KR20140030878A - Seismic reinforcing device - Google Patents

Abstract

The present invention relates to a seismic reinforcing device comprising: an upper plate having an equipment mounted on the upper surface thereof; a lower plate coming in contact with a floor surface on the lower part of the upper plate; a first vibration absorbing unit which is positioned in between the upper and lower plates, which is combined with and fixed in the center of the upper and lower plates, and which includes an elastic body to absorb vibration vertically generated; and a second vibration absorbing unit which is connected to the first vibration absorbing unit and which has an elastic body provided to absorb horizontal vibration. The seismic reinforcing device according to an embodiment of the present invention is provided to protect the equipment from bearing load when the vertical and horizontal vibration is transferred simultaneously to the equipment.

Description

Earthquake Reinforcement Device {SEISMIC REINFORCING DEVICE}

The present invention relates to an earthquake-resistant reinforcing device, and more particularly, to an earthquake-resistant reinforcing device capable of absorbing vibrations transmitted in a vertical direction and a horizontal direction.

In case of building, seismic load is calculated by strength design method, allowable load design method, LRFD, etc., and when it is applied to the structure, reinforcement is designed to endure the structure without collapse.

In addition, in the case of substation and power plant equipment, seismic reinforcement by anchor design is used on the basis of seismic force calculated on the basis of current seismic design standard.

However, the method of anchor reinforcement design on the basis of the current electric power facility considers the seismic force acting horizontally and the maximum value of the horizontal seismic load. Since seismic loads are often applied simultaneously in the horizontal and vertical directions, the seismic forces in the vertical direction cannot be considered.

In addition, in the case of power equipment such as switchboards and control panels, there is a phenomenon that a malfunction occurs while repeating ON / OFF in the event of an earthquake, including a precise control device, and there is a problem that the conventional seismic reinforcement method cannot prepare for this.

The present invention has been proposed to solve at least some of the above problems, and an object thereof is to provide an earthquake-proof reinforcing device that considers the case where the seismic force acts simultaneously in the horizontal and vertical directions.

In addition, it is an object of the present invention to provide a separate seismic reinforcing device that can be applied to the equipment requiring seismic reinforcement without having to consider the design criteria of each facility.

As a technical aspect for achieving the above object, the present invention is located between the lower plate and the upper plate and the lower plate in contact with the bottom surface of the upper plate and the lower portion of the upper plate is installed on the upper surface, The elastic body is fixedly coupled to the center of the upper plate and the lower plate, and connected to the first vibration absorbing unit having an elastic body so as to absorb vibration generated in the vertical direction and the first vibration absorbing unit and absorbing the horizontal vibration. It provides a seismic reinforcement device comprising a second vibration absorbing portion provided.

Preferably, the second vibration absorbing part is provided on the lower surface of the cloud member accommodating part so that the first vibration absorbing part is fixed and the cloud member accommodating part having a lower surface recessed inward and the cloud member accommodating part are movable in a horizontal direction. It may be configured to include a second elastic portion for connecting the rolling member receiving portion in the rolling member and the lower plate.

In addition, the rolling member is characterized in that the spherical shape.

Preferably, the lower surface of the cloud member accommodating part and the cloud member may be coated with a wear resistant material to minimize friction.

Preferably, the seismic reinforcing device may further include a damper portion that reduces the shaking of the upper plate or absorbs vibration in the vertical direction when a load is applied to the upper plate.

Preferably, the damper part is connected to a damper case having oil therein and the hinge part, and a piston moving upward and downward by one side is connected to a lower end of the piston and further provides a third elastic part providing restoring force to the piston. It can be configured to include.

Preferably, the damper portion may further include a hinge portion which is hinged in combination with the upper plate.

In addition, the hinge portion may preferably include an upper rod having a lower portion as a curved surface and a lower rod formed at a curved portion corresponding to a curved surface of the lower portion of the upper rod.

 In addition, preferably, the curved portion of the lower portion of the upper rod and the curved portion of the lower rod may be coated with a wear resistant material to minimize friction.

And preferably, a seismic reinforcing system including a plurality of seismic reinforcing devices installed at a lower end of the facility to absorb vibrations generated when a load is applied to the facility.

According to the seismic reinforcing device according to an embodiment of the present invention as described above, the seismic reinforcing device provides an effect of protecting the equipment from the supporting load when the seismic force is applied simultaneously in the horizontal direction and the vertical direction.

In addition, it provides the effect of protecting equipment from earthquakes simply and uniformly without considering the design criteria of each facility.

1 is a plan view of a seismic reinforcing device according to an embodiment of the present invention.
Figure 2 is a front view of Figure 1;
Figure 3 is a front view of the hinge portion and the damper portion of the seismic reinforcement device according to an embodiment of the present invention.
Figure 4 is a front view of a facility equipped with one seismic reinforcing device according to an embodiment of the present invention.
5 to 6 is a front view and a plan view of a facility equipped with a plurality of seismic reinforcement device.

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will now be described in detail with reference to the accompanying drawings.

The embodiments described below are embodiments suitable for understanding the technical features of the present invention. However, the present invention is not limited to the technical features of the present invention by the embodiments described or applied to the embodiments described below, and various modifications are possible in the technical scope of the present invention.

In particular, the present invention relates to an earthquake-proof reinforcement device of power equipment such as switchboards and control panels as an example, but is not necessarily limited to power equipment, and is not only vibration caused by seismic waves but also various elements capable of applying vibration to equipment other than seismic waves. It can also be applied to protecting the equipment by absorbing the vibration in the horizontal and vertical direction generated by.

1 to 2, the seismic reinforcing device 100 according to an embodiment of the present invention includes a first vibration absorbing unit 120 and the first vibration having an elastic body to absorb vibration generated in a vertical direction. It may be configured to include a second vibration absorbing portion 130 connected to the absorbing portion 120 and provided with an elastic body to absorb the vibration in the horizontal direction.

First, the first vibration absorbing unit 120 is configured to include a first elastic portion 121 that can absorb the vibration in the vertical direction. The first elastic portion 121 may be provided as an air spring filled with a gas therein.

 The first elastic portion 121 is located at the lower end of the upper plate 111, the vibration generated in the vertical direction absorbs the vibration in the air spring facility (10) provided in the upper plate 111 is vertical Prevents damage caused by vibration in the direction.

However, when the first elastic portion 121 is an air spring, it is only an embodiment and may be provided with various elastic members.

When the first elastic part 121 is the air spring 121, when the plate and the air spring 121 are connected to each other, the breakage of the air spring 121 is prevented and the upper plate 111 is connected to the upper spring 111. An upper connection member 122 is preferably provided between the first elastic part 121 and the upper plate 111 so that the first elastic part 121 and the upper plate 111 can be easily connected. In addition, the upper connection member 122 may be fixed to the upper plate 111 by fixing means 140 such as a bolt.

On the other hand, the lower portion of the first vibration absorbing unit 120 is provided with a second vibration absorbing unit 130 that can absorb the vibration in the horizontal direction transmitted to the facility (10).

The second vibration absorbing part 130 is fixed to the first vibration absorbing part 120 and the cloud member accommodating part 131 and the cloud member accommodating part 131 are moved in a horizontal direction. It is connected to one side of the cloud member 132 and the lower plate 112 and the cloud member accommodating portion 131 provided on the lower surface of the cloud member accommodating portion 131 to absorb the vibration in the horizontal direction It comprises a 2 elastic parts 133.

First, the second vibration absorbing part 130 may move freely to the first vibration absorbing part 120 provided at the lower end of the facility 10 while the facility 10 moves in an arbitrary horizontal direction. The cloud member 132 may be provided at a lower end of the first vibration absorbing part 120.

For example, the vibration caused by the seismic wave, the vibration in the horizontal direction due to the seismic wave vibration can be transmitted in any direction so that the facility 10 is moved in any horizontal direction, the first vibration absorbing portion 120 The cloud member 132 is provided at the bottom to freely move the first vibration absorbing part 120.

At this time, the rolling member 132 is preferably provided in a spherical shape for the movement of the first vibration absorbing unit 120 in any horizontal direction.

In addition, the cloud member accommodating part 131 to accommodate the cloud member 132 is provided so that the cloud member 132 is provided at the bottom of the first vibration absorbing unit 120, the first vibration absorbing unit 120 Is connected to.

Thus, the cloud member accommodating part 131 is coupled to the lower end of the first vibration absorbing part 120 is connected to the first vibration absorbing part 120, the lower part of the cloud member accommodating part 131 It may be provided in a shape recessed inward to accommodate the cloud member 132.

Therefore, referring to FIG. 2, when the cloud member 132 has a spherical shape, the lower end of the cloud member accommodating part 131 may be provided to be recessed inwardly to accommodate the spherical shape.

In addition, a lower surface of the cloud member accommodating part 131 and the cloud member 132 are coated with a wear-resistant material to minimize friction so that the first connected to the upper part of the cloud member accommodating part 131. It is preferable that the vibration absorbing unit 120 can be freely moved in any horizontal direction.

Accordingly, the facility 10 positioned on the first vibration absorbing part 120 and the first vibration absorbing part 120 by the rolling member 132 accommodated in the cloud member accommodating part 131 may be any. It is movable in the horizontal direction of.

If it is impossible to move freely, the facility 10 is directly affected by the vibration in the horizontal direction, and the facility 10 is increased by the vibration.

As a result of the free movement of the installation 10, the rolling member accommodating part 131 is provided with a second elastic part 133 so as to reduce vibration in the horizontal direction while being transferred to the installation 10. The vibration in the horizontal direction can be absorbed.

That is, the installation 10 is free to move in any direction when the vibration is transmitted in the horizontal direction, the vibration is moved by the second elastic portion 133 provided in the second vibration absorbing unit 130 during the movement. While being absorbed, the installation 10 is prevented from being damaged by vibration in the horizontal direction.

One side of the second elastic portion 133 is connected to the cloud member accommodating portion 131 and the other side is fixed to the lower plate 112.

Thus, the first vibration absorbing part 120 connected to the facility 10 and the cloud member accommodating part 131 connected to the first vibration absorbing part 120 are free to move in the horizontal direction, but the second The vibration is absorbed by the elastic portion 133, the movement is limited.

When the rolling member accommodating part 131 and the first elastic part 121 are easily connected, and the first elastic part 121 is an air spring, breakage of the air spring due to vibration in the vertical direction is prevented. In order to prevent the above, the lower connection member 123 may be further provided between the cloud member accommodating part 131 and the first elastic part 121 like the upper connection member 122 discussed above.

In this case, the cloud member accommodating part 131 and the lower connection member 123 may be fixed to the first elastic part 121 by the fixing means 141.

In addition, the second elastic portion 133 may be provided with a spring as shown in Figures 1 and 2, this is only one embodiment and various embodiments having an elastic force is possible.

In addition, the second elastic part 133 may be fixed while maintaining an angle of 90 degrees evenly with respect to the first vibration absorbing part 120 as shown in FIGS. 1 to 2.

 At this time, the cloud member receiving portion 131 can move in any horizontal direction, the cloud member receiving portion 131 is limited by the second elastic portion 133 because the movement is limited to the second elastic portion within a limited range The vibration transmitted to the facility 10 is absorbed by the elastic force.

However, this is only one embodiment, and the number of the second elastic parts 133 and the fixed position may be variously modified.

For example, when the second elastic part 133 is connected to the cloud member accommodating part 131 with three elastic members, each elastic member maintains 120 degrees around the cloud member accommodating part 131. And may be connected to the lower plate 112.

On the other hand, when one side of the second elastic portion 133 is connected to the cloud member receiving portion 131, the other side is connected to the lower plate 112, as long as the height of the cloud member 132 One side and the other side of the two elastic portion 133 will generate a height difference.

Thus, when the second elastic part 133 is provided horizontally with the lower plate 112, only the vibration in the horizontal direction is absorbed, but in this way one side and the other side of the second elastic part 133 makes a height difference When contracted and relaxed, it also absorbs vertical vibrations.

On the other hand, in another embodiment of the present invention, the second elastic part 133 is connected to the same height as the height of one side of the second elastic part 133 connected to the cloud member accommodating part 131 to the horizontal direction. In order to absorb only the vibration of the side plate 113 protruding from the lower plate 112 may be further provided.

That is, one end of the second elastic portion 133 is connected to the side plate 113 at a height corresponding to the cloud member accommodating portion 131 and the other end is connected to the cloud member accommodating portion 131. One end and the other end of the second elastic portion 133 is provided at the same height, so that the second elastic portion 133 absorbs only the vibration in the horizontal direction.

However, as the first vibration absorbing unit 120 and the second vibration absorbing unit 130 absorb vibrations transmitted to the facility 10 in the vertical direction and the horizontal direction, the facility 10 is shaken. Alternatively, vibration may remain due to the first elastic body and the second elastic portion 133.

Therefore, the damper unit 160 may be further included between the upper plate 111 and the lower plate 112 to prevent such shaking and continuous vibration and to absorb the vibration in the vertical direction within a short time.

The damper part 160 includes a damper case 164 having oil therein, a piston 161 moving up and down in the damper case 164, and one side of the damper part 160. It may be configured to include a third elastic portion 162 is connected to the lower end of the) and provides a restoring force to the piston 161.

One side of the damper part 160 may be fixed to the upper plate 111 by the fixing plate 170 and the fixing anchor 171, and the other side may be fixed to the lower plate 112 or the side plate 113. Can be.

In addition, the vertical direction is caused by the vibration transmitted to the facility 10 by the third elastic part 162 connected to the oil inside the damper case 164 and the piston 161 inside the damper case 164. When it moves to absorb the vibration in the vertical direction with the first elastic portion 121.

In this case, the hinge part 150 may be further included to prevent damage of the damper part 160 when the damper part 160 receives a force in a horizontal direction.

The hinge portion 150 has a hinge 151 at a portion where the upper rod 152 is coupled to the upper plate 111, and has a curved surface at the lower end of the upper rod 152, and the curved surface and The upper portion of the lower rod 154 is provided to correspond to the curved surface to the hinge 151 movement in the portion where the upper rod 152 and the lower rod 154 is connected.

However, the curved portion of the lower portion of the upper rod 152 and the curved portion of the lower rod 154 may be coated with a wear resistant material to minimize frictional force.

4 to 6, in consideration of the weight and size of the facility 10 requiring seismic reinforcement, one seismic reinforcement device 100 is provided as well as a plurality of seismic reinforcement devices 100. It may be provided with a seismic reinforcement system 200 having.

By the way, the seismic reinforcement system 200 is different in the number of use of the seismic reinforcement device 100 in consideration of the size of the facility 10, the seismic resistance without having to consider the type of equipment or the configuration of the device used in the facility Seismic reinforcement can be obtained by fixing the equipment for seismic reinforcement on the top of the reinforcement device 100, so as a separate device can be safely protected from other vibrations as well as seismic waves.

 Hereinafter, the operation and effects of the seismic reinforcing device 100 according to an embodiment of the present invention will be described in detail.

 1 to 3, the first earthquake-resistant reinforcement apparatus 100 according to an embodiment of the present invention includes a first elastic portion 121 and a damper portion 160 to absorb vibrations transmitted in the vertical direction. .

When the first elastic portion 121 is provided with an air spring, the vertical vibration transmitted to the facility 10 absorbs the vibration while the air spring is deformed in the vertical direction.

At the same time, the damper part 160 has a rod connected to the piston 161 by a vertical load transmitted to the upper plate 111 and the lower plate 112 when the vibration in the vertical direction is transmitted in the vertical direction. Will move.

At this time, when the piston 161 of the damper unit 160 descends, the oil provided in the damper case 164 gradually flows into the damping hole 163 and is transmitted to the upper plate 111. Is attenuated.

In addition, when the piston 161 is lowered, not only vibration is absorbed by the third elastic part 162 provided at the lower end of the piston 161, but also the restoring force is provided to the piston 161 to provide the piston 161. In the absence of a vertical load acting on the piston 161 causes the piston to rise again.

On the other hand, the seismic reinforcement device 100 according to an embodiment of the present invention to absorb the vibration transmitted in the horizontal direction is provided with a second vibration absorbing unit (130).

When the vibration in the horizontal direction is transmitted to the facility 10, the cloud member 132 provided at the lower end of the facility 10 is free to move in any horizontal direction, the facility 10 also to move do.

 In this case, the second elastic portion 133 is provided on one side of the cloud member accommodating portion 131 in which the cloud member 132 is accommodated, and the other side of the second elastic portion 133 is the lower plate 112. Is fixed to) to limit the movement of the cloud member receiving portion (131).

As a result, the vibration transmitted to the first vibration absorbing part 120 and the facility 10 provided on the cloud member accommodating part 131 and the cloud member accommodating part 131 may cause vibration of the second elastic part. As absorbed, the effect is reduced.

1 to 2, the second elastic part is compressed and partially stretched by the vibration transmitted from the direction of the second elastic part 133 of any one of the second elastic parts 133 and the second elastic part in a horizontal plane. The vibration transmitted according to the compression and tension of the part 133 is reduced.

In addition, the damper part 160 may include the upper plate 111 because the first vibration absorbing part 120 does not include an elastic member capable of absorbing only horizontal vibration but only horizontal vibration. When the lower plate 112 or the side plate 113 is damaged by movement in the horizontal direction occurs.

To prevent this, the damper part 160 may further include a hinge part 150. The damper unit 160 is coupled to the upper plate 111 and the lower plate 112 when a horizontal vibration is transmitted to the damper unit 160 by the hinge 151 provided in the hinge unit 150. The damaged part is not broken.

In addition, a curved surface 153 is provided at a portion where the upper rod 152 and the lower rod 154 of the hinge portion 150 are connected, so that the upper rod 152 is moved even when the upper plate 111 is moved in a horizontal direction. ) May rotate around the curved surface 153 to prevent damage to the damper unit 160.

In addition, the seismic reinforcing device 100 according to an embodiment of the present invention includes a first vibration absorbing part 120 that absorbs the vibration in the horizontal direction and a second vibration absorbing part 130 that absorbs the vibration in the vertical direction. Connected to and fixed to each other in the rolling member accommodating portion 131, it is possible to absorb the vibration in the vertical direction and the vibration in the horizontal direction at the same time.

That is, while the first elastic part 121 of the first vibration absorbing part 120 absorbs the vibration in the vertical direction, the second elastic part 122 contracts and relaxes to generate horizontal vibration. By absorbing, the vibration transmitted in the horizontal and vertical directions can all be eliminated.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the following claims It will be appreciated that those skilled in the art will readily understand the present invention.

10: facility 100: seismic reinforcing device
111: upper plate 112: lower plate
120: first vibration absorbing portion 121: first elastic portion
122: upper connecting member 123: lower connecting member
130: second vibration absorbing unit 131: cloud member receiving unit
132: rolling member 133: second elastic portion
150: hinge portion 151: hinge
152: upper rod 153: curved surface
154: lower rod 160: damper portion
161: piston 162: third elastic portion
163: damping hole 164: damping case
200: seismic reinforcement system

Claims (11)

An upper plate on which the facility is mounted;
A lower plate in contact with a bottom surface of the lower plate;
A first vibration absorbing part disposed between the upper plate and the lower plate and fixedly coupled between the upper plate and the lower plate and having an elastic body to absorb vibration generated in a vertical direction; And
A second vibration absorbing part connected to the first vibration absorbing part and having an elastic body to absorb vibration in a horizontal direction;
Earthquake-resistant reinforcement device configured to include. The method of claim 1,
And a first elastic part absorbing the vertical vibration applied to the upper plate.
The seismic reinforcement device, characterized in that the first elastic portion is an air spring. The method of claim 1, wherein the second vibration absorbing portion
A cloud member accommodating part in which the first vibration absorbing part is fixed and the lower surface is recessed inward;
A rolling member provided on a lower surface of the rolling member accommodation portion to move the rolling member accommodation portion in a horizontal direction; And
And a second elastic part connected to one side of the lower plate and the rolling member receiving part to absorb vibration in a horizontal direction. The method of claim 3,
The rolling member is a seismic reinforcement device, characterized in that the spherical shape. The method of claim 3,
The lower surface of the cloud member receiving portion and the cloud member is a seismic reinforcement device characterized in that the contact portion is coated with a wear-resistant material to minimize friction. The method of claim 1,
And a damper unit for reducing the shaking of the upper plate or absorbing the vibration in the vertical direction when a load is applied to the upper plate. The method according to claim 6,
A damper case having an oil therein;
A piston moving upward and downward in the damper case; And
One side is connected to the lower end of the piston and a third elastic portion for providing a restoring force to the piston; The method according to claim 6,
The damper portion is a seismic reinforcement device further comprises a; hinge portion coupled to the upper plate hinged movement. 9. The method of claim 8,
The hinge portion has an upper portion of the upper rod is hinged to the upper plate and the lower portion is provided with a curved surface; And
The upper portion is a seismic reinforcement device comprising a; lower rod formed of a curved surface corresponding to the lower surface of the upper rod. 10. The method of claim 9,
Earthquake-resistant reinforcement device, characterized in that the curved portion of the lower portion of the upper rod and the curved portion of the lower rod is coated with a wear-resistant material to minimize friction. Equipment requiring seismic reinforcement; And
And a seismic reinforcing device according to any one of claims 1 to 10 installed at a lower end of the facility to absorb vibrations generated when a load is applied to the facility.

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