KR20120132896A - Earthquake Proof Apparatus for a Structure - Google Patents

Abstract

PURPOSE: A quakeproof device is provided to reduce horizontal force actuating on a structure by allowing the movement to a horizontal direction, thereby improving earthquake-resistant performance. CONSTITUTION: A quakeproof device(100) comprises a lower plate(1), an upper plate(3), an outer cylinder(4), an inner cylinder(5), a cover(6), a top plate(8), and a shock-absorbing piston(7). The lower plate is fixed to the ground. The upper plate is laminated by interposing a plurality of steel balls on the lower plate. The outer cylinder is arranged on the upper plate and formed into a hollow cylinder. The inner cylinder has vertical length shorter than vertical length of the outer cylinder. The cover is formed to be integrated with the inner cylinder, thereby closing the upper part of the inner cylinder. The top plate is arranged on the cover and has width same with the diameter of the outer cylinder. The shock-absorbing piston comprises a cylindrical body(72) possible to move up and down by being touched to an inner periphery of the inner cylinder.

Description

Earthquake Proof Apparatus for a Structure}

The present invention relates to an earthquake-resistant device, and more particularly, to protect the structure by reducing the vibration in the horizontal and vertical direction during the earthquake by the steel ball interposed between the upper plate and the lower plate and the buffer piston interposed in the inner and outer cylinders. It relates to a seismic device.

Structures such as bridges and buildings should have sufficient stability against natural phenomena such as earthquakes, strong winds and heavy rain. These days, safety against earthquakes is particularly important.

The seismic waves generated by the earthquake are largely divided into a body wave and a surface wave. The real wave is a wave that passes through the interior of the crust and is a P wave (primary wave) with the same direction of movement and movement of the medium, and an S wave (secondary wave) with perpendicular direction of movement and the movement of the medium. have. In addition, since surface waves are transmitted along the surface of the earth, an earthquake causes great damage.

Therefore, the present invention improves the seismic performance by reducing the horizontal force acting on the structure by receiving the movement in the horizontal direction, and also minimizes the vertical vibration of the structure due to the deformation in the vertical direction to the structure when the earthquake occurs The aim is to minimize the damage.

In order to solve the above object, the present invention is a plate-shaped lower plate is fixed on the ground; An upper plate having a cylindrical shape formed on the lower plate via a plurality of steel spheres and having a cylindrical guide pillar formed in a vertical direction at the center of the upper surface; A cylindrical outer cylinder provided on the upper plate and having an empty interior; An inner hollow cylinder having a vertical length, which may be moved up and down in contact with an inner circumference of the outer cylinder, and having a vertical length smaller than the vertical length of the outer cylinder; A circular cover integrally formed with the inner cylinder to cover an upper portion of the inner cylinder; A top plate provided on the cover and having a width equal to the diameter of the outer cylinder; And a cylindrical body that can be moved up and down in contact with the inner circumference of the inner cylinder, a protrusion projecting from the center of the upper surface of the body to the bottom of the cover, and the outer circumference of the cylindrical guide pillar at the bottom of the body. An earthquake-resistant device comprising: a shock absorbing piston having a hollow cylindrical sliding column that can be moved up and down in contact with the inner cylinder, wherein a first coil spring is provided to surround the sliding pillar under the body of the shock absorbing piston. And a second coil spring having a diameter larger than the diameter of the first coil spring under the inner cylinder 5 and surrounding the circumference of the first coil spring, and having air in the outer cylinder at a lower portion of the outer cylinder. A first air inlet for introducing air and a first air outlet for discharging air from the inside of the outer cylinder to the atmosphere; The cover, a second air inlet for introducing air into the space formed by the inner cylinder and the body and a second air outlet for discharging air from the space to the atmosphere is formed, the ring-shaped first air cushion top It is formed to surround the side of the plate and the upper side of the outer cylinder at the same time, the ring-shaped second air cushion is formed to surround the outer periphery of the outer cylinder, the ring-shaped third air cushion is the side and the lower portion of the upper plate Characterized in the seismic device is formed to surround the side of the plate at the same time.

In addition, the present invention is characterized in that the seismic device is formed in the outer ring of the inner cylinder in contact with the inner ring of the outer cylinder, the circumference of the body of the cushioning piston, and the circumference of the guide pillar, respectively.

In addition, in the present invention, the circular hollow portion includes a rectangular spacer formed at a predetermined interval, the plurality of steel spheres is characterized in that the seismic device inserted into the hollow portion.

According to the earthquake resistance device of the present invention as described above, the first coil spring, the second coil spring and the inner coil to accommodate the horizontal displacement acting on the structure by the steel sphere interposed between the upper plate and the lower plate and By the buffer piston it is possible to minimize the vibration in the vertical direction to the structure.

1 is a cross-sectional view of a seismic device according to an embodiment of the present invention.
2 is a schematic diagram of a device for explaining the operation of the seismic device according to an embodiment of the present invention.

Hereinafter, a seismic device according to an embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a cross-sectional view of a seismic device according to an embodiment of the present invention. The seismic device 100 according to the present invention is installed on the ground and the structure or a part of the structure is to be built on the top plate (8) located on the top, can be arranged by appropriately adjusting the number of earthquake devices according to the weight of the structure have.

In the seismic device 100 according to the embodiment of the present invention, the lower plate 1 having a planar shape is fixedly installed on the ground, and the upper plate 3 is interposed between the plurality of steel balls 2 on the lower plate 1. It consists of a laminated structure. The plurality of steel balls (2) is provided with a spacer 21 to maintain a constant interval between the steel balls (2), in the present embodiment, a rectangular shape in which a circular hollow portion into which the steel balls can be inserted is formed at regular intervals Although spacer 21 is disclosed, a variety of known spacers may be provided.

In addition, the upper plate 3 also has the same surface shape as the lower plate 1, and a cylindrical guide pillar 31 in the vertical direction is formed at the center of the upper surface.

On the other hand, the upper cylinder (3) is formed with a cylindrical outer cylinder 4 is hollow inside, the outer cylinder (4) inside the outer cylinder (4) to be in contact with the inner circumference of the outer cylinder (4) An inner cylinder 5 having a diameter smaller than) is formed. Accordingly, the inner cylinder 5 may move up and down along the inner wall of the outer cylinder 4.

In addition, the inner cylinder 5 is also formed in a hollow cylindrical shape, the vertical length of the inner cylinder 5 is formed smaller than the vertical length of the outer cylinder (5). In addition, a circular cover 6 is integrally formed with the inner cylinder 5 to cover the upper portion of the inner cylinder 5.

In addition, the cover 6 is provided with a planar top plate 8, the width of the top plate 8 has the same width as the diameter of the outer cylinder (4).

In addition, a buffer piston (7) is provided inside the inner cylinder (5), the buffer piston (7) of cylindrical shape smaller than the inner cylinder (5) to be in contact with the inner circumference of the inner cylinder (5) A body 72, a protrusion 71 protruding from the center of the upper surface of the body 72 toward the bottom surface of the cover 6, and a cylindrical sliding column 73 provided on the bottom surface of the body 72. In this case, the cylindrical sliding column 73 may be empty inside, and the above-described guide column 31 may be located inside the sliding column 73. Therefore, the buffer piston 7 can move up and down along the inner wall of the inner cylinder 5 and the guide column 31 along the inner wall of the sliding column 73.

On the other hand, in the interior of the outer cylinder 4, under the body 72 of the buffer piston (7), the sliding pillar (73), that is, the sliding coil (73) inside the first coil spring (9) ), The first coil spring 9 is provided so that the first coil spring 9 supports the body 72. In addition, a second coil spring 10 having a diameter larger than that of the first coil spring 9 is provided below the inner cylinder 5 so as to surround the circumference of the first coil spring 9. ) Supports the inner cylinder (5).

Therefore, the outer cylinder 4 is formed in order of the outer cylinder 4, the second coil spring 10, the first coil spring 9, the sliding pillar 73, and the guide pillar 31 in this order. Although the height of the first coil spring 9 shown in the figure is shown higher than the height of the second coil spring 10, the height of both may be the same.

In addition, a lower portion of the outer cylinder 4 has a first air inlet 41 for introducing air into the outer cylinder 4 and a first air outlet 42 for discharging air from the inside of the outer cylinder 4 to the atmosphere. Is formed. Therefore, when the earthquake sensor detects an earthquake, it is possible to supply compressed air to the inside of the outer cylinder through an air supply control device (not shown), and when the inside of the outer cylinder 4 is above a certain pressure, the air is discharged to the outside of the outer cylinder. You may.

Similarly, the cover 6 also discharges air to the atmosphere from the second air inlet 61 which introduces air into the space I formed by the cover 6, the inner cylinder 5, and the body 72. The second air outlet 62 is formed. Therefore, when the earthquake sensor detects an earthquake, it is possible to supply compressed air to the space (I) through an air supply control device, which is not shown.

In this case, the air supply control device, not shown, is a device for discharging the preset compressed air by receiving a signal from the earthquake sensor and blocking the compressed air when the predetermined pressure is exceeded. A known air compressor, an air tank, a regulator , And actuators.

On the other hand, the seismic device 100 according to an embodiment of the present invention is provided with a ring-shaped first air cushion 11 that simultaneously covers the side of the top plate 1 and the upper side of the outer cylinder 4, the outer cylinder A ring-shaped second air cushion 12 surrounding the outer circumference of the upper plate is provided, and a ring-shaped third air cushion 13 surrounding the side of the upper plate and the lower plate is provided at the same time.

In addition, the seismic device 100 according to the embodiment of the present invention includes an interior of the outer cylinder 4 and a space composed of a cover 6, an inner cylinder 5, and a body 72 of the buffer piston 7. In order to prevent the injected air from leaking, the outer circumference of the inner cylinder 5 in contact with the inner circumference of the outer cylinder 4, the circumference of the body 72 of the buffer piston 7, and the guide pillar 31 It is preferable that the O-ring 14 is formed along the circumference.

In addition, since the seismic device 100 according to the embodiment of the present invention is exposed to the external environment, it is preferable to perform Cr plating on the entire surface and the first coil spring and the second coil spring to prevent rust.

Earthquake resistance device 100 according to an embodiment of the present invention can be installed in the lower portion of the structure in an appropriate amount according to the area of the structure.

Hereinafter, when an earthquake occurs, the operation of the earthquake-resistant device 100 according to an embodiment of the present invention will be described with reference to FIG.

When an earthquake occurs, when the earthquake sensor detects this and sends an air supply signal to the air supply control device, the air supply control device is configured to provide compressed air with the first air inlet 41 and the second air of the seismic device 100. It is injected into the inlet (61). In this case, the compressed air is preferably 100 kg / cm 2 or more. Compressed air is injected into the interior of the outer cylinder 4 and the space I formed by the cover 6, the inner cylinder 5, and the body 72, thereby forming an inner cylinder integrally formed with the cover 6 ( 5) and the up and down movement of the cushioning piston (7) is controlled, while the elastic deformation and restoration of the first coil spring (9) and the second coil spring (10) with respect to the structure provided on the seismic device (100) Vertical shocks are absorbed and dampen vibrations. Thereafter, the air supply control device supplies air to the atmosphere through the first air outlet 42 and the second air outlet 62 when the pressure inside the outer cylinder 4 and the space I exceeds a predetermined pressure. To be discharged.

According to the strength and type of the seismic wave, the compressed air is inside the outer cylinder 4 provided with the first coil spring 9 and the second coil spring 10, and the cover 6, the inner cylinder 5, and the body 72. It may be injected at the same time into the space (I) consisting of) or may be injected sequentially, and the air discharged may be adjusted to be discharged at different times in different amounts.

On the other hand, the vibration in the horizontal direction during the earthquake to absorb the impact on the structure by moving the steel sphere 2 and the lower plate 1 relative to the upper plate (3) in the horizontal direction.

Therefore, when constructing a structure by installing the seismic device according to the present invention in an appropriate number according to the weight of the structure, when the earthquake occurs, to minimize the vertical vibration and horizontal vibration caused by the support wave to maintain the structure provided on the top of the earthquake resistant device You can do that.

1: lower plate 2: steel ball
3: upper plate 31: guide pillar
4: outer cylinder 5: inner cylinder
6: cover 7: buffer piston
71: protrusion 72: body
73: sliding column 8: top plate
9: 1st coil spring 10: 2nd coil spring
11, 12, 13: 1st, 2nd, 3rd air cushion 100: seismic device

Claims (3)

A lower plate having a surface shape fixedly installed on the ground;
An upper plate having a cylindrical shape formed on the lower plate via a plurality of steel spheres and having a cylindrical guide pillar formed in a vertical direction at the center of the upper surface;
A cylindrical outer cylinder provided on the upper plate and having an empty interior;
An inner hollow cylinder having a vertical length, which may be moved up and down in contact with an inner circumference of the outer cylinder, and having a vertical length smaller than the vertical length of the outer cylinder;
A circular cover integrally formed with the inner cylinder to cover an upper portion of the inner cylinder;
A top plate provided on the cover and having a width equal to the diameter of the outer cylinder; And
A cylindrical body which can be moved up and down in contact with the inner circumference of the inner cylinder, a protrusion projecting from the center of the upper surface of the body to the bottom of the cover, and abutting the outer circumference of the cylindrical guide pillar at the bottom of the body As an earthquake-resistant device comprising; a shock absorbing piston having a hollow cylindrical sliding column that can be moved up and down;
In the interior of the outer cylinder, a first coil spring is provided to surround the sliding column under the body of the buffer piston, a diameter larger than the diameter of the first coil spring under the inner cylinder (5) of the first coil spring The second coil spring is wrapped around the circumference,
A lower portion of the outer cylinder is formed with a first air inlet for introducing air into the outer cylinder and a first air outlet for discharging air from the inside of the outer cylinder to the atmosphere,
The cover has a second air inlet for introducing air into the space formed by the cover, the inner cylinder and the body and a second air outlet for discharging air from the space to the atmosphere,
A ring-shaped first air cushion is formed to simultaneously surround the side of the top plate and the upper side of the outer cylinder,
A ring-shaped second air cushion is formed to surround the outer circumference of the outer cylinder,
A seismic device is formed such that the ring-shaped third air cushion surrounds the side of the upper plate and the side of the lower plate at the same time. The earthquake resistance device of claim 1, wherein an O-ring is formed along an outer circumference of the inner cylinder, which is in contact with the inner circumference of the outer cylinder, a circumference of the body of the cushioning piston, and a circumference of the guide pillar. The method according to claim 1 or 2,
A circular hollow portion includes a rectangular spacer formed at regular intervals, wherein the plurality of steel spheres is inserted into the hollow portion seismic device.

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