KR101230056B1 - Moving Floor Structure for Seismic Isolation - Google Patents

Abstract

The present invention relates to a seismic isolation technology that protects equipment installed in a building when an earthquake occurs, and more particularly, by installing a movable floor supported by steel balls on an existing building floor, even if the building vibrates greatly due to an earthquake. Is faced with a seismic movable floor structure that can relatively vibrate and safely protect the equipment installed on it.
Even if the building structure vibrates largely due to the earthquake, the movable floor on which the equipment is mounted does not vibrate or vibrates with a very small amplitude to safely protect the equipment mounted thereon, and the structure is simple. Components can be manufactured in large quantities and inexpensively, and are prefabricated and easy to install in a building. In addition, the seismic isolating movable floor of the present invention adopts a ball surface seismic bearing, which can not only absorb the large vibration generated when an earthquake occurs, but also can support a large load so that expensive equipment such as computer equipment and control equipment can be removed from the earthquake. Suitable for protection

Description

Movable Floor Structure for Seismic Isolation

The present invention relates to a seismic isolation technology that protects equipment installed in a building when an earthquake occurs, and more particularly, by installing a movable floor supported by steel balls on an existing building floor, even if the building vibrates greatly due to an earthquake. Is faced with a seismic movable floor structure that can relatively vibrate and safely protect the equipment installed on it.

Generally, the term “isolating” separates the entire building structure from the ground or separates a specific part of the building structure from the building structure, so that the building structure or building is separated from the ground even if the ground or building structure vibrates greatly when an earthquake occurs. Part of a building separated from the structure means relatively little vibration to protect the building structure or equipment installed on a part of the building from earthquakes.

On the contrary, "earthquake-resistant" means that the structure itself is firmly designed so that the structure does not collapse even when an earthquake occurs and the structure such as a building, a bridge, or the like vibrates significantly.

Recently, as facilities are automated and tasks are computerized, expensive control equipment or computing equipment is installed and operated in factories, office buildings, etc., as shown in FIG. 1, supporting structures are installed on the floor of the building and deck floors on the supporting structures. After forming the double floor by installing the control equipment or computing equipment is installed on the deck floor. Various cables such as wires, signal cables, and communication lines pass through the deck floor structure to the space between the floor and the deck floor.

Ordinary control equipment or computer equipment is manufactured in a cabinet shape in order to save space, the floor is narrow and the height is high, such narrow and high objects can be easily overturned when the building vibrates due to the earthquake. As such, when the control equipment or the computer equipment is overturned by an earthquake, the equipment itself may be damaged and become unusable. However, as these equipments are overturned, other important facilities or devices may be damaged to further spread the damage. Therefore, these control equipment or computer equipment should be installed in the place where isolating design is essential.

Large structures, such as buildings and bridges, have specially designed seismic bearings between the substructures and the foundational structures formed on the ground, so that structures supported by the seismic bearings are relatively less vibrated even if the ground vibrates greatly due to an earthquake. This mainly applies.

In Korean Patent Nos. 10-0409274, 10-0316196, 10-0469520, 10-0608230, etc., there are posted seismic bearings used for seismic isolation of such a large structure, and these seismic bearings are mostly rubber layers and steel plates. It is a structure in which layers are alternately stacked in multiple layers and is used where a very large vertical load is applied, such as a building or a large structure.

In the seismic isolation structure of the access floor, a floor plate is supported by a plurality of supports, an earthquake-proof cover with an elastic body is fitted at the end of the floor plate, and a support portion having a roller is installed at the bottom of the support plate, and each support is provided. The lower part is posted with an access floor having a structure connected to each other by an X using a lower reinforcement material.

However, the seismic isolation structure of the access floor is limited in its ability to absorb large vibrations due to the small displacement of the seismic cover, and it is difficult to manufacture since rollers are provided at the bottom of all supports, and the rollers at the bottom of the support are Has a structure that supports all the loads of the equipment mounted on the access floor, so there is a problem that it is difficult to be practical as a structure that is difficult to support a large load.

As described above, the seismic isolator bearings commonly used in seismic isolation design can be used for seismic isolation of large structures such as buildings and bridges, and are not suitable for the seismic isolation design of equipment or facilities such as control equipment or computerized equipment. Conventional isolating access floor that can be applied to the seismic isolation design of the facility is difficult to be practical due to various problems.

Therefore, it can be applied to the seismic design of equipment such as control equipment or computer equipment, and its structure is simple and easy to manufacture, it is easy to install, it can absorb the large vibration generated when an earthquake occurs, and A seismic floor structure capable of supporting a load is required.

In order to solve the technical problem as described above, the base isolation movable floor of the present invention is installed on the bottom of the lower frame (1), which is fixed in a row in a row to form a plurality of rows, each of the lower frame (1) as The upper frame (2) installed to face the lower frame (1), the ball bearing surface (3) is installed between the lower frame (1) and the upper frame (2), put on the upper surface of the upper frame (2) Deck frame (4) to be fixed by fixing, and deck plate (5) to be fixed to the upper surface of the deck frame (4) successively to form a bottom.

When the earthquake occurs and the building structure vibrates with the ground, the lower frame 1 fixed to the floor of the building vibrates with the building structure. At this time, the ball bearing bearing 3 absorbs the horizontal displacement of the vibration caused by the earthquake as the ball intervening between the lower block and the upper block rolls. Therefore, even if the lower frame 1 fixed to the floor of the building due to an earthquake vibrates greatly with the building structure, the deck frame 4 on which the heavy equipment is mounted and the upper frame 2 on which the deck plate 5 is fixed are Inertia does not vibrate or vibrates at very small amplitudes, so that the equipment mounted on it is safely protected.

Even if the building structure vibrates greatly due to an earthquake, the base-floor movable floor of the present invention does not vibrate or vibrates with a very small amplitude to safely protect the equipment mounted thereon.

In addition, the seismic isolating movable floor of the present invention is simple in structure and can be produced in a large amount of components inexpensively, it is easy to be installed in the building is prefabricated. In addition, the seismic isolating movable floor of the present invention adopts a ball surface seismic bearing, which can not only absorb the large vibration generated when an earthquake occurs, but also can support a large load so that expensive equipment such as computer equipment and control equipment can be removed from the earthquake. Suitable for protection

1 is a conventional deck floor structure in which the control equipment or computer equipment is installed.
2 is an overall configuration diagram of a base isolation movable floor of the present invention.
3 is a detailed configuration diagram of the lower frame.
Figure 4 is a cross-sectional view of the ball bearing face mounting portion.
5 is a configuration diagram of the deck frame.
6 is a cross-sectional view of the deck frame coupling portion.

As shown in FIG. 2, the base isolation movable floor of the present invention is installed on an upper portion of each of the lower frames 1 and the lower frame 1 which is fixed in a row on the floor of the building to form a plurality of rows. The upper frame (2) is installed facing the frame (1), the ball bearing surface (3) is installed between the lower frame (1) and the upper frame (2), fixed on the upper surface of the upper frame (2) It is composed of a deck frame (4), and a deck plate (5) which is successively fixed to the upper surface of the deck frame (4) to form a bottom.

As shown in Figure 3, the lower frame (1) is made of a certain length of the channel 11, which is made by folding the steel plate of a certain thickness so as to have a c-shaped cross section, and is attached to one end of the channel (11) A connecting plate 12 having a coupling protrusion 121 formed at one side thereof, and a coupling groove 131 to which the coupling protrusion 121 of the connecting plate 12 is inserted, is attached to the other end of the channel 11. The coupling plate 13 and the connecting plate 12 and the coupling plate 13 is composed of a fixing plate 14 for fixing them by using a fixing screw 16.

The connecting plate 12 may be formed with a hole 122 in the center so as to reduce the weight and facilitate the coupling with the connecting plate 12. The connecting plate 12 and the coupling plate 13 are preferably attached to the channel 11 by welding, and the fixing plate 14 and the ball face true bearing 3 are fixed to the connecting plate 12 and the coupling plate 13. Screw holes 123 and 132 are formed therein.

Between the connecting plate 12 and the coupling plate 13 respectively attached to both ends of the channel 11, it is good to attach the reinforcing bar 15 along the center line of the channel, the reinforcing bar 15 is a square rod or c- It is good to make a magnetic channel and attach it to the bottom surface of the channel 11 by welding.

The lower frame 1 manufactured as described above couples the connecting plate 12 of one lower frame 1 to the coupling plate 13 of the other lower frame 1, and is coupled to the connecting plate 12. The coupling part of the plate 13 is fixed by the fixing plate 14 using the fixing screw 16. In this way, the plurality of lower frames 1 connected in series are fixed to the floor of the building in a plurality of rows at regular intervals.

The upper frame 2 has the same shape as the lower frame 1 and is installed to face the lower frame 1 on the upper portion of the lower frame 1, respectively, and is long in the same manner as the lower frame 1. Connected.

Ball face true bearing (3) is installed between the lower frame (1) and the upper frame (2), as shown in the cross-sectional view of Figure 4, the lower frame as a conical ball seat 311 is formed on the upper surface Lower block 31 coupled to the connecting plate 12 of (1), the upper shape coupled to the lower block 31 to the connecting plate of the upper frame 2 in the same shape as the lower block 31 The block 32 and the lower block 31 and the ball 33 placed on the ball seat 311 of the upper block 32 facing each other.

The lower block 31 and the upper block 32 is formed with a rim 312, the fixing hole 313 is formed in the rim 312, the lower block 31 and the upper block with a fixing screw 34 It is preferable to be able to couple the 32 to the connecting plate 12 of the lower frame 1 and the upper frame 2, respectively. The ball 33 is a steel ball of a certain diameter is used.

The deck frame 4 is a hexahedral frame structure as shown in FIG. 5, and is fixed successively over two upper frames 2 forming a row adjacent to each other. The upper surface of the deck frame (4) is preferably provided with a grating structure fixing member 41 having a predetermined spacing in each of the horizontal and vertical so as to fix the deck plate (5) of a predetermined size.

As shown in FIG. 2, the deck frame 4 is successively installed on the upper surfaces of the two upper frames 2 adjacent to each other, and the lower frames of the two deck frames 4 adjacent to each other are shown in the cross-sectional view of FIG. 6. As described above, the fixing bracket 43 is fixed to the upper surface of the upper frame 2 by one fixing bracket 42.

 The deck plate 5 is a rectangular plate of a predetermined size, and is made of a plate such as a metal plate, a synthetic resin, a wood plate, plywood, and is successively fixed to the upper surface of the deck frame 4 to form a bottom. The upper surface of the floor formed of the deck plate (5) is equipped with equipment such as control equipment, computer equipment.

As described above, the floor formed of the deck plate 5 fixedly connected to the deck frame 4 is a movable floor which can be moved separately from the floor of the building by the ball bearings 3.

An anchor wire 6 may be installed between the lower frame 1 and the upper frame 2. The anchor wire 6 has a fixing portion 62 having a fixing hole formed at both ends of the wire rope 61 of a predetermined thickness, and one end of the anchor wire 6 is fixed to the channel 11 of the lower frame 1. The other end is fixed to the channel of the upper frame (2) with a fixing screw (63).

If the length of the wire rope 61 of the anchor wire 6 is sufficient, the wire rope becomes taut when the large amount of relative deformation between the lower frame 1 and the upper frame 2 occurs due to an earthquake. Since the relative displacement between the (1) and the upper frame 2 is restrained, the lower block 31 and the upper block 32 are not separated from each other in the spherical surface bearing 3 and are safe.

Operation of the base isolation movable floor configured as described above is as follows.

When the earthquake of the present invention occurs and the building structure vibrates greatly with the ground, the lower frame 1 fixed to the floor of the building vibrates with the building structure. At this time, the ball surface vibration bearing 3 absorbs the horizontal displacement of the vibration caused by the earthquake as the ball 33 interposed between the lower block 31 and the upper block 32 rolls. Therefore, the deck frame (4) and the deck plate (5) on which the heavy equipment is mounted is fixed to the upper frame (2) does not vibrate by inertia or vibration at a very small amplitude.

If the anchor wire 6 is installed between the lower frame 1 and the upper frame 2, the anchor wire 6 is excessively extended between the lower frame 1 and the upper frame 2 when a large earthquake occurs. It is safe by preventing relative displacement.

1: lower frame, 2: upper frame, 3: ball bearing,
4 deck frame, 5 deck plate, 6 anchor wire,
11: channel, 12: connecting plate, 13: bonding plate, 14: fixing plate,
15: reinforcing rod, 16: fixing screw,
31: lower block, 32: upper block, 33: ball, 34: fixing screw
41: fixing member, 42: fixing bracket, 43: fixing screw,
61: wire rope, 62: fixing part, 63: fixing screw.

Claims (6)

As a series of fixed to the floor of the building to form a plurality of rows, a certain length of the channel 11, which is made by folding the steel plate of a certain thickness so as to have a c-shaped cross-section, attached to one end of the channel (11) The coupling plate 12 having the coupling protrusion 121 formed on one side of the rectangular plate, and the coupling groove 131 to which the coupling protrusion 121 of the connecting plate 12 is inserted as being attached to the other end of the channel 11. Is formed of a coupling plate 13, and the connecting plate 12 and the coupling plate 13 is composed of a fixed plate 14 for fixing them after coupling the plurality of lower frames (1);
A plurality of upper frames (2) having the same shape as the lower frame (1) and installed on the lower frame (1) to face the lower frame (1), respectively;
The lower block 31 is installed between the lower frame 1 and the upper frame 2, and the conical ball seat 311 is formed on the upper surface and is coupled to the connecting plate 12 of the lower frame 1. The upper block 32 is coupled to face the lower block 31 to the connecting plate of the upper frame 2 in the same shape as the lower block 31, and the lower block 31 and the upper surface facing each other. Ball face true bearing 3, consisting of a ball 33 placed on the ball seat 311 of the block 32.
A six-sided frame structure that is raised and fixed on an upper surface of the upper frame (2), the deck frame (4) is successively fixed over two upper frames (2) forming a row adjacent to each other;
And, the deck plate (5) to be successively fixed to the upper surface of the deck frame (4) to form a bottom;
It is configured to include, a base isolation movable floor structure. According to claim 1, wherein the base isolation movable floor structure,
It is installed between the lower frame (1) and the upper frame (2), the fixing portion 62 is formed with a fixing hole at both ends of the wire rope 61 of a certain thickness, each of the two fixing portions 62 In addition, the lower frame (1) and the upper frame (2) is further provided with an anchor wire (6) that is fixed by a fixing screw (63), the anchor wire (6) is the lower frame (1) and the upper frame when an earthquake occurs A seismic isolating movable floor structure, characterized in that it restrains excessive relative displacement from occurring. The method of claim 1,
The deck frame (4), the upper surface has a fixed structure 41 of the grid structure having a constant interval, respectively horizontally and vertically, characterized in that the structure is easy to successively fix the deck plate (5) of a constant size , Base isolation operation floor structure. The method of claim 1,
The connecting plate 12 of the lower frame 1, characterized in that the hole 122 is formed in the center in order to reduce the weight and facilitate the coupling plate 13, the base isolation movable floor structure. The method of claim 1,
The lower block 31 and the upper block 32 of the ball face true bearing 3 form a rim 312 around the site where the ball seat 311 is formed, and a fixing hole 313 in the rim 312. ) To form the lower block 31 and the upper block 32 to be coupled to the connecting plate 12 of the lower frame 1 and the upper frame 2 using fixing screws 34, respectively. The base isolation movable floor structure characterized by the above-mentioned. The method of claim 1,
The deck frame (4) is characterized in that the lower frame of two adjacent deck frames adjacent to each other is fixed to the upper surface of the upper frame (2) by a fixing screw (43), a base isolation movable floor structure .

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