JPH09221933A - Equipment for preventing lift of base isolated building - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent a tensile force from acting on a seismic isolator and thereby to reduce a burden on it, by preventing lift of an upper structure. SOLUTION: A first guide rail 10 is fixed on the foundation side, while a second guide rail 20 is fixed on the upper structure side in a direction intersecting the direction of disposition of the first guide rail 10, and a connecting rod 30 is provided between these first and second guide rails 10 and 20. One end of the connecting rod 30 which is disposed on the first guide rail 10 side is fitted to the first guide rail 10 in such a manner that it is movable on the first guide rail 10 only in the direction of disposition thereof, while the other end of the connecting rod 30 which is disposed on the second guide rail 20 side is fitted to the second guide rail 20 in such a manner that it is movable on the second guide rail 20 only in the direction of disposition thereof.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for preventing a seismic isolation structure from rising so that a tensile force does not act on the seismic isolation device.

[0002]

2. Description of the Related Art In recent years, many structures have been designed in consideration of earthquakes that may occur in the future by taking measures against earthquakes by seismic isolation. As an example of this seismic isolation structure, the entire upper structure is separated from the foundation and floated, and laminated rubber is inserted as a seismic isolation device between the lower surface of the upper structure and the foundation and the upper structure is There is known a seismic isolation structure in which a damper is arranged between the lower surface of an object and a foundation to reduce the natural frequency of a vibration system including an upper structure and its support.

In this seismic isolation structure, the natural period of the upper structure becomes longer than the predominant period of seismic waves due to the interposition of laminated rubber, so that an earthquake occurs and a large seismic force acts on the foundation. In addition, the seismic force acting on the upper structure can be reduced, and the damper absorbs the vibration energy of the earthquake to ensure the safety of the entire structure.

[0004]

By the way, in the seismic isolation structure as described above, the seismic isolation device effectively operates against the sway in the direction in which the seismic isolation layer is formed to ensure the safety of the structure. However, for example, when a force acts in the direction in which the upper structure collapses, a tensile force acts in the axial direction on the seismic isolation device located outside the direction in which it collapses, placing a large burden on the seismic isolation device itself. There was such a problem. Therefore, conventionally, when designing the above-described seismic isolation structure, the height / width ratio of the structure must be about 2.5 or less in order to prevent the structure from collapsing. There were restrictions.

The present invention has been made in view of the above circumstances, and an object thereof is to prevent a tensile force from acting on the seismic isolation device in the seismic isolation structure.

[0006]

According to a first aspect of the present invention, there is provided a device for preventing the seismic isolation structure from rising between a foundation and an upper structure disposed above the foundation via the seismic isolation device. The first guide rail is fixed to the foundation side along the foundation surface, and the first upper structure side facing the foundation is located below the first guide rail. A second guide rail oriented in a direction intersecting with the arrangement direction of the guide rail is fixed along the lower surface of the upper structure, and is connected between the first guide rail and the second guide rail. A member is erected, and one end of the connecting member arranged on the side of the first guide rail is attached to the first guide rail such that the one end is movable on the first guide rail only by the arrangement method. , The other end arranged on the side of the second guide rail Characterized in that attached to the second guide rails only being movable on a second guide rail in its laying direction.

According to a second aspect of the present invention, there is provided the seismic isolation structure floating prevention device, wherein the seismic isolation structure floating prevention device has a first guide rail and a second guide rail at both ends of the connecting member. Is attached to each of the guide rails, and rolling means is mounted to roll along the guide rails when the connecting member moves on both guide rails.

[0008]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of a device for preventing the seismic isolation structure from rising according to the present invention will be described with reference to FIGS. FIG. 1 shows a device for preventing the seismic isolation structure from being lifted up, which is arranged between the foundation 2 and the upper structure 3 in the seismic isolation structure 1. The seismic isolation structure lifting prevention device includes a first guide rail 10 provided on a horizontal base surface 2 a formed on the foundation 2 and a horizontal guide structure formed on an upper structure 3 facing the foundation 2. It is provided with a second guide rail 20 provided on the lower surface 3a and a connecting rod (connecting member) 30 provided between the first guide rail 10 and the second guide rail 20.

The first guide rail 10 has a pair of rails 11 and 12 made of channel steel having a U-shaped cross section.
At both ends of these rails 11 and 12, leg portions 13 and 14 made of similar channel steel are provided, respectively. These rails 11 and 12 are arranged back to back with a space therebetween, and legs 13 are also arranged back to back,
A base plate 15 is fixed to each of the rails 14, and the rails 11 and 12 are integrated with each other.
A first slit S ₁ is formed between the two. Also,
Stiffeners 11a and 12a are arranged in inner recesses of the rails 11 and 12 near the legs 13 and 14 to stiffen the rails 11 and 12.

The integrated rails 11 and 12 are erected on a pedestal 2b formed on the base surface 2a with a base plate 15 arranged. Anchor bolts 4 struck on the base 2 side are projected on the pedestal 2b, and the anchor bolts 4 are attached to the base plate 15 and the rail 1.
The nut 4b is doubly screwed to the male screw portion 4a formed at the tip of the anchor bolt 4 by penetrating the side wall portions 11b and 12b of the first and second guide rails 10.
Are fixed in parallel along the base surface 2a.

The second guide rail 20 has a structure exactly the same as that of the first guide rail 10.
Legs 23 and 24 are provided at both ends of the rails 1 and 22, respectively, and these rails 21 and 22 are arranged back to back with a space therebetween.
The base plates 25 are fixed to the rails 3 and 24, respectively, and the rails 21 and 22 are integrated with each other.
A second slit S ₂ is formed between 1 and 22.
Further, stiffeners 21a and 22a are arranged in inner recesses of the rails 21 and 22 near the legs 23 and 24, respectively.

The integrated rails 21, 22 form a bottom surface 3a of the upper structure 3 which forms a base isolation layer between the rails 21 and 22.
The base plate 25 is arranged on the pedestal 3b formed in the above, and the pedestals are arranged upside down. The pedestal 3b is provided with an anchor bolt 5 projecting toward the upper structure 3 side, and the anchor bolt 5 is attached to the base plate 2
5 and the side wall portions 21b and 22b of the rails 21 and 22 and the nut 5b is doubly screwed to the male screw portion 5a formed at the tip of the anchor bolt 5, whereby the second
The guide rails 20 are fixed in parallel along the lower surface 3a of the upper structure 3.

The second guide rail 20 is arranged above the first guide rail 10 with a gap, and the second guide rail 20 forms a 90 ° angle in the horizontal direction so that the second guide rail 20 can be arranged in a different direction. The center of the second guide rail in the longitudinal direction is the first
Is arranged vertically above the center of the guide rail in the longitudinal direction, whereby the first guide rail 10 and the second guide rail 20 are arranged in an X shape when viewed from above.

The connecting rod 30 is the first guide rail 1
The first slit S ₁ and the second slit S _{2 are} vertically installed between 0 and the second guide rail 20 so as to overlap each other when viewed from above.

The first guide rail 10 of the connecting rod 30.
The one end 31 disposed on the side is inserted into the first slit S ₁ toward the base 2 side and projects toward the base 2 side. A rectangular slide plate 32, which is larger than the width of the first slit S ₁ , is arranged in a penetrating state at the protruding one end 31, and a nut 33 is doubly screwed to a male screw portion 31a formed at the one end 31. Has been done. Thereby, the connecting rod 30
Is attached to the first guide rail 10 so that it can be moved on the first guide rail 10 only by the arrangement method.

Second guide rail 20 of connecting rod 30
The other end 35 disposed on the second side is the second toward the upper structure 3 side.
Is inserted into the slit S ₂ and protrudes toward the upper structure 3 side. A slide plate 36, which is the same as the slide plate 32, is arranged in a penetrating state at the protruding other end 35, and a nut 37 is doubly screwed to a male screw portion 35a formed at the other end 35. Thereby, the connecting rod 30
Is attached to the second guide rail 20 so that it can be moved only by the arrangement method of the second guide rail 20.

[0017] Incidentally, the rail 1 forming the first slit S ₁
The lengths of 1 and 12 and the lengths of the rails 21 and 22 forming the second slit S ₂ are all equal, and are set to be longer than twice the maximum displacement of the seismic isolation layer expected in design. Accordingly, the moving range of the connecting rod 30 on the first guide rail 10 and the moving range of the connecting rod 30 on the second guide rail 20 are set to be twice or more the maximum displacement of the seismic isolation layer. Has been done.

As shown in FIG. 2, a plurality of the lifting preventing devices are attached around a seismic isolation device 40 made of laminated rubber G arranged between the foundation 2 and the upper structure 3. At this time, the nuts 33 and 37 screwed to the connecting rod 30 in each lifting device are tightened against the elastic force of the seismic isolation device 40 to introduce an axial force to the connecting rod 30, thereby seismically isolating. The device 40 is in a state in which the compressive force F is introduced in advance. In addition, seismic isolation device 4
The compressive force F introduced at 0 corresponds to the maximum tensile force expected to act on the seismic isolation structure 1 by design.

In the seismic isolation structure 1 having the seismic isolation structure lifting prevention device configured as described above, seismic force acts on the seismic isolation structure 1 in the horizontal direction, and the upper structure 3
When the first guide rail 10 is displaced with respect to the base 2 in the arrangement direction of the first guide rail 10, the connecting rod 30 does not move on the second guide rail 20 side, as shown in FIG. It slides on the top 10 as the upper structure 3 moves.

The upper structure 3 is second with respect to the foundation 2.
When the guide rail 20 is displaced in the arrangement direction of the guide rail 20, as shown in FIG.
The upper structure 3 slides on the second guide rail 20 in the opposite direction in which the upper structure 3 is displaced, while not moving on the side and apparently stationary.

Further, the upper structure 3 is attached to the foundation 2,
When the first guide rail 10 and the second guide rail 20 are displaced in a direction other than the arrangement direction of the first guide rail 10 and the second guide rail 20, the movement of the connecting rod 30 causes the first guide rail 10 side and the second guide rail 20 to move. On the side is compounded. As a result, even if the upper structure 3 is displaced with respect to the foundation 2 in all directions around the foundation 2, the seismic isolation device 40 operates effectively while keeping the spacing between the seismic isolation layers constant.

Next, when the seismic force acts in the direction in which the upper structure collapses, and when the upper structure 3 tries to float up from the foundation 2 outside the direction in which it collapses,
Connecting rod 3 installed between foundation 2 and superstructure 3
0 acts as an anchor to prevent the seismic isolation layer from spreading, that is, to prevent the upper structure 3 from being lifted up. Further, the connecting rod 30 cancels the tensile force by the compressive force F previously introduced to the seismic isolation device 40.

When the upper structure 3 tries to sink to the foundation 2 side in the collapse direction, both ends of the connecting rod 30 are separated from both guide rails to narrow the seismic isolation layer. Occurs, the seismic isolation device 40 is compressed and the elastic force of the laminated rubber G provides seismic isolation.

According to the seismic isolation structure floating prevention device constructed as described above, when the upper structure 3 tries to lift from the foundation 2, the connecting rod 30 acts as an anchor and the upper structure is lifted. 3 can be prevented.

The seismic isolation device 40 also includes a connecting rod 30.
As a result, the compressive force F corresponding to the maximum tensile force expected to act on the seismic isolation structure 1 is introduced in advance, so that the tensile force is canceled by the compressive force F and the seismic isolation device 40
It is possible to prevent the pulling force from acting on.

Further, when the seismic isolation layer is displaced in the horizontal direction, the connecting rod 30 slides on the first guide rail 10 and the second guide rail 20 to follow, so that the spacing of the seismic isolation layer is increased. It is possible to effectively operate the seismic isolation device 40 while maintaining a constant value.

In this embodiment, a pair of rails made of grooved steel having a U-shaped cross section is used as the first and second guide rails 10 and 20, but the present invention is not limited to such a construction. Instead of one, for example, one plate-shaped guide rail having a slit or the like may be adopted.

In the present embodiment, the slide plates 32 and 36 are attached to the ends of the connecting rod 30 so that the connecting rod 30 slides on both guide rails.
As another embodiment in place of No. 6, a carriage (rolling means) 50 as shown in FIG. 5 may be arranged. This dolly 50
Similar to the slide plates 32 and 36, a base plate 51 attached to the end portion of the connecting rod 30 is provided with four wheels 52 that are in contact with both guide rails 10 (20). When moving on 10 (20), the wheels 52 roll along with it and the connecting rod 30 can be moved more smoothly. Further, bearings may be adopted in the carriage 50 instead of the wheels 52.

[0029]

As described above, according to the device for preventing the seismic isolation structure from rising according to claim 1, the first guide rail is fixed to the foundation side and the first guide rail is fixed to the upper structure side. The second guide rail is fixed so as to be oriented in a direction intersecting the direction in which the guide rails are arranged, and a connecting member is installed between the first guide rail and the second guide rail. Moreover, one end of the connecting member arranged on the first guide rail side is attached to the first guide rail so as to be movable on the first guide rail only by the arrangement method, and the second guide is attached. Since the other end of the connecting member arranged on the rail side is attached to the second guide rail while being movable on the second guide rail only in the arrangement direction, the upper structure floats from the foundation. When trying to rise, the connecting member The upper structure is towed to play the role of anchor, it can be prevented by applying a tensile force to the seismic isolation device as well as preventing the floating of the superstructure. Also, when the seismic isolation layer is displaced in the horizontal direction,
Since the connecting member follows by sliding on the first guide rail or the second guide rail, it is possible to effectively operate the seismic isolation device while keeping the spacing between the seismic isolation layers constant.

According to the seismic isolation structure lifting prevention device of the second aspect, both ends of the connecting member are in contact with the first guide rail and the second guide rail, respectively, and the connecting member has both guide rails. Since rolling means for rolling along the guide rail when moving up is attached, the seismic isolation layer can be displaced smoothly, and the seismic isolation effect of the seismic isolation device can be further enhanced. .

[Brief description of drawings]

FIG. 1 is a perspective view showing an embodiment of a seismic isolation structure lifting prevention device according to the present invention.

FIG. 2 is a side cross-sectional view showing a state of arrangement of the lifting prevention device for the base isolation structure in the base isolation layer.

FIG. 3 is a side cross-sectional view showing an operating state in the horizontal direction along the arrangement direction of the first guide rail in the device for preventing the seismic isolation structure from rising.

FIG. 4 is a side sectional view showing an operating state in the horizontal direction along the arrangement direction of the second guide rail.

FIG. 5 is a perspective view showing another embodiment of the seismic isolation structure floating prevention device according to the present invention.

[Explanation of symbols]

 1 seismic isolation structure 2 foundation 3 upper structure 10 first guide rail 11, 12 rail 20 second guide rail 21, 22 rail 30 connecting rod (connecting member) 40 seismic isolation device 50 bogie (rolling means)

Claims (2)

[Claims] 1. A lift-up prevention device for a seismic isolation structure, which is interposed between a foundation and an upper structure arranged above the foundation via a seismic isolation device to prevent the upper structure from rising. Then, the first guide rail is fixed along the foundation surface on the foundation side, and intersects with the arrangement direction of the first guide rail located below on the upper structure side facing the foundation. A second guide rail oriented in a direction is fixed along a lower surface of the upper structure, and a connecting member is installed between the first guide rail and the second guide rail, With respect to the first guide rail side, the one end arranged on the first guide rail side is attached to the first guide rail so as to be movable on the first guide rail only by the arrangement method, and arranged on the second guide rail side. The other end of the guide is placed on the second guide rail. Floating prevention device seismic isolation structure, characterized in that attached to the second guide rail only to be movable in the laying direction. 2. The seismic isolation structure floating prevention device according to claim 1, wherein both ends of the connecting member are in contact with the first guide rail and the second guide rail, respectively. A device for preventing the seismic isolation structure from rising, comprising rolling means attached to roll along the guide rail when moving on the guide rail.