JP5252580B2 - Seismic isolation structure - Google Patents

Description

  The present invention relates to a structure having a base of a building as a base isolation structure, and more particularly to a base having a base isolation structure that is connected so that the building can be moved in a horizontal direction relative to the base.

  There are two main techniques for improving the strength of buildings against earthquakes. The first technique is a technique for improving the strength of the building itself. Since this building has an extremely strong structure, there is a drawback that the construction cost becomes high. In particular, the construction cost is extremely high in order to obtain a sufficient strength against a very strong earthquake. Buildings also have a unique resonance period. If the resonant period of the building and the period of the earthquake are the same, the building will be extremely damaged.

In order to avoid such an adverse effect, a second technology, that is, a structure for transmitting the vibration to the building via an elastic body even if the foundation vibrates due to an earthquake has been developed as a structure having a seismic isolation structure. . (See Patent Documents 1 and 2)
In the seismic isolation structure of Patent Document 1, a friction material is provided between the foundation and the building, and a horizontal movement mechanism that can move the building in the horizontal direction is provided. In the horizontal movement mechanism, an annular spring retaining member is fixed to the foundation side, and a spiral spring is disposed inside the spring stopper, and the inner end portion of the spiral spring is placed on the building. It is wrapped around the lower end and fixed. In the seismic isolation structure, the building moves in the horizontal direction due to the earthquake, and the spiral spring is elastically deformed. In other words, the horizontal movement of the building is restricted by a spiral spring.

  Furthermore, the seismic isolation structure of Patent Document 2 is provided with a sliding block so as to protrude downward from the building, and the lower surface of the sliding block is supported in surface contact with the upper surface of a cradle fixed to the foundation. Yes. At the time of an earthquake, the energy of the motion caused by the earthquake of the building is attenuated by the sliding frictional resistance in the horizontal direction between the sliding block and the cradle. Further, a cylindrical body is fixed to the cradle, and a hinged elastic or elastic-plastic member is provided between the cylindrical body and the sliding block so as to hold the sliding block at the center position of the cylindrical body. .

JP 2001-227197 A JP 11-311294 A

  Since the structure of the above seismic isolation structure is complicated, the manufacturing cost is high. In particular, there is a drawback that the structure of the elastic body that places the building in place is complicated. In addition, since the building is placed in a fixed position by providing an elastic body inside the annular spring retaining member or cylinder, the annular spring retaining member or cylinder moves in the horizontal direction relative to the foundation of the building due to an earthquake. There is a harmful effect of limiting the amplitude of the. Although it is possible to increase the amplitude in the horizontal direction by enlarging the annular spring-clamping member and the cylinder, there is a drawback in that if these are increased, a large protrusion is formed on the foundation, which becomes an obstacle. Further, there is a disadvantage that the equipment cost becomes higher if the annular spring stopper or the like is enlarged to increase the amplitude capable of moving in the horizontal direction.

The present invention has been developed for the purpose of solving the above drawbacks. An important object of the present invention is to provide a seismic isolation structure that can simplify the overall structure and reduce manufacturing costs.
An important object of the present invention is to provide a seismic isolation structure that can easily and inexpensively increase the horizontal amplitude relative to the foundation of a building.
Furthermore, an important object of the present invention is to provide a structure having a seismic isolation structure that can prevent the obstacles from becoming obstructed by increasing the horizontal amplitude due to the earthquake while reducing the protrusions protruding on the foundation. There is.

Means for Solving the Problems and Effects of the Invention

  The seismic isolation structure of the present invention includes a foundation 1, a building 50 connected to the foundation 1 so as to be movable in the horizontal direction, and the building 50 connected to the foundation 1 so as to be movable in the horizontal direction. The horizontal direction moving mechanism 2 is provided. The horizontal movement mechanism 2 includes a horizontal plate 3 provided on the upper surface of the foundation 1 and a sliding block fixed to the lower end of the building 50 and arranged on the horizontal plate 3 so as to be movable in a horizontal plane. 4 and a metal beam 5 fixed in a linearly extending posture on both sides of the sliding block 4 and deformed by an earthquake, and fixed to the foundation 1 and can move the metal beam 5 in the axial direction, but orthogonal to the axial direction. A pair of support portions 6 that are supported so as not to move in the direction to be moved, and an elastic body 7 that is disposed between the support portion 6 and the sliding block 4 are provided. In the horizontal movement mechanism 2, the sliding block 4 moves in the axial direction of the metal bar 5 to elastically deform the elastic body 7, and the sliding block 4 moves in the direction perpendicular to the axial direction of the metal bar 5 to move the metal. The crosspiece 5 is deformed.

  The structure having the above seismic isolation structure has a feature that the whole structure can be simplified and the manufacturing cost can be reduced. This is because the structure having the above-mentioned seismic isolation structure does not require an elastic body having a complicated structure and restricts movement relative to the foundation of the building with a metal bar and an elastic body in a linearly extending posture. In particular, a straight metal bar does not need to be processed into a complicated shape, and the manufacturing cost can be significantly reduced.

  Moreover, the structure of the above seismic isolation structure has the feature that the horizontal amplitude with respect to the foundation of the building can be easily increased at a low cost. This is because it is possible to increase the horizontal amplitude by lengthening the linear metal beam that does not need to be processed into a complicated structure. Further, the structure having the above-mentioned seismic isolation structure also realizes a feature that even if the horizontal amplitude due to the earthquake is increased, the protruding portion protruding to the foundation can be reduced to prevent them from getting in the way. The structure of the above seismic isolation structure does not need to be provided with an annular cylinder or the like protruding on the surface of the foundation to limit the horizontal movement as in the past, but with a metal beam extending in a straight line, This is because the movement is restricted.

  Furthermore, the structure having the above-mentioned seismic isolation structure has a feature that the upward restraining force with respect to the foundation of the building can be increased. It is a pair of support parts fixed to the foundation so that the metal beam fixed to the sliding block fixed to the lower end of the building can move in the axial direction but not in the direction perpendicular to the axial direction. It is because it supports. This structure suppresses the building from moving away from the foundation due to the vertical shaking of the earthquake, so the horizontal amplitude can be increased while reliably restricting upward movement relative to the foundation of the building. .

  In the seismic isolation structure of the present invention, the support 6 has a metal rod 5A as a pair of metal rods 5A formed by fixing the metal beam 5 in a linearly extending posture on both sides of the sliding block 4. The metal rod 5 </ b> A can be inserted into the elastic body 7 by including a through-hole 33 inserted so as to be movable in the direction.

  The seismic isolation structure according to the present invention has two support portions 6 as two metal plates 5B in which the metal bars 5 are fixed to both surfaces of the sliding block 4 and arranged in parallel to each other. A guide slit 34 for moving the metal plate 5B in the axial direction is provided, and the elastic body 7 can be disposed between the two metal plates 5B.

  In the seismic isolation structure of the present invention, the support 6 is fixed between the two metal plates 5B and fixed to the foundation 1 and the upper surface of the fixed column 31. A groove plate 32 having a pair of side wall portions 32B on both sides of the fixed plate portion 32A, and two metal plates 5B between the side wall portion 32B of the groove shape member 32 and the fixed column 31. A guide slit 34 can be provided for moving the shaft in the axial direction.

  The structure of the seismic isolation structure of the present invention can be provided with a through hole 33 through which the metal rod 5A is inserted in the axial direction in the fixed support 31.

  Furthermore, in the seismic isolation structure of the present invention, the elastic body 7 can be an elastic block 7X made of a rubber-like elastic body.

It is a vertical sectional view of the structure of the seismic isolation structure concerning one example of the present invention. It is a partial cross section top view of the structure of the seismic isolation structure shown in FIG. It is a partial cross section perspective view of the horizontal direction moving mechanism of the structure of the seismic isolation structure shown in FIG. FIG. 4 is an exploded perspective view of the horizontal movement mechanism shown in FIG. 3. It is a bottom perspective view of a sliding block. It is an expansion vertical sectional view of a support part, Comprising: It is a figure corresponded in the VI-VI line cross section of FIG. It is a perspective view of the structure of the seismic isolation structure concerning the other Example of this invention. It is sectional drawing of the coupling tool of the structure shown in FIG. It is a perspective view of the structure of the seismic isolation structure concerning the other Example of this invention. It is sectional drawing of the base fixing | fixed part of the coupling tool of the structure shown in FIG. It is a disassembled perspective view which shows the connection structure of the coupling tool of a structure of the seismic isolation structure concerning another Example of this invention, and a foundation.

  Embodiments of the present invention will be described below with reference to the drawings. However, the embodiment shown below exemplifies the structure of the base isolation structure for embodying the technical idea of the present invention, and the present invention does not specify the structure of the base isolation structure as follows. .

  Further, in this specification, in order to facilitate understanding of the scope of claims, numbers corresponding to the members shown in the examples are indicated in the “claims” and “means for solving problems” sections. It is added to the members. However, the members shown in the claims are not limited to the members in the embodiments.

  The seismic isolation structure shown in FIGS. 1 to 4 is connected to the foundation 1 by a horizontal movement mechanism 2 so that the building 50 can be moved in the horizontal direction. The horizontal movement mechanism 2 includes a horizontal plate 3 provided on the upper surface of the foundation 1 and a sliding block fixed to the lower end of the building 50 and arranged on the horizontal plate 3 so as to be movable in a horizontal plane. 4 and a metal beam 5 that is fixed in a linearly extending posture on both sides of the sliding block 4 and deformed by an earthquake, and is fixed to the foundation 1 and can move the metal beam 5 in the axial direction. A pair of support portions 6 that are supported so as not to move in a direction orthogonal to the support portion 6, and an elastic body 7 disposed between the support portion 6 and the sliding block 4 are provided.

  In the horizontal movement mechanism 2, the elastic body 7 and the metal bar 5 are deformed when the sliding block 4 fixed to the building 50 moves in the X-axis direction and the Y-axis direction. When the sliding block 4 moves in the X-axis direction, that is, moves in the axial direction of the metal bar 5, the elastic body 7 is elastically deformed, and when it moves in the direction perpendicular to the axial direction of the metal bar 5, which is the Y-axis direction, The metal bar 5 is deformed.

  The foundation 1 has a horizontal plate 3, which is a metal plate, fixed horizontally on a concrete foundation 10. The horizontal plate 3 is an iron plate or stainless steel plate having a thickness of 25 mm, a length of 2400 mm, and a width of 900 mm. The periphery of the horizontal plate 3 is fixed on the H-shaped steel 11 with bolts 12. In the foundation 1 of FIG. 1, an H-section steel 11 is arranged around a horizontal plate 3 and the H-section steel 11 is fixed to a concrete foundation 10. The H-shaped steel 11 is fixed to the concrete foundation 10 with the flange 11A in a horizontal posture, the horizontal plate 3 is fixed to the inner side of the upper flange 11A, and the reinforcing bar 13 is fixed to the outer side of the flange 11A by welding. The reinforcing bar 13 is embedded in the concrete foundation 10.

  2 and 3, the peripheral wall 14 is fixed in a square shape around the upper surface, and the outer side of the peripheral wall 14 is fixed to the inner side of the upper flange 11 </ b> A of the H-section steel 11. The peripheral wall 14 is a metal plate and is fixed to the horizontal plate 3 by welding. The horizontal plate 3 with the peripheral wall 14 fixed on the upper surface restricts the stroke in the X-axis direction in which the sliding block 4 reciprocates in the axial direction of the metal bar 5 and the stroke in the Y-axis direction orthogonal thereto with the peripheral wall 14. To do. This is because the sliding block 4 and the metal bar 5 fixed thereto are reciprocated inside the peripheral wall 14. The peripheral wall 14 in the figure has a shape that allows the sliding block 4 to reciprocate with a stroke of 200 mm in the X-axis direction and the Y-axis direction. However, the peripheral wall has a stroke in which the sliding block reciprocates in the X-axis direction and the Y-axis direction, for example, 100 mm or more, preferably 150 mm or more, and more preferably 180 mm or more.

  As shown in the sectional view of FIG. 1, the horizontal plate 3 is fixed to the concrete foundation 10 with the upper edge of the peripheral wall 14 being in the same horizontal plane as the ground line (GL) of the foundation 1. The H-section steel 11 has a reinforcing bar 13 welded to the lower flange 11 </ b> A, and the reinforcing bar 13 is embedded in the concrete foundation 10. Further, the H-shaped steel 11 connects the lower flange 11 </ b> A to the bottom of the foundation 1 through a vertical position adjusting tool 15 that adjusts the vertical position.

  The vertical position adjuster 15 fixes a screw rod 15B perpendicularly to the bottom plate 15A. The H-shaped steel 11 is provided with a through hole for the screw rod 15B outside the flange 11A. The vertical position adjusting tool 15 inserts a threaded rod 15B into which a nut 15C is screwed into a predetermined position through a through hole of the H-shaped steel 11, and rotates the nut 15C to adjust the vertical position of the H-shaped steel 11. After adjusting the vertical position of the H-shaped steel 11 by rotating the nut 15C so that the upper edge of the peripheral wall 14 fixed to the horizontal plate 3 is a ground line, the nut 15D is screwed into the screw rod 15B from above. The flange 11A of the H-section steel 11 is clamped by a pair of nuts 15C and 15D. In this state, ready-mixed concrete is placed, and the H-section steel 11 and the reinforcing bars 13 are fixed to the concrete foundation 10. The foundation 1 described above is a cover plate 16 that moves in the horizontal direction together with the building 50 in the event of an earthquake, and the opening of the recess formed inside the peripheral wall 14 can be closed to a flat surface. The cover plate 16 has an insertion hole 16 </ b> A that penetrates the sliding block 4 in the vertical direction and is open at the center. However, the cover plate can have a large opening hole through which the sliding block passes so that it does not move horizontally with the building in the event of an earthquake.

  The sliding block 4 is a quadrangular columnar metal block. The lower end surface of the sliding block 4 is placed on the upper surface of the horizontal plate 3 so that the upper portion is fixed to the building 50. The sliding block 4 of FIG. 5 is provided with a grease groove 17 on the lower end surface that slides on the foundation 1, and further has a grease path 18 that communicates with the grease groove 17. A grease nipple 19 is provided at the opening of the grease path 18. The sliding block 4 injects grease from the grease nipple 19 and stores the injected grease in the grease path 18 and the grease groove 17. The stored grease is supplied to the sliding surface between the sliding block 4 and the foundation 1 to reduce the frictional resistance between the sliding block 4 and the foundation 1. That is, when the foundation 1 vibrates due to an earthquake, the sliding block 4 can be smoothly slid on the horizontal plate 3 to reduce the acceleration acting on the building 50.

  The metal bar 5 has one end fixed to the sliding block 4 and the other end connected to the support portion 6 so as to be movable only in the axial direction. The metal bar 5 of FIGS. 1 to 4 is fixed to both sides of the sliding block 4 and a pair of metal rods 5A fixed in a linearly extending manner on both sides of the sliding block 4 and arranged in parallel to each other. It consists of two metal plates 5B.

  The metal rod 5 </ b> A is a metal round bar that is deformed by an earthquake. It is inserted so that it can only move. Further, the metal rod 5A is also inserted through the elastic body 7, and the elastic body 7 is arranged at a fixed position. The metal rod 5A is also inserted through the elastic body 7 so as to be movable in the axial direction. The metal rod 5A is an iron round bar having a diameter of 20 mm and a length of 800 mm. However, the metal rod may be a round rod made of metal such as iron or stainless steel having a diameter of 10 mm to 30 mm and a length protruding from the sliding block of 500 mm to 1000 mm.

  The metal bar 5 of the metal plate 5 </ b> B is a metal flat bar that is deformed by an earthquake, and is fixed to both surfaces of the lower end portion of the sliding block 4 with set screws 21. A female screw hole 22 is provided on the opposing surface of the lower end portion of the sliding block 4 to screw the metal plate 5B. The distance between the two metal plates 5 </ b> B fixed to both surfaces of the sliding block 4 is specified by the lateral width of the sliding block 4. The lateral width of the sliding block 4 is specified to a dimension in which the inner distance between the two metal plates 5B is, for example, 120 mm. 2 to 4, the spacer 23 is fixed between the sliding block 4 and the metal plate 5B. Therefore, the thickness of the spacer 23 is added to the lateral width of the sliding block 4. The dimension becomes the inner space between the two metal plates 5B. The inner space between the two metal plates 5B is specified by the lateral width of the elastic body 7 disposed here. In the structure in which the elastic body 7 having a narrow width is arranged, the inner space between the two metal plates 5B is narrowed, and in the structure in which the elastic body 7 having a wide width is arranged, the two metal plates 5B are arranged. Increase the inner spacing. Accordingly, the inner distance between the two metal plates 5B is, for example, 50 mm to 300 mm, preferably 100 mm to 200 mm.

  The metal plate 5B is made of a spring material that is elastically deformed, such as carbon fiber or stainless steel. When the horizontal plate 3 vibrates due to an earthquake, the spring metal plate 5B acts to push the sliding block 4 back to the center because a force to restore the linear plate 3 acts. For this reason, there is a feature that the sliding block 4 can approach the center after the earthquake. However, it is not always necessary to use a spring material for the metal plate. This is because when the horizontal plate 3 vibrates due to an earthquake, the metal plate 5B is deformed and transmitted to the sliding block 4 while absorbing the energy of the earthquake.

  The thickness of the metal plate 5B, ie, the ease of deformation, is the force by which the horizontal plate 3 swaying in the Y-axis direction that is perpendicular to the longitudinal direction of the metal plate 5B vibrates the building 50 in the horizontal direction. Influence. A thin and easily deformable metal plate has a weak force that the horizontal plate that vibrates in the horizontal direction vibrates the building. On the other hand, a thick and difficult-to-deform metal plate has a force that causes the horizontal plate that vibrates in the horizontal direction to vibrate the building. Become stronger. Therefore, the thickness of the metal plate 5B is set to an optimum value in consideration of the force that the horizontal plate 3 that vibrates in the horizontal direction vibrates the building 50, that is, the acceleration. Further, the metal plate 5 </ b> B of the metal bar 5 fixed to the sliding block 4 is also changed by the load acting on the sliding block 4. A thick and hard-to-deform metal plate is used for the high-load sliding block that acts, and a thin and easy-to-deform metal plate is used for the small-load sliding block that acts. For example, the two metal plates 5B, which are the metal bars 5, use iron plates having a thickness of 20 mm and a vertical width of 150 mm. However, the metal plate may have a thickness of 10 mm to 50 mm and a vertical width of 50 mm to 200 mm.

  The seismic isolation structure shown in FIGS. 1 to 4 has an overall length of the metal plate 5B of 180 mm and a longitudinal interval of the peripheral wall 14 of 220 mm, and a distance of 200 mm between the tip of the metal plate 5B and the inner surface of the peripheral wall 14. Is provided. This structure can reciprocate the sliding block 4 with a stroke of 200 mm in the longitudinal direction of the metal plate 5B. The metal rod 5 </ b> A and the metal plate 5 </ b> B have their front end surfaces on the same surface, and have their front ends connected to the support portion 6.

  In the structure having the above-described seismic isolation structure, the metal bar 5 includes the metal rod 5A and the metal plate 5B. However, in the seismic isolation structure according to the present invention, the metal beam can be configured only by the metal rod, or the metal beam can be configured only by the metal plate.

  The support portions 6 are disposed on both sides of the sliding block 4 and are fixed to the foundation 1. In the seismic isolation structure shown in FIG. 4, the support 6 is fixed to the upper surface of the horizontal plate 3. The support portions 6 disposed on both sides of the sliding block 4 connect the metal rod 5A and the metal plate 5B in a posture extending on both sides of the sliding block 4 so as to be movable only in the axial direction. The support portion 6 has a through hole 33 through which the metal rod 5A is inserted. The metal rod 5A is inserted into the through hole 33 so that the metal rod 5A can be moved only in the axial direction. Further, the support portion 6 has a guide slit 34 for guiding the two metal plates 5B. The metal plate 5B is inserted into the guide slit 34 so that the metal plate 5B can be moved only in the axial direction. ing. The support portion 6 shown in the drawing has the metal rod 5 </ b> A and the tip of the metal plate 5 </ b> B outside the support portion 6 so that the sliding block 4 can reciprocate with a predetermined stroke in the X-axis direction that is the longitudinal direction of the metal bar 5. Protruding.

  The support portion 6 shown in FIGS. 4 and 6 is positioned between the two metal plates 5B, and is fixed to the fixed column 31 fixed to the horizontal plate 3 of the foundation 1 and the upper surface of the fixed column 31. And a groove member 32 that holds the two metal plates 5B in place.

  The fixed support 31 is a metal block, and is provided with a through hole 33 through which the metal rod 5A is inserted so as to penetrate in the axial direction. The inner shape of the through hole 33 is slightly larger than the outer shape of the metal rod 5A so that the metal rod 5A inserted through the through hole 33 can be smoothly moved in the axial direction. The fixed column 31 which is a metal block is fixed to the upper surface of the horizontal plate 3 by a method such as welding or bolting. The fixed support 31 which is a metal block is firmly fixed to the horizontal plate 3 and reliably receives the reaction of the force acting on the sliding block 4 via the elastic body 7 when the horizontal plate 3 vibrates due to an earthquake. be able to. However, the fixed strut is not necessarily a metal block, the bottom surface is fixed to the horizontal plate, the groove shape material is fixed to the upper part, and a through hole through which the metal rod is inserted can be provided. A metal material having a shape, for example, a cross-sectional shape that is L-shaped, C-shaped, or U-shaped can also be used.

  The groove member 32 has a pair of side wall portions 32B on both sides of the fixed plate portion 32A, and has a U-shaped cross section. The groove member 32 is fixed to the upper surface of the fixed column 31 via a set screw 35 that passes through the fixed plate portion 32A. The fixed column 31 has a female screw hole 36 into which the set screw 35 is screwed on the upper surface. The groove member 32 fixes the fixed plate portion 32A to the fixed column 31 in a posture in which the pair of side wall portions 32B faces downward, and is on both sides of the fixed column 31 and between the pair of side wall portions 32B. A guide slit 34 for guiding the metal plate 5B is provided. The inner width of the guide slit 34 is slightly larger than the thickness of the metal plate 5B so that the metal plate 5B guided by the guide slit 34 can be smoothly moved in the axial direction.

  In the horizontal movement mechanism 2, the force with which the horizontal plate 3 that shakes due to an earthquake vibrates the building 50 in the horizontal direction also varies depending on the distance between the pair of support portions 6 disposed on both sides of the sliding block 4. For example, if the distance between the pair of support portions is widened, the entire length of the elastic body disposed on both sides of the slide block and between the slide block and the support portion becomes longer. If is narrowed, the total length of the elastic body is shortened. When the entire length of the elastic body is increased, the elastic plate easily contracts in the X-axis direction, which is the axial direction of the metal rail, and the force that the horizontal plate that swings in the X-axis direction vibrates the building is weakened. On the contrary, when the total length of the elastic body is shortened, the elastic plate is less likely to contract in the X-axis direction, and the force that the horizontal plate that vibrates in the X-axis direction vibrates the building becomes stronger. In addition, when the distance between the pair of support portions is increased, the distance at which the both ends of the metal rail extending on both sides of the sliding block are supported by the support portion is increased, and the metal rail is in the Y-axis direction, which is a direction perpendicular to the longitudinal direction. It becomes easy to deform. That is, if the distance between the pair of support portions is widened, the metal bar is easily deformed in the Y-axis direction, and the force that the horizontal plate that swings in the Y-axis direction vibrates the building is weakened. On the other hand, when the distance between the pair of support portions is narrowed, the metal bar is not easily deformed in the Y-axis direction, and the force of the horizontal plate that swings in the Y-axis direction vibrates the building. Therefore, the distance between the pair of support portions 6 takes into consideration the ease of deformation of the metal rod 5A and the metal plate 5B in the Y-axis direction and the ease of contraction of the elastic body 7 in the X-axis direction (elastic coefficient). And set the optimal interval.

  As shown in FIGS. 3 and 4, the elastic body 7 is arranged on both sides of the sliding block 4, and the elastic body 7 is arranged on the sliding block 4 that moves relative to the horizontal plate 3 in the axial direction of the metal bar 5. It is pressed and elastically deformed. Each elastic body 7 is arranged between the two metal plates 5B and between the sliding block 4 and the support portion 6 as shown in the figure. The elastic body 7 in FIG. 4 is a quadrangular columnar elastic block 7 </ b> X extending in the axial direction of the metal bar 5. The elastic body 7 which is the elastic block 7X is opened around an insertion hole 7A extending in the axial direction, and the metal rod 5A is inserted into the insertion hole 7A to fix the sliding block 4 and the support column 31 of the support portion 6. It is arranged at a fixed position between. The elastic body 7 which is the elastic block 7X is a rubber-like elastic body. However, the elastic body can be a coil spring. The elastic body, which is a coil spring, is disposed between the sliding block and the support portion by inserting a metal rod in the axial direction of the coil. The elastic body 7 made of a rubber-like elastic body or a coil spring effectively uses the energy of the earthquake acting between the support portion 6 and the sliding block 4 by contracting in the X-axis direction, which is the axial direction of the metal bar 5. Absorbs vibrations quickly and attenuates vibrations.

  The seismic isolation structure is connected to the foundation 1 via the horizontal movement mechanism 2 so that the building 50 can be moved in the horizontal direction. FIG. 1 shows a building 50 having a steel structure, and a sliding block 4 is fixed to the lower end of a column 51 of the steel building 50 so as to be connected to the foundation 1 through a horizontal movement mechanism 2. The column 51 is a hollow pipe, and the upper part of the sliding block 4 is inserted and fixed in the hollow part of the pipe, and the sliding block 4 is fixed to the column 51. The outer shape of the sliding block 4 shown in FIG. 2 is substantially equal to the inner shape of the hollow pipe so as to be inserted into the column 51 which is a hollow pipe. The sliding block 4 which is a metal block is fixed to the lower end of the column 51 by a method such as welding or bolting.

  FIG. 7 shows a wooden building 50 having a sliding block 4 provided at the lower end of a connector 55 for fixing the base 52 of the wooden building 50 in order to connect to the foundation 1 via the horizontal movement mechanism 2. Yes. In the illustrated connecting tool 55, the sliding block 4 is fixed to a fixing portion 55 </ b> C that protrudes downward from a base fixing portion 55 </ b> A that connects the base 52 of the building 50. The sliding block 4 which is a metal block is fixed to the lower end of the connector 55 by a method such as welding or bolting. The sliding block 4 is placed on the horizontal plate 3 so as to be movable in the horizontal direction. However, although not shown in the drawings, the connection tool can fix a pillar that is a hollow pipe projecting downward from a base fixing portion that connects the base, and can be fixed by inserting a sliding block at the lower end of the pillar.

  In the building 50 shown in FIG. 7, the connecting tool 55 arranged at the corner of the building 50 is configured such that the planar shape of the base fixing portion 55 </ b> A is L-shaped to fit the corner of the base 52. Further, the connector 55 arranged on the side of the building 50 is configured such that the planar shape of the base fixing portion 55 </ b> A is a straight line that fits in the middle of the base 52. Further, the base fixing portion 55A shown in FIGS. 7 and 8 has a groove shape in which the base 52 is inserted. The base fixing portion 55A of this shape has a feature that the base 52 can be connected easily and reliably.

  In the building 50 of FIG. 7, a base 52 of a wooden pillar is fixed to a base fixing part 55 </ b> A of the connector 55. The base 52 of the wooden column is, for example, a square member having a height of 300 mm and a width of 100 mm, and an end portion is inserted into a groove portion of the base fixing portion 55A and is fixed to the base fixing portion 55A by bolting. However, although not shown in the figure, the connecting tool can be provided with a female screw hole penetrating the side surface of the base fixing portion, and a base screw can be fixed by screwing a set screw into the female screw hole.

  In the building 50 of FIG. 7, the base 52 is made of wood, but the base 52 may be made of metal as shown in FIG. In the building 50 in FIG. 9, a metal base 52 is fixed to a base fixing portion 55 </ b> A of the connector 55. Therefore, the connector 55 does not need to fix the base of the wooden pillar to the base fixing portion 55A. However, although not shown, a wooden base may be placed on a metal base. As shown in FIG. 9, the building 50 in which the base 52 is made of metal has a horizontal structural member 53 such as a wooden joist fixed on the upper surface of the base 52, and the floor (not shown) of the building 50 on the upper surface. Is built.

  The metal base 52 shown in FIG. 9 is a channel having a U-shaped cross-section, and the cross-sectional shape of the base fixing portion 55A connecting the cross-section is U-shaped along the cross-section of the base 52 as shown in FIG. It is in the shape. The metal base 52 and the base fixing portion 55A can have a U-shaped outer shape of, for example, 300 mm × 100 mm. However, although the metal base is not shown in the drawing, it can be H-shaped steel, I-shaped steel, square pipe, or groove-shaped steel having a C-shaped cross section. The base fixing part of the connector for connecting the metal bases of these shapes can have a cross-sectional shape that can connect the bases of these shapes. The metal base 52 and the base fixing portion 55 </ b> A that are channels are connected to each other via a connection plate 54. The connection plate 54 shown in FIG. 9 has one end fixed to the base fixing portion 55 </ b> A and the other end fixed to the metal base 52. The connection plate 54 is bolted and connected to the base fixing portion 55 </ b> A and the metal base 52. For example, as shown in FIG. 10, the metal base 52 and the base fixing portion 55 </ b> A are connected to each other by a connecting plate 54 on one side surface and upper and lower surfaces. The connecting plate 54 shown in this figure is disposed on the inside and outside of the base fixing portion 55A and the base 52 having a U-shaped cross section, and the base fixing portion 55A and the base 52 are connected to the two connecting plates 54. It is fixed in a state of being pinched from inside and outside. This connection structure can connect the base fixing part 55A and the base 52 most firmly. However, the connection plate can connect only the base fixing part and the inner side surface of the base, or can connect only the outer side surface.

  Furthermore, the connection tool 55 which makes the cross-sectional shape of the base fixing | fixed part 55A U-shape can also connect the wooden base 52 with the structure shown in FIG. The base 52 shown in this figure has an insertion portion 52A for cutting the outer peripheral surface of the tip portion and inserting it into the base fixing portion 55A so that the end portion can be fitted inside the base fixing portion 55A having a U-shaped cross section. Is provided. This connection structure has an advantage that it can be connected to an accurate position while specifying the connection position between the base fixing part 55A and the base 52 by the depth of the insertion part 52A. The insertion portion 52A inserted into the base fixing portion 55A is fixed to the base fixing portion 55A by bolting or screwing.

  The connecting tool 55 for connecting the base 52 as a wooden or metal is provided with a column fixing portion 55B at a portion where the column 51 is fixed. The column fixing portion 55B is a rectangular pipe that is connected by inserting the lower end of the column 51, a metal material from which one surface or two opposite surfaces of the rectangular pipe are removed, or a combination of a plurality of metal plates. . The connecting tool 55 shown in FIG. 8 is a column fixing portion 55B in which a metal plate is bent into a groove shape and a base fixing portion 55A is provided at both ends, and two metal plates serving as partitions are fixed in the middle. . 7 to 9 and FIG. 11, the column fixing portion 55B for inserting and fixing the column 51 is integrally fixed to the base fixing portion 55A. The connector 55 arranged at the corner of the building 50 has a shape in which the base fixing portion 55A is connected to the side surface adjacent to the column fixing portion 55B, and the connector 55 arranged at the side of the building 50 is linear. A column fixing portion 55B is provided between the pair of base fixing portions 55A to be arranged. The base fixing portion 55A is welded and fixed to the column fixing portion 55B, or is bolted and fixed to the column fixing portion. Furthermore, the connection tool 55 shown in the figure has the upper end surfaces of the column fixing portion 55B and the base fixing portion 55A as the same surface. However, the column fixing portion can be protruded from the upper end of the base fixing portion. The column 51 to be inserted into the column fixing portion 55B is fixed to the column fixing portion 55B by bolting, or although not shown, a set screw is screwed into a female screw hole provided through the side surface of the column fixing portion. Fixed.

  The seismic isolation structure described above is connected to the foundation 1 through the horizontal movement mechanism 2 at all locations at the lower end of the building 50, and the entire building is elastically limited in the horizontal plane. It can be moved with. Since this structure moves all the places of the lower end part of the building 50 elastically with respect to the foundation 1, it can be set as the most ideal seismic isolation structure. However, the structure of the seismic isolation structure of the present invention does not necessarily have to be provided with a horizontal movement mechanism at all locations at the lower end of the building, but is provided with a horizontal movement mechanism at a part of the lower end of the building. And can be linked to the foundation. In this structure, the lower end of the building in which the horizontal movement mechanism is arranged moves while being elastically restricted with respect to the foundation, and the lower end of the building in which the horizontal movement mechanism is not arranged is elastically The top surface of the foundation is moved horizontally in synchronization with the entire building where movement is restricted. In this structure, for example, the lower end portion located at the corner of the building is connected to the foundation via a horizontal movement mechanism, and the lower end portion located on the side of the building is connected to the foundation without the horizontal movement mechanism. It can arrange | position so that it can move to the upper surface of this, and can make it a seismic isolation structure efficiently. Since this structure can reduce the number of places where the horizontal movement mechanism is disposed, the manufacturing cost can be reduced.

DESCRIPTION OF SYMBOLS 1 ... Foundation 2 ... Horizontal direction moving mechanism 3 ... Horizontal plate 4 ... Sliding block 5 ... Metal bar 5A ... Metal rod
5B ... Metal plate 6 ... Supporting part 7 ... Elastic body 7X ... Elastic block
7A ... Insertion hole 10 ... Concrete foundation 11 ... H-shaped steel 11A ... Flange 12 ... Bolt 13 ... Reinforcement 14 ... Perimeter wall 15 ... Vertical position adjuster 15A ... Bottom plate
15B ... Screw rod
15C ... Nut
15D ... Nut 16 ... Cover plate 16A ... Insertion hole 17 ... Grease groove 18 ... Grease path 19 ... Grease nipple 21 ... Set screw 22 ... Female screw hole 23 ... Spacer 24 ... Fixing hole 31 ... Fixing post 32 ... Groove shape member 32A ... Fixed plate
32B ... Side wall 33 ... Through hole 34 ... Guide slit 35 ... Set screw 36 ... Female screw hole 50 ... Building 51 ... Pillar 52 ... Base 52A ... Insertion part 53 ... Horizontal structural member 54 ... Connection plate 55 ... Connection tool 55A ... Base Fixed part
55B ... Column fixing part
55C ... fixed part

Claims (6)

A foundation (1), a building (50) connected to the foundation (1) movably in the horizontal direction, and this building (50) connected to the foundation (1) movably in the horizontal direction. A seismic isolation structure comprising a horizontal movement mechanism (2) comprising:
The horizontal movement mechanism (2) is a horizontal plate (3) provided on the upper surface of the foundation (1), and is fixed to the lower end of the building (50), and a horizontal plane is placed on the horizontal plate (3). A sliding block (4) arranged so as to be movable in, a metal bar (5) deformed by an earthquake fixed in a linearly extending posture on both sides of the sliding block (4), and A pair of support portions (6) fixed to the foundation (1) and supported so that the metal bar (5) can be moved in the axial direction but not in a direction perpendicular to the axial direction, and the support portions (6) and an elastic body (7) disposed between the sliding block (4),
The sliding block (4) moves in the axial direction of the metal bar (5) to elastically deform the elastic body (7), and the sliding block (4) is orthogonal to the axial direction of the metal bar (5). A structure having a seismic isolation structure which moves in the direction to deform the metal bar (5).   The metal bar (5) is a pair of metal rods (5A) fixed in a posture extending linearly on both sides of the sliding block (4), and the support portion (6) is the metal rod (5A). The base-isolated structure according to claim 1, further comprising a through-hole (33) inserted so as to be movable in an axial direction, and the metal rod (5A) being inserted through the elastic body (7). Structure.   The metal bar (5) is fixed to both surfaces of the sliding block (4) and is provided with two metal plates (5B) arranged in parallel to each other. 3. A guide slit (34) for moving the metal plate (5B) in the axial direction, and the elastic body (7) is disposed between the two metal plates (5B). Structure of seismic isolation structure described in 1.   The support portion (6) is located between the two metal plates (5B), and is fixed to the base (1) and fixed on the upper surface of the fixed support (31). A groove plate (32) having a pair of side wall portions (32B) on both sides of the fixed plate portion (32A) formed by fixing, and the side wall portion (32B) of the groove shape member (32) and the fixed column ( The seismic isolation structure according to claim 3, wherein a guide slit (34) for moving the two metal plates (5B) in the axial direction is provided between the two metal plates (5B).   The seismic isolation structure structure according to claim 4, wherein a through hole (33) is provided in the fixed support post (31) for inserting the metal rod (5A) in the axial direction.   6. The seismic isolation structure according to claim 1, wherein the elastic body (7) is an elastic block (7X) made of a rubber-like elastic body.

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