KR101068077B1 - Combined aseismic structural system for electrical and communication equipments without power interruption and removal - Google Patents

Abstract

Seismic isolator, the upper end of which is connected to the ceiling slab; A connecting plate provided at an upper end of the installed equipment; And a wire sling having one end coupled to a lower end of the seismic isolator and the other end coupled to the connecting plate, wherein the seismic isolator comprises a spring and a viscous damper connected in parallel with the spring. The connecting plate may include a first L-shaped member that forms an upper and lower side surface; A second L-shaped member installed across the first L-shaped member; And a third L-shaped member installed across the second L-shaped member such that two L-shaped members are installed such that their vertical surfaces are adjacent to each other. ; And an activity preventing device provided in a downward direction of the equipment, wherein the activity preventing device comprises: an angle pipe installed at a position where the upper plate supporting the equipment is removed, and an upper end of one end thereof being cut; A connection bracket having one end connected to the equipment and the other end connected to the other end of the tube; An a-shaped member installed across the lower side of the one end of the tube and having a horizontal surface connected to the square tube and a vertical surface connected to a holding rod installed on a bottom slab; A vertical surface is connected to the holding rod and a horizontal surface is connected to the bottom slab L-shaped holding rod anchor bracket; And a support member installed adjacent to the upper plate which is installed on the upper side of the tube and is not removed.

Description

COMBINED ASEISMIC STRUCTURAL SYSTEM FOR ELECTRICAL AND COMMUNICATION EQUIPMENTS WITHOUT POWER INTERRUPTION AND REMOVAL}

The present invention relates to a fall prevention device that is installed in an uninterruptible and non-separable manner, and a composite seismic structure system including the fall prevention device and an activity preventing device, and more particularly, to a double floor structure (Access Floor) By installing the fall prevention device including the seismic isolator, the connecting plate and the wire sling in the upper direction of the equipment with respect to the equipment in operation, to prevent the fall of the equipment by the seismic lateral force, and in the lower direction of the equipment, By installing an activity prevention device including a connection bracket, a-shape reinforcement, an L-shaped holding rod anchor bracket, and a supporting member, it prevents the equipment from being driven by earthquake lateral forces, and also without stopping the equipment or relocating the equipment. The present invention relates to a composite earthquake resistant structural system capable of installing a fall prevention device and the above-described activity preventing device.

Currently, power supply facilities such as switchboards and relay panels, or equipment installed in monitoring panels, distribution panels, communication panels, protection panels, control rooms, communication control lines, control rooms, computer rooms, etc., are double-floor structures with another floor plate installed on the floor of the building. It is intended to be installed at.

Looking at the configuration of the double-bottom structure with reference to Figure 1, first, on the concrete floor slab (3) is a holding rod (4) attached by applying an epoxy adhesive is provided at regular intervals. Stringers 5 are provided in a lattice structure on the support rods 4, support top plates 1 are installed on the stringers 5, and relay panels 2 are installed on the support top plates 1. have. When the equipment and the like installed on the support upper plate 1 are heavy, fix two of the four holes in the support upper plate 1 with anchor bolts, and then cushion pads on the surface of the support upper plate 1. Place the pads and connect the stringers 5 to the holding rods 4 in all directions to fix them with bolts.

Then, the support top plate 1 is assembled in all directions to fit the impact pad grooves, thereby completing. The material of the support top plate 1 mainly used a steel sheet, but recently, polyurethane and a small particle board (Particle Board) integral type that solves the shortcomings of the steel sheet are mainly used.

The overall height of such a conventional double-floor structure is about 20 ~ 40 cm, the basic supporting force of the support top plate is 1.5 tons / m ² , the support force is 3.5 tons / m ² when reinforced with a support rod. Sufficient bearing capacity is provided for equipment weighing approximately 100-800 kg. However, the basic structure of the double-floor structure is that each corner is not a complete fixed end, but a ramen structural formula, which is vulnerable to lateral force or vibration in the event of an earthquake.

In addition, when installing various equipment inside a building or structure to which seismic design is applied, before installing the double-floor structure, make a steel frame according to the size of the supporting plate of the equipment such as the relay panel and anchor it to the slab floor, Then, install the support floor plate over the remaining space to install and assemble the double bottom structure, and install the control cable to assemble the support top plate after the connection work finally to finish the installation. Therefore, there is a problem in that the installation of the conventional double-floor structure is not only cumbersome in construction order, but also requires a large cost to manufacture the steel frame.

In addition, when seismic reinforcement is applied to the double-floor structure as described above, seismic reinforcement is easy for new buildings and newly-installed equipment. There is a problem in that the seismic reinforcement cannot be performed while the equipment is in operation. In addition, in the case of equipment in which the control cable is excessively installed, it is difficult to reinforce the seismic performance because it is difficult to secure an installation space for seismic reinforcement.

The present invention has been made to solve the above problems, an object of the present invention is to install a connection plate on the top of the equipment using a hole provided on the top of the equipment, the top of the equipment of the fall prevention device By installing the rest of the components, it provides a fall prevention device that can reinforce the seismic performance of the equipment in operation in an uninterruptible and non-removable manner.

Another object of the present invention, in addition to the fall prevention device, by installing the activity prevention device in the downward direction of the equipment in which the control cable is excessively installed, it is possible to reinforce the seismic performance in the uninterrupted and non-removable manner for the equipment in operation. To provide a complex seismic structure system.

Anti-conduction device according to the present invention for achieving the above object, the seismic isolator is connected to the ceiling slab top; A connecting plate provided at an upper end of the installed equipment; And a wire sling having one end coupled to a lower end of the seismic isolator and the other end coupled to the connecting plate, wherein the seismic isolator comprises a spring and a viscous damper connected in parallel with the spring. The connecting plate may include a first L-shaped member that forms an upper and lower side surface; A second L-shaped member installed across the first L-shaped member; And a third L-shaped member installed across the second L-shaped member, wherein the two L-shaped members are installed such that their vertical surfaces are adjacent to each other.

The seismic isolator is connected to the ceiling slab via an anchor bracket, and the anchor bracket is a-shaped member.

At least one seismic isolator is installed, and when a plurality of seismic isolators are installed, each seismic isolator is preferably connected in parallel.

The first L-shaped member is fixed to the equipment by bolting in accordance with a hole provided in the equipment.

A fastening hole is formed in a vertical surface of the third L-shaped member, and the wire sling is connected to the connection plate by being connected to the fastening hole.

The wire sling is secured with a clip in the tensioned state.

Composite seismic structure system according to the present invention for achieving the above another object, the fall prevention device is provided in the upper direction of the installed equipment; And an activity preventing device provided in a downward direction of the equipment, wherein the activity preventing device comprises: a square tube installed at a position where a support upper plate supporting the equipment is removed, and an upper end of one end thereof being cut; A connection bracket having one end connected to the equipment and the other end connected to the other end of the tube; A-shaped reinforcement is installed across the lower side of the one end of the tube, the horizontal surface is connected to the square tube and the vertical surface is connected to the holding rod is installed on the bottom slab; A vertical surface is connected to the holding rod and a horizontal surface is connected to the bottom slab L-shaped holding rod anchor bracket; And a support member installed adjacent to the support upper plate which is installed on the upper side of the tube and is not removed.

The connecting bracket is L-shaped, and the connecting bracket and the equipment are connected to each other by bolts being fastened to the bottom channel of the equipment by passing through a vertical surface of the L-shaped connecting bracket, and the connecting bracket and the pipe are connected to the L by the bolt. It is connected to each other by fastening through the other end of the tube passing through the horizontal plane of the connecting bracket of the type.

The connecting bracket is a bending bracket, one end of the bending bracket is connected to the stopper of the lower end of the equipment, the other end of the bending bracket is bolted to the other end of the tube.

The a-shape reinforcement and the tube are connected to each other by fastening the bolt, the a-shape reinforcement and the holding rod is connected to each other by fastening the U bolt.

The vertical surface of the support rod anchor bracket and the support rod are connected to each other by fastening the U bolt, and the horizontal surface of the support rod anchor bracket and the bottom slab are connected to each other by fastening the anchor bolt.

The support member is made of steel sheet.

The present invention is to install the connecting plate on the top of the equipment using a hole (especially, eye bolt hole) that originally existed on the top of the equipment, by fixing a wire sling on the connecting plate without installing a separate device fixing device The equipment can be secured to the fall prevention device. Thus, not only the manufacturing cost can be reduced, but the seismic performance can be reinforced without stopping or relocating the equipment in operation.

In addition, the seismic isolator with spring and viscous dampers connected in parallel to each other is fixed to the ceiling slab instead of directly fixing the equipment to the ceiling slab, thereby reducing the earthquake response and reducing the seismic force on the equipment to prevent the equipment from falling. Can be.

Moreover, the effect of reducing vibration is secured by fixing a wire sling with a clip in a state where prestress is applied tightly.

In addition, even if the control cable of the equipment installed and operating in the double-floor structure is excessively installed, when the work space for seismic reinforcement is insufficient, by using the space to remove the support top plate by installing the activity prevention device according to the present invention earthquake In addition to resisting lateral forces, seismic performance can be augmented without stopping or relocating equipment.

Figure 1 schematically shows a double bottom structure according to the prior art.
2 is a schematic cross-sectional view of a state in which a composite earthquake resistant rescue system including an anti-fall device and an anti-activity device according to an embodiment of the present invention is applied to equipment.
Figure 3 schematically shows a side view of a state in which the anti-conduction device according to an embodiment of the present invention is applied to the equipment.
4 schematically illustrates a plan view of a connecting plate according to an embodiment of the present invention.
5a and 5b schematically show the connection state of the square tube, a-shape reinforcement, holding rods, holding rod anchor bracket according to an embodiment of the present invention.
Figure 6 schematically shows a side view of a state in which the activity prevention device according to an embodiment of the present invention is applied to the equipment.
Figure 7 schematically shows a connection state of the connection bracket and the tube according to another embodiment of the present invention.
8 schematically illustrates a state in which two seismic isolators according to the present invention are installed.

The composite earthquake resistant structural system including the fall prevention device and the active restraint device installed in an uninterruptible and non-separable manner according to the present invention is largely divided into the following nine members, and each member is welded or rigidly assembled.

1. Anchor bracket: A type member, preferably made of steel. Connect the horizontal plane to the ceiling slab and the vertical plane to the seismic isolator.

2. Seismic isolator: It is composed of spring and viscous damper in parallel. It adjusts the natural frequency of equipment to deviate from the earthquake's excellent period and absorbs the shock of seismic wave to reduce displacement.

3. Connecting plate: A structure assembled as an L-shaped member, preferably made of steel, and connecting the equipment to a wire sling.

4. Wire sling: one end is connected to seismic isolator and the other end is connected to connecting plate.

5. Connecting bracket: L-shaped member, preferably made of steel, which connects the bottom channel or stopper of the equipment with the tube.

6. Tube: One end is fastened to the a-shape reinforcement and the other end is fastened to the connection bracket to fix the equipment so that the equipment does not work in the event of an earthquake.

7. Type A stiffeners: The holding rods are connected to each other to prevent the holding rods from falling over.

8. Shoring Rod Anchor Bracket: An L-shaped member, preferably made of steel, which holds the shoring rod so that it does not escape from the floor slab.

9. Support plate: Steel plate, used as a passageway for transporting workers or equipment.

Hereinafter, the present invention will be described in more detail with reference to Examples, but the scope of the present invention is not limited to the following Examples.

Prior to the description of the present invention, "equipment" in the present specification refers to a switchboard, a relay panel, a control panel, a monitoring panel, a communication / control line of a situation room or a control room, a computer, and the like. Obviously, the various equipment mentioned can be applied to the present invention.

2 is a schematic cross-sectional view of a state in which a composite earthquake resistant rescue system including an anti-fall device and an anti-activity device according to an embodiment of the present invention is applied to equipment.

Referring to FIG. 2, the composite seismic rescue system 1000 according to the present invention includes a fall prevention device 100 and an activity prevention device 200. The fall prevention apparatus 100 is installed in an upper direction of the switchboard 10, and the activity preventing device 200 is installed in a lower direction of the switchboard 10.

Referring to FIG. 3 and FIG. 2 illustrating a state in which an anti-conduction device according to the present invention is applied to equipment, the anti-conduction device 100 includes an earthquake isolation device 110, a connection plate 120, and Wire sling 130. The seismic isolator 110 includes a spring 111 and a viscous damper 112 connected in parallel to each other, the upper end of the seismic isolator 110 is connected to the ceiling slab (20). More specifically, the upper end of the seismic isolator 110 is connected to the ceiling slab 20 via the anchor bracket 140, the anchor bracket 140 is a-shaped member, the horizontal plane of the anchor bracket 140 The anchor bolt 141 is fastened to the ceiling slab 20 and fixed to the vertical surface 142 of the anchor bracket 40 via the shackle 113 and the eye bolt 114 of the seismic isolator 110. The upper end is fastened.

On the other hand, the lower end of the seismic isolator 110 is connected to the wire sling 130 via the eye bolt 115 and the shackle 116.

In the present embodiment, one seismic isolator is provided, but in another alternative embodiment, a plurality of seismic isolators may be installed. In addition, at least one anchor bracket may be installed.

The connecting plate 120 is provided at an upper end of the switchboard 10 in operation. Referring to FIG. 4, which is a plan view of a connecting plate according to an embodiment of the present invention, with reference to FIGS. 2 and 3, the connecting plate 120 has a first L-shaped member 121 forming upper and lower surfaces thereof. A second L-shaped member 122 is installed across the first L-shaped member 121, and the second L-shaped member 122 is installed across the two L-shaped members, the vertical surfaces of which are adjacent to each other. It is provided with a third L-shaped member 123 which is installed to be.

The first L-shaped member 122 is fixed to the switchboard 10 by bolting to a hole already provided in the switchboard 10, in particular, an eye bolt hole 30. A fastening hole 124 is formed on the vertical surface of the third L-shaped member 123, and the wire board 10 is connected to the fastening hole 124 through the eye bolt 117. It is fixed to the fall prevention apparatus 100. Therefore, according to the present invention, it is possible to fix the equipment to the fall prevention device without installing a separate equipment fixing device to reduce the production cost, and to improve the seismic performance without stopping or relocating the equipment in operation. I can reinforce it.

One end of the wire sling 130 is coupled to the lower end of the seismic isolator 110, the other end is coupled to the connecting plate 120. The wire sling 130 is secured by the clip 131 in the tensioned state to reduce the vibration.

As described above, according to the present invention, the seismic response acting on the equipment can be greatly reduced by fixing the equipment to the ceiling slab through the fall prevention device without directly fixing the equipment to the ceiling slab. Seismic isolator equipped with a damper is fixed to the ceiling slab to reduce the earthquake response to reduce the earthquake force on the equipment to prevent the fall of the equipment.

Next, the activity prevention device will be described.

5a and 5b schematically show the connection state of the square tube, a-shape reinforcement, holding rods, holding rod anchor bracket according to an embodiment of the present invention. Figure 6 schematically shows a side view of a state in which the activity prevention device according to an embodiment of the present invention is applied to the equipment.

2, 5a, 5b and 6, the activity prevention device 200 is a square tube 210, connecting bracket 220, a-shape reinforcement 230, holding rod anchor bracket 240 and support member 250 Include.

The tube 210 is installed at a position where the support top plate 40 supporting the switchboard 10 is partially removed. As shown in FIGS. 5A and 5B, one end of the tube 210 is cut at an upper end thereof. This is to facilitate the bolt coupling with the a-shaped reinforcement 230 to be described later when the seismic reinforcement work.

The connecting bracket 220 is L-type, one end thereof is connected to the switchboard 10, specifically, the bolt 221 is passed through the vertical plane of the L-shaped connecting bracket 220 of the switchboard 10 ) Is fastened to the bottom channel 12. The other end of the connection bracket 220 is connected to the corner tube 210 by fastening the bolt 222 through the other end of the corner tube 210 through the horizontal plane of the L-shaped connection bracket 220.

Referring to FIG. 7 schematically illustrating a connection state between a connection bracket and a tube according to another embodiment of the present invention, the connection bracket 220 is a bending bracket 220 'and one end of the bending bracket 220'. Is connected to the stopper 14 of the lower end of the switchboard 10, the other end of the bending bracket 220 'is bolted to the other end of the tube 210.

Referring back to Figures 2, 5a, 5b and 6, the a-shape reinforcement 230 is installed across the lower side of the one end of the square tube (210). Specifically, the bolt 231 is fastened to the horizontal surface of the a-shape reinforcement 230 and the square tube 210, the holding rod 60 is installed on the vertical surface and the bottom slab 50 of the a-shape reinforcement 230. ) U bolt 232 is fastened. Thus, the a-shape reinforcement 230 is connected to each tube 210, each holding rod 60 is connected to each other.

The L-shaped holding rod anchor bracket 240 is vertically fastened with the holding rod and the U bolt 241, and the horizontal surface is fastened with the anchor bolt 242 to the bottom slab 50.

The support member 250 is a steel sheet, which is installed on the upper side of the square tube 210 and adjacent to the support upper plate 40 that is not removed. The support member 250 is intended to facilitate the passage of the operator or equipment transport.

As described above, according to the present invention, even when the control cable of the equipment installed and operated in the double-floor structure is excessively installed, and the work space for seismic reinforcement is insufficient, the activity according to the present invention is utilized by utilizing the space from which the support top plate is removed. By installing the prevention device, it is possible not only to resist seismic lateral force, but also to enhance the seismic performance without stopping the equipment or moving the equipment.

Hereinafter, the process of installing the fall prevention device and the activity preventing device constituting the composite seismic structure system according to the present invention will be described with reference to the drawings.

First, referring to Figures 2 to 4, look at the installation process of the fall prevention device.

The upper end of the switchboard 10 is provided with an eye bolt hole 30. The eye bolt hole 30 is used at the time of relocation of the switchboard 10. In general, the eyebolt hole 30 is formed in the switchboard 10. The worker installs the connecting plate 120 at the upper end of the switchboard 10 by bolt-fitting the first L-shaped member 121 of the connecting plate 120 to the eye bolt hole 30. Then, the anchor bolt 140 is fastened to the ceiling slab 20 by fastening the anchor bolt 142 to the horizontal surface of the anchor bracket 140. Then, the eye bolts 114 and 115 are fastened to the upper and lower ends of the seismic isolator 120 in which the spring 111 and the viscous damper 112 are connected in parallel, and the upper eye bolt 114 is the shackle 113. Connected to the anchor bracket 140 via the, eyebolt 115 at the bottom is connected to one end of the wire sling 130. The other end of the wire sling 130 is fixed to the fastening hole 124 provided in the third L-shaped member 123 of the connecting plate 30 via the eye bolt 117 to fix the wire sling 130. It is fixed by the clip 131 in the prestressed state by pulling taut.

Through the installation work of the fall prevention apparatus according to the present invention, the running switchboard can be reinforced with seismic performance without having to be stopped or moved. And it is possible to prevent conduction of the switchboard due to the seismic lateral force.

Next, the process of installing the activity preventing device will be described with reference to the drawings.

2, 5a, 5b and 6, the control cable 70 is excessively laid in the lower portion of the support top plate 40 in which the switchboard 100 is located. The portion of the support plate 40 is not cut by removing the switchboard is located. The corner tube 210 is positioned by providing a space into which the corner tube 210 can be inserted. Drill a hole in the bottom channel 12 of the switchboard 10 and screw out one end of the connection bracket 220 to the bottom channel 12 of the switchboard 10 with the horizontal bolt 221, and the connection bracket 220. The other end of the vertical bolt 222 and the nut is fastened to the tube 210 by fastening.

The a-shape reinforcement 230 is positioned directly below the corner pipe 210, and then the bolt 231 is fastened to connect with the corner pipe 210, and the support rod 60 by fastening the U-shaped bolt 232 to the support rod ( 60).

On the other hand, the anchor rod 60 is fastened to the bottom slab 50 by fastening the anchor bolt 242 to the horizontal surface of the L-shaped anchor rod anchor bracket 240 so as not to be separated during an earthquake. The U-shaped bolt 241 is fastened.

Then, after the above operation is completed, the support member 250 made of steel sheet is installed adjacent to the support top plate which is not removed at the same height as the height of the existing double bottom structure.

Thereby, seismic performance can be reinforced without stopping or moving the switchboard in operation in which the control cable is excessively installed. In addition, it is possible to prevent activity of the switchboard due to the seismic lateral force.

While specific embodiments of the present invention have been described above, the present invention is not limited to the above-described specific embodiments, and the technical field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Anyone of ordinary skill in the art can make various modifications, as well as such modifications are within the scope of the claims.

10: switchboard 12: bottom channel
14: stopper 20: ceiling slab
30: hole 40: support top plate
50: floor slab 60: holding rod
70: control cable 100: fall prevention device
110: seismic isolator 111: spring
112: viscous damper 113, 116: shackle
114, 115, 117: i-bolt 120: connecting plate
121: first L-shaped member 122: second L-shaped member
123: third L-shaped member 124: fastening hole
130: wire sling 134: clip
200: activity prevention device 210: corner
220: connection bracket 220 ': bending bracket
230: a-shape reinforcement 240: holding rod anchor bracket
250: support member 1000: composite earthquake resistant structural system

Claims (12)

Seismic isolator, the upper end of which is connected to the ceiling slab;
A connecting plate provided at an upper end of the installed equipment; And
And a wire sling having one end coupled to a lower end of the seismic isolator and the other end coupled to the connection plate.
The seismic isolator is provided with a spring and a viscous damper connected in parallel to the spring,
The connecting plate may include a first L-shaped member that forms an upper and lower side surface; A second L-shaped member installed across the first L-shaped member; And a third L-shaped member installed across the second L-shaped member such that two L-shaped members are installed such that their vertical surfaces are adjacent to each other. . The apparatus of claim 1, wherein the seismic isolator is connected to the ceiling slab via an anchor bracket, and the anchor bracket is an a-shaped member. The method of claim 1, wherein at least one seismic isolator is installed, and when the plurality of seismic isolators are installed, each seismic isolator is connected in parallel. Prevention device. The apparatus of claim 1, wherein the first L-shaped member is fixed to the equipment by being bolted to a hole provided in the equipment. The method of claim 1, wherein a fastening hole is formed in a vertical surface of the third L-shaped member, and the wire sling is installed in an uninterruptible and non-separable manner by being connected to the connection plate by being connected to the fastening hole. Fall prevention device. The apparatus of claim 1, wherein the wire sling is fixed by a clip in a tensioned state. An anti-conduction device according to any one of claims 1 to 6, which is provided in an upward direction of the installed equipment; And
Includes; the activity prevention device provided in the downward direction of the equipment,
The activity preventing device, the pipe is installed in a position where the support top plate for supporting the equipment is removed, the upper end of one end is cut; A connection bracket having one end connected to the equipment and the other end connected to the other end of the tube; A-shaped reinforcement is installed across the lower side of the one end of the tube, the horizontal surface is connected to the square tube and the vertical surface is connected to the holding rod is installed on the bottom slab; A vertical surface is connected to the holding rod and a horizontal surface is connected to the bottom slab L-shaped holding rod anchor bracket; And a support member installed adjacent to the support upper plate which is installed on the upper side of the pipe and is not removed, wherein the seismic structure system is installed in an uninterruptible and non-separable manner. The connecting bracket and the equipment are connected to each other by a bolt is fastened to the bottom channel of the equipment through a vertical surface of the L-shaped connecting bracket, the connection bracket and the equipment. Each pipe is connected to each other by a bolt is fastened through the other end of the pipe passing through the horizontal plane of the L-shaped connection bracket, the seismic structure structure is installed in an uninterruptible and no relocation system. The uninterruptible power supply according to claim 7, wherein the connection bracket is a bending bracket, one end of the bending bracket is connected to a stopper of the lower end of the equipment, and the other end of the bending bracket is bolted to the other end of the tube. And a seismic structure system installed in a snowless manner. According to claim 7, wherein the a-shape reinforcement is connected to each other by fastening the square tube and the bolt, the a-shape reinforcement and the holding rods are connected to each other by the U bolt is fastened, the composite is installed in an uninterruptible and no relocation method Seismic rescue system. The vertical surface of the holding rod anchor bracket and the holding rod are connected to each other by fastening U bolts, and the horizontal surface of the holding rod anchor bracket and the bottom slab are connected to each other by fastening anchor bolts. Complex seismic rescue system installed in uninterruptible and non-separable manner. 8. The composite seismic structure system according to claim 7, wherein the supporting member is made of a steel sheet.

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