KR101127938B1 - Seismic isolating apparatus - Google Patents

Abstract

The present invention relates to a base isolation device, and more particularly, a laminated base isolation rubber 120 formed by alternately laminating a rubber sheet and a steel sheet, an upper flange 140 attached to an upper portion of the laminated base isolation rubber 120, and the lamination. A lower flange 160 attached to the lower portion of the base isolation rubber 120, and a plurality of damping dampers 180 installed around the laminated base isolation rubber 120, and the damping dampers 180 extend in the vertical direction. A damper member 182, an upper guide member 184 connecting an upper end of the damper member 182 to the upper flange 140, and a lower end of the damper member 182 to the lower flange 160. And a lower guide member 186, wherein the upper guide member 184 has a groove extending in the horizontal direction, and an upper end of the damper member 182 is horizontal along the groove of the upper guide member 184. Moveable in the direction The lower guide member 186 is formed with a groove extending in the horizontal direction, and a lower end of the damper member 182 is installed to be movable in the horizontal direction along the groove of the lower guide member 186. A groove 188 of the upper guide member 184 is mounted with a spring 188 for supporting the upper ends of the damper member 182 so as to face each other, and the damper member 182 in the groove of the lower guide member 186. Springs 189 for supporting the lower end of the opposite to each other is characterized in that it is mounted.

According to the present invention, when an earthquake occurs and an external force in the horizontal direction is generated, the spring primarily resists the external force and the damper member shears secondly, thereby resisting the external force and dissipating energy step by step.

Laminated base rubber, damping damper, damper element, spring

Description

Isolation Device {SEISMIC ISOLATING APPARATUS}

The present invention relates to a base isolation device.

Recent earthquakes have occurred in Asian neighboring countries and Korea's earthquake statistics data published by the Korea Meteorological Administration indicate that Korea is not a safe zone for earthquakes. Therefore, a seismic design that can withstand seismic forces is required.

In general, a seismic isolation device is installed between an upper structure such as a building, a bridge, and a lower structure supporting the same to support the structure with sufficient rigidity vertically and to dissipate energy with sufficient deformation capacity for the horizontal force.

The seismic isolator may be divided into a flexible support that acts to extend the vibration period of the structure and a damping device that absorbs seismic energy to reduce the response displacement of the structure according to its role.

Flexible supports, which serve to extend the period of vibration, must bear the weight of the structure itself in the vertical direction, be able to cause large deformations in the horizontal direction, and the performance deterioration should not occur with age changes. As the flexible support, a laminated base rubber made by bonding a rubber sheet and a steel plate of a constant thickness alternately is used. Laminated base rubber can greatly improve the rigidity in the vertical direction due to the steel sheet, thereby reducing the lateral loosening due to the vertical load and maintaining a stable deformation shape. In addition, since the shear deformation of the rubber sheet is not restrained when the shear force in the horizontal direction is applied, the elasticity of the rubber sheet alone may exhibit horizontal rigidity.

On the other hand, as a damping device for reducing the response displacement of the structure, a device in which a lead core is planted in the center of the laminated base rubber. The lead-based damping device reduces excessive relative displacements between the superstructure and the ground generated during an earthquake and stops the vibration quickly after the earthquake ends.

However, lead attenuation devices inevitably use excessive amounts of lead, which is a hazardous substance, and there is a risk of environmental damage. In manufacturing, the handling of lead becomes a problem, and when dismantling the structure in the future, the disposal method of the seismic isolation device using lead becomes a problem.

The present invention is designed to solve the problems of the prior art, and an object of the present invention is to provide an isolating device having an attenuation device having the same or higher performance without using lead.

According to a characteristic of the present invention for achieving the above object, a laminated base isolation rubber formed by alternately laminating a rubber sheet and a steel plate, an upper flange attached to an upper portion of the laminated base isolation rubber, attached to a lower portion of the laminated base isolation rubber A lower damper and a plurality of damping dampers provided around the laminated base isolation rubber, wherein the damping damper includes a damper member extending in a vertical direction, an upper guide member connecting an upper end of the damper member to the upper flange, and A lower guide member connecting a lower end of a damper member to the lower flange, wherein the upper guide member has a groove extending in a horizontal direction, and an upper end of the damper member in a horizontal direction along the groove of the upper guide member. It is installed to be movable and extends in the horizontal direction to the lower guide member. Grooves are formed, and a lower end of the damper member is installed to be movable in a horizontal direction along the groove of the lower guide member, and the groove of the upper guide member has a spring for supporting the upper ends of the damper members opposite to each other. It is mounted, the base of the lower guide member is provided with a seismic isolation device, characterized in that the spring is mounted to support the lower end of the damper member to face each other.

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The plurality of damping dampers may be symmetrically disposed about the laminated base rubber.

The damper member may be made of a plate-like steel having a predetermined thickness.

According to the present invention, when an earthquake occurs and an external force in the horizontal direction is generated, the spring primarily resists the external force and the damper member shears secondly, thereby resisting the external force and dissipating energy step by step.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a base isolation device according to an embodiment of the present invention, Figure 2 is a cross-sectional view along the line A-A of FIG.

As shown in FIGS. 1 and 2, the base isolation device 100 includes a laminated base isolation rubber 120, an upper flange 140 attached to an upper portion of the laminated base isolation rubber 120, and a bottom of the laminated base isolation rubber 120. It includes a lower flange 160 to be attached, and a damping damper 180 is provided in a plurality around the laminated base isolation rubber 120.

The laminated base isolation rubber 120 is formed by alternately stacking a rubber sheet and a steel sheet. The upper flange 140 serves to connect the laminated base rubber 120 and the upper structure, the lower flange 160 allows the laminated base rubber 120 to be disposed on the lower structure or the ground, and the upper flange 140 ) And the lower flange 160 is typically composed of a steel plate. Since the laminated base isolation rubber 120, the upper flange 140, and the lower flange 160 are the same as in the conventional configuration, detailed description thereof will be omitted.

A plurality of damping dampers 180 are installed around the laminated base isolation rubber 120, and as shown in the illustrated example, the damping dampers 180 may be symmetrically disposed about the laminated base isolation rubber 120. Since the plurality of damping dampers 180 are symmetrically disposed about the laminated base isolation rubber 120, the pair of damping dampers 180 facing each other when the horizontal force is applied in one direction may resist the horizontal force.

The damping damper 180 includes a damper member 182 extending in the vertical direction, an upper guide member 184 connecting the upper end of the damper member 182 to the upper flange 140, and a lower end of the damper member 182. And a lower guide member 186 connected to the lower flange 160.

The damper member 182 is made of a plate-shaped steel material having a predetermined thickness, and the cross section of the center portion is narrowly formed. As the steel constituting the damper member 182, it is preferable to use a high toughness steel having a ductile capacity and strength 1.8 times higher than that of a conventional steel.

A groove portion extending in the horizontal direction is formed in the upper guide member 184, and an upper end of the damper member 182 is installed to be movable in the horizontal direction along the groove portion of the upper guide member 184. A groove 188 of the upper guide member 184 is mounted with a spring 188 for supporting the upper ends of the damper member 182 to face each other.

Like the upper guide member 184, the lower guide member 186 is provided with a groove extending in the horizontal direction, and the lower end of the damper member 182 is installed to be movable in the horizontal direction along the groove of the lower guide member 186. do. A groove 189 of the lower guide member 186 is also mounted with a spring 189 for supporting the lower ends of the damper member 182 to face each other.

Hereinafter, a method of operating the base isolation device configured as described above will be described.

When an earthquake occurs and a shear force in the horizontal direction is applied to the structure, the top and bottom of the damper member 182 is moved in the opposite direction. That is, the upper end of the damper member 182 moves to the right and the lower end moves to the left, or the upper end of the damper member 182 moves to the left and the lower end moves to the right, so that the damper member 182 moves in a diagonal direction. Will be deployed.

When the horizontal shear force is released, the damper member 182 returns to its original position by the restoring force of the springs 188 and 189. That is, the damper member 182 in the diagonal direction is disposed in the vertical direction.

If the shear force in the horizontal direction acts above the external force that the springs 188 and 189 can receive, the damper member 182 begins to resist the external force after the springs 188 and 189 are fully retracted and tensioned. Since the damper member 182 is made of high toughness steel, the damper member 182 dissipates energy while deforming in a diagonal direction.

As described above, according to the present invention, when an earthquake occurs and an external force in the horizontal direction occurs, the springs 188 and 189 primarily resist the external force, and the damper member 182 shears the second deformation while resisting the external force. The damping function can be performed in stages.

1 is a perspective view of a base isolation device according to an embodiment of the present invention.

2 is a cross-sectional view taken along the line A-A of FIG.

Explanation of symbols on the main parts of the drawings

100 Seismic Isolation Machine 120 Laminated Seismic Rubber

140 Upper Flange 160 Lower Flange

180 Damper Damper 182 Damper Member

184 Upper guide member 186 Lower guide member

188, 189 spring

Claims (5)

Laminated base rubber (120) formed by alternately laminating a rubber sheet and a steel sheet, An upper flange 140 attached to an upper portion of the laminated base isolation rubber 120, A lower flange 160 attached to a lower portion of the laminated base isolation rubber 120, and A damping damper 180 is provided in a plurality around the laminated base isolation rubber 120, The damping damper 180 includes a damper member 182 extending in a vertical direction, an upper guide member 184 connecting an upper end of the damper member 182 to the upper flange 140, and the damper member 182. It has a lower guide member 186 connecting the lower end of the lower flange 160, The upper guide member 184 is formed with a groove extending in the horizontal direction, the upper end of the damper member 182 is installed to be movable in the horizontal direction along the groove of the upper guide member 184, the lower guide The member 186 is provided with a groove extending in the horizontal direction, the lower end of the damper member 182 is installed to be movable in the horizontal direction along the groove of the lower guide member 186, A groove 188 of the upper guide member 184 is mounted with a spring 188 for supporting the upper ends of the damper member 182 so as to face each other, and the damper member 182 in the groove of the lower guide member 186. Isolation device, characterized in that the spring (189) for supporting the lower end of the opposite sides on each other is mounted. delete delete The method according to claim 1, The damping damper (180) is characterized in that the isolation device is characterized in that the symmetrical arrangement around the laminated base rubber (120). The method according to claim 1, The damper member 182 is a base isolation device, characterized in that made of a plate-like steel having a predetermined thickness.

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