside of the post coupling reinforcement 700. It is characterized in that it is prepared to solve it.

In addition, as shown in FIGS. 6 and 8D , the horizontal reinforcing material 610 and the diagonal reinforcing material 620 for reinforcing the post 310 according to the present invention is an elastic material ( 730) to maximize frictional force.

The present invention makes it possible to respond to strong seismic shocks by strengthening the frictional force between the poles and the pole reinforcement, and strengthening the frictional force between the pole coupling reinforcement and the diagonal reinforcement or the horizontal reinforcement. With strong seismic performance, there is an effect that the raised floor can sufficiently have seismic performance even by reinforcing only a part of the posts instead of reinforcing the posts in the entire area of the raised floor.

In addition, according to the present invention, since it is impossible or very difficult to reinforce the lower post of the object to be protected, selectively reinforcing the post in an area other than the lower part of the area to be protected has the effect of easily reinforcing the post.

1 is a perspective view showing an embodiment of a general raised floor.
2 is a perspective view showing an embodiment of a general installation form of seismic reinforcement applied to a general raised floor. (Entire support reinforcement)
3 is a perspective view illustrating an embodiment of a raised floor post reinforcement according to the present invention.
4 is a perspective view showing an embodiment of a post coupling reinforcement according to the present invention.
5 is a perspective view showing an embodiment of a method of manufacturing a post coupling reinforcement according to the present invention.
6 is a perspective view showing an embodiment of the diagonal reinforcement according to the present invention.
7 is a perspective view showing an embodiment of a method for manufacturing a diagonal reinforcing material according to the present invention.
8 is a perspective view showing an embodiment of a method for installing a diagonal reinforcement in the floor direction according to the present invention.
9 is a perspective view showing an embodiment of a horizontal reinforcement according to the present invention.
10 is a perspective view showing an embodiment in which the diagonal reinforcement according to the present invention is applied to the entire room. (For less than 300 m2: only the rim, for more than 300 m2: rim + selective heat reinforcement)
11 is a perspective view showing an embodiment in which a diagonal reinforcing material and a horizontal reinforcing material according to the present invention are mixed and applied to the entire room. Insert both the picture where the horizontal reinforcement is installed at the bottom and the picture where the horizontal reinforcement is installed at the top
12 is a perspective view showing a fixing method after installing the horizontal reinforcement according to the present invention at the bottom.
13 is a perspective view illustrating an example of the existing raised floor 100 on which the equipment 113 is mounted.
14A is a front view of another general raised floor 100a post reinforcement.
14B is a perspective view of another typical raised floor post reinforcement.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art can easily implement them. However, the present invention may be implemented in several different forms and is not limited to the embodiments described herein.

As shown in FIG. 1 , a general general raised floor 300 does not have an earthquake response function. A post 310 is fixed to the floor, a head 320 is provided on the post 310 , a stringer 330 is coupled to the head 320 , and a panel 340 is placed on the stringer 330 . This configuration requires reinforcement for earthquake response because there is a risk of collapse and damage of the post 310 when a large earthquake in the horizontal direction occurs.

As shown in FIG. 2 , all of the various post reinforcement methods applied in Korea are methods of reinforcing the entire post 310 . However, in reality, it is very difficult to perform such reinforcement work in the lower part of the general raised floor 300 in the area where the protection object 400 is installed. In general, one panel 340 of the general raised floor 300 is 600 x 600 mm, and in general, looking at the equipment size, the width is 600 mm and the depth is 800 to 1,200 mm. That is, there is a post 310 in the middle part of 1,200 mm in the height direction. If the height of the post 310 is 400 mm or less, the human hand cannot reach it.

In addition, there are many cables in the lower part of the object 400 to be protected, such as computer and communication equipment, so cable damage may occur during operation, so there are many places where it is impossible to reinforce the post 310 under the object 400 to be protected.

However, according to the guidelines of the Ministry of Public Administration and Security in Korea, when the height of the post 310 exceeds 100 mm, the post 310 is unconditionally reinforced. A method of solving this should be such that the reinforcement performance of the pole 310 is strengthened so that it is not necessary to reinforce the lower pole 310 of the area to be protected 400 .

As shown in FIGS. 3A and 4A , the post reinforcement 600 for reinforcing the posts 310 of the raised floor 1000 according to the present invention is a post coupling reinforcing material 700 for wrapping and fixing the outer circumferential surface of the posts 310 . ), a diagonal reinforcing material 620 and a horizontal reinforcing material 610 connecting one side to the post coupling reinforcing material 700 .

As shown in FIG. 3b , the post coupling reinforcing material 700 is coupled to the outer circumferential surface of the post 310 in a semi-circularly separated structure, and the diagonal reinforcing material 620 is formed at one end horizontally, and the upper end of the post 310 . Coupled to one side of the post coupling reinforcement 700 coupled to, and the other end formed horizontally is coupled to the post binding reinforcement 700 coupled to the lower end of the neighboring post 310, or the floor surface or the floor coupled to the floor coupled to the fixture 800 .

In addition, the horizontal reinforcement 610 has one end coupled to the post coupling reinforcement 700 coupled to the post 310, and the other end is coupled to the post coupling reinforcement 700 coupled to the adjacent post 310. . You may use these post coupling reinforcing materials 700 by appropriately combining them according to the field.

As shown in FIG. 4A, the post coupling reinforcement 700 according to the present invention has a separated structure, and the elastic material 730 can be attached to the inside of the separated structure. Coating 731, strip 732 , is provided in the form of a pipe 733 is configured so that the post 310 and the post coupling reinforcement 700 are firmly coupled.

The elastic material 730 formed on the inner surface of the post coupling reinforcing material 700 maximizes the frictional force to further enhance the earthquake-resistant performance. One method of providing the elastic material 730 is a method of coating (731) the elastic material 730 on the inner surface of the post coupling reinforcing material 700, and by adding the elastic material 730 to the inner surface.

The method of coating 731 of the elastic material 730 on the inner surface of the post coupling reinforcement 700 is, as shown in FIG. 4b, coating 731 of the elastic material 730 in a spraying form 740. . In addition, as shown in FIG. 4c , the coating 731a may be immersed in the liquid elastic material 730 .

In addition, as shown in FIG. 4D, the padding on the post 310 is applied to the inside using a band 732 of a flexible elastic material 730 that fits the size of the post coupling reinforcing material 700, or a pipe type 733. It can be manufactured in the form of splitting the elastic material 730 of the longitudinal direction and putting it on the inside. That is, an elastic material 730 having a pipe shape 733 that is split in the middle of FIG. 4E and surrounds the post 310 is attached to the outer circumferential surface of the post 310, and the elastic material 730 having the pipe shape 732) It is coupled with a bolt 780 to the post coupling reinforcement 700 (710, 720) on the outer circumferential surface of the .

In addition, as shown in FIG. 4f , a C-shaped elastic material 734 for reinforcing the post 310 may be formed to couple the post reinforcing material 700 . The C-shaped elastic material 734 cuts one side, spreads the cut surface, inserts it into the post 310 and wraps it, and then fastens the post coupling reinforcing materials 700; 710 with bolts 780 to combine them.

As shown in FIG. 5A , in order to efficiently manufacture the post coupling reinforcement 700 , two molds 800 formed of an upper plate 810 and a lower plate 820 are used. A hole 831 is processed with a mold in the member 830 of the square plate for forming the post-coupling steel material, and the other mold 800a is used for bending in a desired shape. In this way, mass production is possible at low cost. That is, it may be manufactured by bending it in a desired shape using the bending mold 800a.

In more detail, as shown in FIG. 5b, the upper plate 810a is concave in a semicircular shape so as to fit the member 830 for forming the post coupling reinforcement 700 to the circular shape of the post 310, and the lower plate ( When the 820a) is placed on the mold 800a formed to protrude in a semi-circular shape and bent, the post coupling reinforcement 700 with the hole 831 processed is completed.

As shown in Figures 6a and 6b, the diagonal reinforcement 620 according to the present invention forms a horizontal or bent connection portion 620a by flattening both ends of the circular pipe, and a hole ( 620b) is processed and used. One connecting portion 620a of the diagonal reinforcing material 620 is coupled to the post coupling reinforcing material 700 coupled to the upper end of the post 310 with a bolt 780, and the other connecting portion 620a is of the post 310. Although not shown in the drawing, the structure is coupled to the post coupling reinforcement 700 coupled to the bottom with a bolt 780, coupled to the bottom surface with an anchor 781, or bolted to a floor fixture fixed to the floor.

And the elastic material 730 is provided on both sides of the connection part 620a flatly pressed to both ends of the diagonal reinforcement 620 in contact with the post coupling reinforcement 700 (coating, padding, fitting) to strengthen the friction force. give.

7, the diagonal reinforcement 620 according to the present invention is manufactured by two molds 800b formed of an upper plate 810b and a lower plate 820b. First, the ends of both ends of the diagonal reinforcing material 620 formed as a circular pipe are processed into a mold 800b that flatly forms the connecting portion 620a. A mold is used to round the edges of the flat connection portion while processing the hole 620b on the flat connection portion 620a.

The reason why the edge of the flat connecting part 620a is rounded is that the end of the flat part of the diagonal stiffener 620 is caught on the post when it is combined with the post coupling reinforcing material 700, so it may be difficult to hang it at a desired angle. Because.

As shown in FIG. 8 , the post coupling reinforcement 700 is coupled to the upper end of the post 310 according to the present invention, and the diagonal reinforcement 620 is coupled to the post coupling reinforcement 700 .

The connecting portion 620a of the other side of the diagonal reinforcement 620 should be coupled to the bottom direction. At this time, the combination in the bottom direction can be made into three types.

First, as shown in FIG. 8c , it is a method of combining the pole coupling reinforcement 700 and the bolt 780 coupled to the lower end of the neighboring poles 310 . At this time, in order to increase the seismic performance, it should be installed as low as possible toward the floor.

Second, as shown in Fig. 8a, it is fixed directly to the floor in the direction of the adjacent post 310 or placed on the adjacent post base 311 and fixed to the floor like the post base 311 with an anchor 781. . In this case, it may be directly fixed to the floor instead of the holding base 311 . If necessary, it can be configured by connecting one end of the diagonal reinforcement 620 by coupling the post coupling reinforcement 700 slightly higher from the lower part of the post 310 .

Third, as shown in FIG. 8b , the anchor 781 is first fixed to the bottom of the fixed frame (floor fixture) 500 formed in a square shape on the bottom surface in the direction of the adjacent post 310, and the fixed frame 500 ), after inserting the machined hole (620b) into the connection portion (620a) of the diagonal reinforcement (620) is fixed with a bolt (781).

In addition, as shown in Figure 8d, the horizontal reinforcement 610 for reinforcing the pole 310 and the pole 310 to each other horizontally to the pole coupling reinforcing material 700 coupled to the pole 310 is horizontally connected to each other. . At this time, an elastic material 730 is formed inside the horizontal reinforcement 610 to reinforce the raised floor 1000 .

As shown in FIG. 9A , the horizontal reinforcing material 610 for reinforcing the raised floor 1000 according to the present invention may be used by flattening both ends of a square bar, a 'C'-shaped bar or a round pipe. At this time, in order to facilitate coupling with the post coupling reinforcing material 700, inclined portions are formed at both ends to be inclined.

Both ends of the horizontal reinforcement 610 are coupled to the post coupling reinforcement 700 to exhibit seismic resistance. And an elastic material 730 is provided on the inner surface where the horizontal reinforcing material 610 is coupled to the post coupling reinforcing material 700 (coating, padding, fitting) to strengthen the frictional force.

In addition, as shown in FIG. 9B , the diagonal reinforcing material 620 for reinforcing the raised floor by being diagonally coupled to the posts 310 of the raised floor 1000 is formed of an elastic material 730 on the inner surface of the connecting portion 620a at both ends. One side of the diagonal reinforcing material 620 is coupled to the post coupling reinforcing material 700 and bolt 780 coupled to the upper end of the post 310 by forming a, and the other side of the diagonal reinforcing material 620 is at the lower end of the post 310. Combined with the combined post coupling reinforcement 700 and fixed to the floor with an anchor 781.

As shown in FIGS. 10A and 10B , only the diagonal reinforcement 620 is applied to the raised floor 1000 according to the present invention to enhance the seismic resistance of the entire room. As such, the diagonal reinforcement 620 shows a superior seismic performance compared to the horizontal reinforcement 610, and there are many places where the seismic performance of the raised floor 1000 can be secured only with the diagonal reinforcement 620.

In addition, as shown in Fig. 10c, in the case of a room of 300 m ² or less, it is possible to secure the seismic performance of the National Radio Research Agency 2020-1 even by reinforcing only the edge post 310 of the room, and a higher level of seismic performance is required. In a place or a room of 300 m ² or more, the column 310 is reinforced by selecting additional columns (longitudinal and horizontal) of the post 310 outside the equipment area. This can be done by selecting the number of columns (longitudinal and horizontal) to be additionally reinforced and the position of the column by using the seismic analysis-only program.

11, in order to reinforce the raised floor in the embodiment according to the present invention, the posts 310 can be reinforced by mixing the diagonal reinforcement 620 and the horizontal reinforcement 610, and as shown in FIG. 11a As shown in the upper direction of the horizontal reinforcing material 610 and FIG. 11B , the horizontal reinforcing material 610 can be installed in the lower direction of the post 310 .

12 is another embodiment according to the present invention, in which a horizontal reinforcing material 6100 for reinforcing a raised floor is installed at the bottom and a part of the horizontal reinforcing material 610 is fixed to the floor using an anchor 781. In Fig. 12a As shown, in order to fix the anchor 781 to the floor, a hole 620c is machined in the middle part of the horizontal reinforcement 610 and fixed with the floor and the anchor 781 using the hole 620c, or horizontally It is fixed to the floor with an anchor 781 using a fixing member 630 surrounding the reinforcing material 610 .

In the above, the technical idea of the present invention has been described along with the accompanying drawings, but the preferred embodiment of the present invention is exemplarily described and does not limit the present invention. In addition, it is a clear fact that anyone with ordinary skill in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

300. General double flooring 310. Shore
320. Header 330. Stringer
340. Panel 400. Objects to be protected
500. Fixed structures
600. Post reinforcement 610. Horizontal reinforcement
620. Diagonal stiffener 620a. connection
620b, 620c. Hall 630. Fixture
700. Post bonding reinforcing materials 710, 720. Post bonding reinforcing materials
730. Elastic material 731. Coating
732. Strip 733. Pipe
734. Type C 780. Bolt
781. Anchors 800, 800a, 800b. mold
810, 810a, 810b. Upper mold 820, 820a, 820b. lower mold
1000. Raised floor

Claims (11)

In order to reinforce the raised floor 1000, the post coupling reinforcing material 700 is separated and coupled to the post with bolts 780 while enclosing the post 310, and an elastic material is provided on the inner surface of the post coupling reinforcing material 700. Post reinforcement having an elastic material, characterized in that 730 is provided to strengthen the frictional force between the post coupling reinforcing material 700 and the post 310. The method of claim 1,
The elastic material 730 formed on the inner surface of the post coupling reinforcing material 700 is provided in a coated 731 form, a belt form 732, a pipe form 733, and a C form 734, characterized in that Post reinforcement with elastic material. The method of claim 1,
The post coupling reinforcing material 700 is split in the middle and an elastic material 730 having a shape surrounding the post 310 is inserted into the post 310, and the post coupling reinforcing material 700 is coupled thereon, characterized in that A post reinforcement with an elastic material. The method of claim 1,
The post 310 and the post 310 are horizontally coupled to the horizontal stiffener 610, or the post coupling stiffener 700 coupled to the upper side of the post 310 and the post coupling stiffener coupled to the lower side of the post 310. Post reinforcement having an elastic material, characterized in that the diagonal reinforcement 620 is combined with 700 diagonally, or the horizontal reinforcement 610 and the diagonal reinforcement 620 are combined together to reinforce the post 310. 5. The method of claim 1 or 4, wherein the
The diagonal reinforcing material 620 forms a connection part 620a by flat pressing both ends of the circular pipe using a mold 800, and trimming the edges of the part pressed flat with another mold 800a while cutting A post reinforcement having an elastic material, characterized in that the hole (620b) is processed and the elastic material (700) is provided in the pressed connection portion (620a). 5. The method of claim 1 or 4,
The horizontal reinforcement 610 is a square pipe or a 'C'-shaped hole 620b is processed at both ends of the reinforcement, the horizontal reinforcement 610 and the post coupling reinforcement 700 is in contact with the lower surface of the horizontal reinforcement 610 It is formed of an elastic material (730), and the horizontal reinforcing material (610) and the post coupling reinforcing material (700) are coupled to each other by a bolt (780). 6. The method according to claim 4 or 5,
One side of the diagonal reinforcing material 620 is coupled to the post coupling reinforcing material 700 installed on the upper end of the post 310, and the other side is fixed to the floor with an anchor 781, or a fixed structure 500 fixed to the floor surface. ) and a post reinforcement having an elastic material, characterized in that it is fixed with a bolt (780). According to claim 1 or 2,
The post coupling reinforcing material 700 is manufactured by processing a hole 831 with a mold 800 that makes a hole processing state in the member 830 of a metal square plate, and bending it to a desired shape using a bending mold 800a. Post reinforcement having an elastic material, characterized in that. The method of claim 1,
After combining the post coupling reinforcement 700 to the general raised floor 300, the horizontal reinforcement 610 and the diagonal reinforcement 620 are connected to the post coupling reinforcement to form an earthquake-resistant raised floor having earthquake-resistant performance, characterized in that A post reinforcement with an elastic material. 5. The method of claim 4,
The horizontal reinforcing material 610 is installed in the lower direction of the post 310, and the middle part of some horizontal reinforcing materials 610 is fixed to the floor using an anchor 781 to secure seismic performance. Equipped with post reinforcement. The method of claim 1,
In the case of a raised floor 1000 with an area of 300 m ² or more, a column (row) without equipment is selected through structural analysis and horizontal reinforcement is basically reinforced. Post reinforcement having an elastic material, characterized in that the target seismic performance is achieved by additionally applying (610) and a diagonal reinforcement (620).

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