JPH10169249A - Base isolating structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make it possible to absorb seismic forces exceeding the deformation performance limit of a base-isolating device. SOLUTION: A base-isolating structure has a base-isolating device 14 interposed between the frame 10 and foundation 12 of a building construction, an auxiliary base isolating device 16, and a viscous damper 30. A disc-shaped plate 18 extended outward from the device 14 is provided at the lower end of the frame 10. The damper 30 is installed to sandwich the base-isolating device 16 and the plate 18 and located on an orthogonal axis passing the center of the base-isolating device 14. The damper 30 has a casing 30b in which a high-viscosity fluid 30a is sealed and a piston 30c installed in such a way as to move freely along the longitudinal direction of the casing 30b, a receiving plate 30d is secured to the projecting end of the piston 30c, and pressure members 30e each having one end secured to the lower surface of the plate 18 are installed on the receiving plate 30d while being opposed to each other at a predetermined interval L. The interval L is set to almost the same length as the magnitude of the deformation performance limit of the base-isolating device 14.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a seismic isolation structure, and more particularly to a seismic isolation structure capable of absorbing seismic energy even when a seismic force exceeding the deformation performance of a seismic isolation device is applied.

[0002]

2. Description of the Related Art Seismic isolation structures are known as means for protecting building structures from earthquake shaking. Most conventional seismic isolation structures have an extreme rigidity between the ground and superstructure in the horizontal direction. A small seismic isolation device is installed in the building to extend the vibration period of the entire structure and concentrate the deformation during an earthquake on the seismic isolation device.

[0003] As one type of seismic isolator developed for such a purpose, a laminated rubber type seismic isolator is known, and this type of seismic isolator is composed of a plurality of rubber plates and alternately with the rubber plates. And vulcanizing the rubber plate in a laminated state to form a laminated body in which these are integrated.

A laminate using such a rubber plate has a load-bearing function against a vertical force and has a deforming ability against a horizontal force acting during an earthquake or the like. Is characterized by absorbing the displacement by being deformed. However, such a conventional seismic isolation device has a technical problem described below.

[0005]

That is, in the above-described laminated rubber type seismic isolation device, when a tensile force is applied in the vertical direction, the rubber plate and the plate of the laminated body are separated from each other. Currently, performance is not guaranteed.

[0006] The tensile force generated by the column axial force when an earthquake force acts on a building structure is higher in a high-rise building, and the vertical load due to the building weight is offset, and a vertical tensile force acts on the lowermost layer. there is a possibility. However, the performance of conventional laminated rubber seismic isolation devices is not guaranteed when a vertical tensile force is generated. Is the design condition.

[0007] For this reason, this type of seismic isolation structure is said to be unsuitable for high-rise or high-rise building structures, and has not been actually designed. However, the basic principle of this type of seismic isolation structure, which attempts to escape the earthquake input by extending the vibration period of the entire building structure, is also effective for high-rise or high-rise building structures. It is considered possible to reduce the response to earthquake input including long-period components by seismic isolation of building structures.

Accordingly, the present inventors have conducted intensive studies and as a result, it has been found that if the vertical tensile force is controlled by a laminated rubber type seismic isolation device, this type of seismic isolation device can be applied to high-rise or super-high-rise buildings. Have already been proposed in Japanese Patent Application No. 7-207986.

However, the seismic isolation structure proposed previously has room for improvement in the following points, according to subsequent studies. In other words, there is a limit to the deformation performance of the seismic isolation device laminate, and if seismic force exceeding the limit is applied, the expected energy will not be absorbed, and the building structure will be in a very dangerous state In such a case, the proposed seismic isolation structure could not cope.

[0010] The present invention has been devised to avoid such a situation, and its object is to provide:
It is an object of the present invention to provide a seismic isolation structure capable of absorbing and relaxing the deformation even when a displacement exceeding the deformation performance limit of the seismic isolation device occurs.

[0011]

In order to achieve the above object, the present invention relates to a seismic isolation structure having a laminated rubber type seismic isolation device interposed between a skeleton of a building structure and a base. In, while providing a plate extending outward of the seismic isolation device on the skeleton side, an arm portion facing the plate from the base side is erected, between the plate and the arm portion, Auxiliary seismic isolation device that regulates the vertical pulling force of the seismic isolation device and allows horizontal deformation of the seismic isolation device is provided, and between the plate and the base side, A viscous damper that operates within the range that exceeds the deformation performance limit of the seismic isolation device is provided. According to the seismic isolation structure configured in this way, when a vertical tensile force acts on the lowermost layer of the skeleton, this is regulated by the auxiliary seismic isolation device, and the horizontal seismic force is reduced. Since the auxiliary seismic isolation device allows deformation of the seismic isolation device,
The vibration absorption function of the seismic isolation device can be exhibited effectively. In addition, since a viscous damper that operates within the range exceeding the deformation performance limit of the seismic isolation device is provided between the plate on the skeleton side and the base, when a displacement exceeding the deformation performance limit of the seismic isolation device occurs. In addition, the deformation can be absorbed and reduced by the viscous damper. The viscous damper is
Four can be arranged on the orthogonal axis centering on the seismic isolation device. When this configuration is employed, the seismic force absorbing function of the viscous damper can be effectively exerted against seismic force in all directions in the horizontal plane. The viscous damper includes a casing in which a high-viscosity fluid is sealed, and a piston movably installed along the axial direction of the casing. The casing is fixed to the base side, and the piston projects A pressing member facing the end at a predetermined interval may be fixed to the plate side, and the predetermined interval may be set to substantially the same size as the deformation performance limit of the seismic isolation device. With this configuration, the projecting end of the piston and the pressing member facing the piston are provided at a distance corresponding to the deformation performance limit of the seismic isolation device. It can be activated when the performance limit is exceeded.

[0012]

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. 1 to 3
1 shows an embodiment of the seismic isolation structure according to the present invention.

The seismic isolation structure shown in FIG. 1 includes a seismic isolation device 14 interposed between a frame 10 and a base 12 of a building structure.
An auxiliary seismic isolation device 16 and a viscous damper 30 are provided. At the lower end of the frame 10, a disk-shaped plate 18 is installed concentrically with the seismic isolation device 14 and extends outside the seismic isolation device 14.

The seismic isolation device 14 has a laminated body 14a having a substantially cylindrical outer shape, and disk-shaped upper and lower end plates 14b and 14c arranged at both ends of the laminated body 14a. I have.

The laminated body 14a is composed of a plurality of disc-shaped high-attenuation rubber plates and a plurality of disc plates inserted between the rubber plates and laminated. By the vulcanization, the rubber plate and the plate are integrated.

The upper end plate 14b of the seismic isolation device 14
Is fixed to the lower surface of a plate 18 provided on the skeleton 10 side, and the lower end plate 14c is fixed to the upper surface side of the base 12.

On the base 12, an annular arm portion 20 stands upright so as to surround the outer periphery of the seismic isolation device 14 and the outer periphery of the plate 18. The distal end side of the arm portion 20 is bent inward at an angle of approximately 90 °, and the bent portion 20 a faces the upper surface side of the plate 18.

The auxiliary seismic isolation device 16 is located at a position where the bent portion 20a of the arm portion 20 and the plate 18 face each other.
Four units having the same configuration are arranged so as to be located on two orthogonal axes (X, Y) passing through the center of the seismic isolation device 14.

The auxiliary seismic isolation device 16 of this embodiment has a laminated body 16a having a smaller diameter than the laminated body 14a of the seismic isolator 14, and ring-shaped upper and lower end plates 16b arranged above and below the laminated body 16a. , 16c.

The laminated body 16a is composed of a plurality of ring-shaped high attenuation rubber plates and a plurality of ring-shaped plates which are alternately inserted between the rubber plates and laminated. By the vulcanization, the rubber plate and the plate are integrated.

The upper end plate 16b disposed on the upper surface side of the laminated body 16a is fixed to the lower surface side of the bent portion 20a of the arm portion 20, and the lower end plate 16c disposed on the lower surface side is fixed. , Fixed to the upper surface of the plate 18.

The viscous damper 30 is installed on the lower surface side of the plate 18 so as to sandwich the four auxiliary seismic isolation devices 16, and on two orthogonal axes (X, Y) passing through the center of the seismic isolation device 14. , Four of the same configuration are arranged.

The viscous damper 30 includes a high-viscosity fluid 30a,
For example, it has a casing 30b in which a fluid in which polybutene, polyisobutylene and glass fiber are mixed at a predetermined ratio is enclosed, and a piston 30c movably installed along the longitudinal axis direction of the casing 30b. ing.

The casing 30b is fixed on the base 12. A receiving plate 30d is fixed to a protruding end of the piston 30c from the casing 30b. A pressing member 30e, one end of which is fixed to the lower surface of the plate 18, is installed on the receiving plate 30d so as to oppose the pressing member 30e at a predetermined interval L.

This interval L is determined by the thickness of the laminated body 14 of the seismic isolation device 14.
The length is set substantially equal to the size of the deformation performance limit of a.

According to the seismic isolation structure configured as described above,
When a vertical pulling force acts on the lowermost layer of the frame 10, the arm 20 is erected so as to face the plate 18 from the base 12 side. 20 is about to move in a direction in which the bent portion 20a approaches.

However, the plate 18 and the arm 2
An auxiliary seismic isolation device 16 of a laminated rubber type is provided between the bent portion 20a and the bent portion 20a of the arm portion 20 when the plate 18 and the bent portion 20a of the arm portion 20 move in the approaching direction. The compressive force is applied to the seismic device 16, and the rigidity of the auxiliary seismic isolator 16 in this direction is extremely large. Therefore, the auxiliary seismic isolator 16 acts on the lowermost layer of the frame 10 in the vertical direction. The pulling force is regulated.

On the other hand, as shown in FIG. 3, with respect to the horizontal seismic force, the seismic isolation device 14 and the auxiliary seismic isolation device 16 are both formed of a laminated rubber type, so that the rigidity in the horizontal direction is improved. Are very small and have a deformation capacity in this direction, and therefore the
The displacement for earthquakes in the range up to the deformation performance limit of a can be absorbed.

Then, when a horizontal seismic force greater than the deformation performance limit of the laminated body 14a acts, the pressing member 30e abuts on the receiving plate 30c of the piston 30b to move the piston 30b in the horizontal direction.

At this time, since the high-viscosity fluid 30a is sealed in the casing 30b, the piston 30c moves while compressing the high-viscosity fluid 30a, and seismic energy is absorbed in this process.

According to the seismic isolation structure of the present embodiment configured as described above, since a vertical tensile force does not act on the seismic isolation device 14, the seismic isolation structure can be stacked on a high-rise or super-high-rise building structure. The rubber-type seismic isolation device 14 can be applied.

Also, in the case of this embodiment, the seismic isolation device 14 and the auxiliary seismic isolation device 16 are arranged vertically in the case of an earthquake with a large vertical movement, and the plate 18 is placed from the base 12 side. Arm 20 is erected so as to face upward,
Since the auxiliary seismic isolation device 16 is provided at the opposed portion, the seismic isolation device 14 and the auxiliary seismic
6 and 7 are alternately compressed, so that these seismic isolation effects can be effectively exerted.

Further, in the case of the present embodiment, the pressing member 30e is connected only between the plate 18 on the frame 10 side and the base 12 when there is a deformation exceeding the deformation performance limit of the seismic isolation device 14. Since the viscous damper 30 which operates by contact with the receiving plate 30d is provided, even when a displacement exceeding the deformation performance limit of the seismic isolation device 14 occurs, the deformation can be absorbed and reduced by the viscous damper 30. it can.

Further, in the case of the present embodiment, since four viscous dampers 30 are arranged on the orthogonal axis (X, Y) centering on the seismic isolation device 14, earthquakes in all directions in the horizontal plane are possible. The seismic force absorbing function of the viscous damper 30 can be effectively exerted against the force.

FIG. 4 shows another embodiment of the seismic isolation structure according to the present invention. The same or corresponding parts as those in the above embodiment are denoted by the same reference numerals, and description thereof is omitted. Only the points will be described.

In the embodiment shown in the figure, the projecting end of the viscous damper 30 of the above embodiment is bent in an L shape, and the receiving plate 30'd is directly fixed to the lower surface of the plate 18.
In this case, as the viscous damper 30 ′, one that operates within a range exceeding the deformation performance limit of the laminated body 14 a of the seismic isolation device 14 is used.

As the highly viscous fluid 30'a sealed in the casing 30'b, a fluid having a lower viscosity than that of the above embodiment is used. According to the seismic isolation structure configured as described above, the viscous damper 30 ′ operates in a range exceeding the deformation performance limit of the laminated body 14 a of the seismic isolation device 14, so that the same operation and effect as those in the above embodiment can be obtained. As well as
The viscous damper 30 ′ of this embodiment exerts a function together with the seismic isolation device 14 from the initial stage against the seismic force in the horizontal direction. System.

In the above embodiment, the viscous damper 3
Although a high-viscosity fluid is exemplified as 0 and 30 ', the viscous damper of the present invention is not limited to this, and, for example, extremely mild steel can be used.

[0039]

As described above in detail in the embodiments,
According to the seismic isolation structure of the present invention, even when a displacement exceeding the deformation performance limit of the seismic isolation device occurs, the deformation can be absorbed and reduced.

[Brief description of the drawings]

FIG. 1 is an explanatory side view showing one embodiment of a seismic isolation structure according to the present invention.

FIG. 2 is an explanatory diagram of a planar arrangement state of the seismic isolation structure of FIG. 1;

FIG. 3 is an explanatory side view when a horizontal seismic force acts on the seismic isolation structure of FIG. 1;

FIG. 4 is an explanatory side view showing another embodiment of the seismic isolation structure according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Frame 12 Base 14 Seismic isolation device 16 Auxiliary seismic isolation device 18 Plate 20 Arm part 20a Bent part 30, 30 'Viscous damper 30a, 30'a High viscous fluid 30b, 30'b Casing 30c, 30'c Piston

Claims (3)

[Claims] 1. A seismic isolation structure having a laminated rubber type seismic isolation device interposed between a skeleton side of a building structure and a base, wherein the seismic isolation device extends outward from the skeleton side toward the skeleton side. A plate is provided, and an arm portion facing the plate is erected from the base side, and between the plate and the arm portion, a tensile force acting on the seismic isolation device in a vertical direction is regulated, In addition, an auxiliary seismic isolation device that allows horizontal deformation of the seismic isolation device is provided, and a viscous damper that operates within a range exceeding the deformation performance limit of the seismic isolation device is provided between the plate and the base. Seismic isolation structure characterized by being provided. 2. The seismic isolation structure according to claim 1, wherein four viscous dampers are arranged on an orthogonal axis centered on the seismic isolation device. 3. The viscous damper includes a casing in which a high-viscosity fluid is sealed, and a piston movably provided along an axial direction of the casing, wherein the casing is fixed to the base side. A pressing member facing the projecting end of the piston at a predetermined interval is fixed to the plate side, and the predetermined interval is set to substantially the same size as the deformation performance limit of the seismic isolation device. The seismic isolation structure according to claim 2.