JP2023026808A - Movement regulating device - Google Patents

Abstract

[Problem] To provide a movement restriction device capable of preventing damage to a building or a retaining wall caused by an upper structure colliding with a retaining wall, etc. [Solution] The movement restriction device includes a first bundle, a pair of second bundles 23, a buffer member, a deformable member 24, and a pin joint 25 that joins the second bundles 23 and the deformable member 24, and when the amount of relative movement of the upper structure with respect to the lower structure reaches or exceeds a predetermined amount, the deformable member 24 is pressed against one of the first bundles 23 and the second bundles 23 via the buffer member to deform and absorb kinetic energy, and restricts the amount of movement to or below the limit displacement of the seismic isolation layer, and the pin joint 25 includes a splice plate 252 fixed to the second bundles 23 and having a bolt hole 252a formed therein, a long hole 243a formed in the deformable member 24 and long in the opposing direction in which the pair of second bundles 23 face each other, and a bolt inserted through the bolt hole 252a and the long hole 243a to fasten a nut. [Selected Figure] Figure 4

Description

The present invention relates to a movement restricting device.

A support structure called a seismic isolation layer, which is greatly deformed during an earthquake, is provided in the foundation of a building or in the intermediate layer of a building having an upper structure and a lower structure. The seismic isolation layer is configured using, for example, laminated rubber or a spring. Due to the presence of the seismic isolation layer, when an earthquake occurs, the seismic isolation layer deforms greatly, reducing the response of the building above the seismic isolation layer and suppressing damage to the building. In the design of a building, the deformation of the seismic isolation layer against the assumed seismic motion is usually calculated and the necessary clearance is set.

In a base-isolated building having a base isolation layer on its foundation, an appropriate clearance is secured between the building and a retaining wall provided on the foundation side, and the building is prevented from colliding with the retaining wall. In a seismically isolated building with a seismic isolation layer installed in the middle floor, it is necessary to secure an appropriate clearance for elevator shafts and equipment piping in the middle floor.

In recent years, the need for a fail-safe mechanism against unexpected seismic motion has increased. In particular, in seismic isolation buildings, there is a demand for excessive deformation suppression mechanisms to prevent collisions with retaining walls and breakage of seismic isolation devices when the seismic isolation layer is excessively deformed.

In order to prevent excessive deformation of the seismic isolation layer, for example, a technique related to a fail-safe mechanism described in Patent Literature 1 is known. This fail-safe mechanism includes a plate-like member fixed in parallel with the damper, and one end of the plate-like member is pin-joined to a circular hole and the other end is pin-joined to an elongated hole. There are also known techniques related to collision buffering using rubber or the like in order to mitigate the impact on the building when the building collides with the retaining wall (see, for example, Patent Documents 2 to 4).

JP 2019-163678 A JP 2014-77229 A JP 2015-183495 A JP-A-2000-345738

The fail-safe mechanism described in Patent Document 1 is often provided separately from the damper designed for damping the building, and a complicated mechanism such as a bar-shaped member for suppressing excessive deformation is separately provided. and increase costs. In addition, in order to suppress excessive deformation by using a collision-absorbing material using rubber or the like as in the technology described in Patent Document 2, etc., a very large number of units are required, and if the scale of the building is large, a collision Arrangement of cushioning material becomes difficult. Furthermore, according to this technique, there is a risk that the retaining wall will yield after excessive deformation, which may hinder the continued use of the building.

Accordingly, the present invention has been made in view of the above circumstances, and provides a movement restricting device capable of suppressing damage to a building or a retaining wall due to collision of an upper structure with a retaining wall or the like.

In order to achieve the above object, the present invention employs the following means.
That is, a movement regulating device according to the present invention is a movement regulating device installed in a seismic isolation layer between an upper structure and a lower structure arranged below the upper structure, wherein the upper structure a pair of second bundles of materials that move in conjunction with the lower structure and are arranged to face each other with a gap therebetween; the first bundles of materials and the a cushioning member fixed to one of the second bundles of materials; a deformable member; and a pin joint portion that joins the second bundle of materials and the deformable member; When the amount of relative movement of the upper structure with respect to the upper structure reaches a predetermined amount or more, it is pressed by one of the first bundle material and the second bundle material through the buffer member and deformed to release kinetic energy. The movement amount is regulated to be less than the limit displacement of the seismic isolation layer, and the pin joint portion is fixed to the second bundle material and formed in a splice plate having a bolt hole formed therein and the deformable member. and a long hole elongated in the opposite direction in which the pair of second bundle materials are opposed, and a bolt inserted through the bolt hole and the long hole and fastened with a nut.

In the movement restricting device configured in this way, when the relative movement amount between the upper structure and the lower structure occurs, the deformable member joined to the second bundle of materials by the pin joint rotates. , Since the deformable member restricts the amount of movement below the limit displacement of the seismic isolation layer, the seismic isolation device is damaged or broken due to excessive deformation, and the upper structure collides with the retaining wall, etc., damaging the building and retaining wall. can be prevented.

Further, in the movement restricting device according to the present invention, the deformable member includes a long member extending in the facing direction, both ends of which are joined to the second bundle of materials, and a space between the long members in the facing direction. and a plurality of rib plates secured together.

In the movement restricting device configured in this manner, a plurality of rib plates are fixed to the deformable member at intervals in the opposing direction (extending direction of the long member). Therefore, local deformation of the long member can be suppressed.

Further, in the movement restricting device according to the present invention, the elongated member is an H-shaped steel arranged with the plate surface of the web facing the vertical direction, and the rib plate has the plate surface facing the opposite direction. may be placed.

In the movement restricting device configured in this manner, the deformable member is formed by providing the rib plate between the flanges of the H-section steel, so the deformable member can be easily manufactured.

Moreover, in the movement restricting device according to the present invention, the deformable member may be replaceable.

In the movement restricting device configured in this manner, the deformable member can be replaced when residual deformation occurs in the deformable member.

Moreover, in the movement restricting device according to the present invention, the deformation member may be plastically deformed to absorb the kinetic energy.

In the movement restricting device configured in this way, the deformable member bends and deforms plastically, so that it is possible to absorb kinetic energy generated when a relative movement amount occurs between the deformable member and the lower structure.

According to the movement restricting device of the present invention, it is possible to prevent the upper structure from colliding with a retaining wall or the like and damaging the building or the retaining wall.

1 is a diagram schematically showing a building in which a movement regulating device according to an embodiment of the invention is installed; FIG. It is the figure which showed typically the movement control apparatus which concerns on one Embodiment of this invention. It is a figure which shows the exchange method of the deformation|transformation member of the movement control apparatus which concerns on one Embodiment of this invention. FIG. 4 is a diagram showing a method of exchanging a deformable member of the movement restricting device according to the embodiment of the present invention, showing a post-process of FIG. 3 ; It is a figure which shows the pin joint part of the movement control apparatus which concerns on one Embodiment of this invention. FIG. 4(b) is an enlarged view of (a) showing a rotation follow-up mechanism of a movement restricting device according to an embodiment of the present invention; Fig. 4 shows experimental results of a movement restricting device according to an embodiment of the present invention, showing a deformation relationship between a load and deformation of an energy absorbing member; Fig. 6 shows experimental results of a movement restricting device according to an embodiment of the present invention, showing a deformation relationship between a load and an amount of rotation of an end portion of an energy absorbing member; It is a figure which shows the data of the model of the building for analysis. It is a figure which shows the relationship between the story drift angle and the layer number in an analysis. It is a figure which shows the relationship between the acceleration and layer number in an analysis.

An embodiment of a movement restricting device according to the present invention will be described below with reference to the drawings.

As shown in FIG. 1 , the building 1 includes an upper structure 2 , a lower structure 3 arranged below the upper structure 2 , and a movement restricting device (fail-safe stopper) 20 . A seismic isolation layer 10 is provided between the upper structure 2 and the lower structure 3 . The seismic isolation layer 10 movably supports the upper structure 2 with respect to the lower structure 3 . The building 1 is, for example, a base isolation building having a base isolation layer 10 on the foundation side. The building 1 may be a base isolation building having a base isolation layer 10 in the middle layer.

The superstructure 2 is, for example, a multistory building. The lower structure 3 is a structure integrated with the foundation of the building 1 when the building 1 is a base-isolated building having a base isolation layer 10 provided on the foundation side. The lower structure 3 is a building having multiple floors when the building 1 is a base-isolated building in which the base-isolating layer 10 is provided in the middle layer.

The seismic isolation layer 10 is provided with, for example, laminated rubber in which rubber plates and steel plates, which are elastic members, are alternately laminated. The seismic isolation layer 10 is configured to elastically deform when relative displacement occurs between the upper structure 2 and the lower structure 3 during an earthquake, thereby making it difficult for the displacement of the lower structure 3 to be transmitted to the upper structure 2. It is As the laminated rubber, other elastic members such as a metal spring may be used in addition to the rubber plate.

A movement restricting device 20 is installed on the seismic isolation layer 10 to restrict the amount of relative movement of the upper structure 2 with respect to the lower structure 3 . A seismic isolation structure 30 is configured by combining the seismic isolation layer 10 and the movement restricting device 20 .

As shown in FIG. 2 , the movement restricting device 20 includes a first bundle 21 , a cushioning member 22 , a pair of second bundles 23 , a deformation member 24 and a pin joint portion 25 . Here, the facing direction along the horizontal plane of the pair of second bundles 23 facing each other with a gap therebetween is defined as the X direction (opposing direction). A direction perpendicular to the X direction along the horizontal plane is defined as the Y direction.

The first bundle 21 is provided under the upper structure 2 (see FIG. 1). The first bundle 21 is formed to protrude downward from the lower portion of the upper structure 2 . The first bundle 21 is formed integrally with the lower portion of the upper structure 2, for example. If the first bundle 21 is separate from the lower portion of the upper structure 2, it is fixed to the lower portion of the upper structure 2 so as to ensure sufficient strength. The first bundle 21 moves in conjunction with the upper structure 2 .

The first bundle 21 is made of H-shaped steel, for example. The first bundle 21 has a pair of first flanges 211 , a first web 212 and a lower rib 213 .

The first flange 211 is formed in a plate shape. The plate surface of the first flange 211 faces the Y direction. The pair of first flanges 211 are arranged facing each other in the Y direction.

The first web 212 connects the pair of first flanges 211 together. The first web 212 is formed in a plate shape. The plate surface of the first web 212 faces the X direction.

The lower ribs 213 are provided on both sides of the plate surface of the first web 212 at the lower portion of the first web 212 . A lower rib 213 is provided to connect the pair of first flanges 211 . The lower rib 213 is joined to the pair of first flange 211 and first web 212 by welding or the like. Lower rib 213 is formed in a plate shape. The lower rib 213 is formed in a substantially rectangular shape in plan view. The plate surface of the lower rib 213 faces the vertical direction. A plurality of lower ribs 213 are provided at intervals in the vertical direction. In this embodiment, three lower ribs 213 are provided.

It should be noted that one more first bundle 21 may be arranged at positions opposite to each other in the Y direction with a deformation member 24 to be described later interposed therebetween.

The cushioning member 22 is fixed to the surface of the first bundle 21 facing the deformation member 24 side. In this embodiment, the cushioning member 22 is fixed to the surface 211a of the first flange 211 of the first bundle 21 facing the deformation member 24 side. The buffer member 22 is formed of an elastic member such as rubber, for example.

The second bundle 23 is provided above the lower structure 3 (see FIG. 1). The second bundle 23 is formed to protrude upward from the upper portion of the lower structure 3 . The second bundle 23 is formed integrally with the upper portion of the lower structure 3 . If the second bundle 23 is separate from the upper portion of the lower structure 3, it is fixed to the upper portion of the lower structure 3 so as to ensure sufficient strength. The second bundle 23 moves in conjunction with the lower structure 3 .

The pair of second bundles 23 are arranged with a gap in the X direction. The second bundle 23 is made of H-shaped steel, for example. The second bundle 23 has a pair of second flanges 231 , a second web 232 and a pair of cover plates 233 and 234 .

The second flange 231 is formed in a plate shape. A plate surface of the second flange 231 faces the Y direction. The pair of second flanges 231 are arranged to face each other in the Y direction.

The second web 232 connects the pair of second flanges 231 together. The second web 232 is formed in a plate shape. The plate surface of the second web 232 faces the X direction.

The cover plate 233 connects the ends of the pair of second flanges 231 on the center side in the X direction (the side closer to the other second bundle of materials 23). The cover plate 234 connects the ends of the pair of second flanges 231 on the X-direction end side (the side farther from the other second bundle 23 side). The cover plates 233 and 234 are joined to the pair of second flanges 231 by welding or the like. The cover plates 233 and 234 are plate-shaped. The cover plates 233, 234 are formed in a substantially rectangular shape. The plate surfaces of the cover plates 233 and 234 face the X direction. The cover plates 233 and 234 can resist the torsional stress of the second bundle 23 and the beam axial force at the time of oblique collision. A hand hole 233a is formed through the cover plate 233 in the plate thickness direction.

As shown in FIG. 3, a mounting plate 235 is provided above the cover plate 233 . The mounting plate 235 is provided to connect the pair of second flanges 231 . The mounting plate 235 is joined to the pair of second flanges 231 and second webs 232 by welding or the like. The mounting plate 235 is formed in a plate shape. The mounting plate 235 is formed in a substantially rectangular shape in plan view. The plate surface of the mounting plate 235 faces the vertical direction.

A plurality of bolt holes 235a are formed through the mounting plate 235 in the plate thickness direction. The bolt hole 235a has a substantially circular shape in plan view. The diameter of the bolt hole 235a corresponds to the diameter of the bolt 256 (see FIG. 2) to be inserted. The plurality of bolt holes 235a are arranged at intervals in the Y direction.

As shown in FIG. 2, the deformation member 24 is joined to the second bundle of materials 23 by a pin joint portion 25, which will be described later. The deformation member 24 has an elongated member 241 and a plurality of rib plates 246 .

The long member 241 is made of H-section steel, for example. The long member 241 has a shape elongated in the X direction. Elongated member 241 has a pair of flanges 242 and a web 243 .

The flange 242 is formed in a plate shape. A plate surface of the flange 242 faces the Y direction. A pair of flanges 242 are arranged to face each other in the Y direction.

A web 243 connects the pair of flanges 242 . The web 243 is formed in a plate shape. The plate surface of the web 243 faces the vertical direction.

A rib plate 246 is provided on the upper surface of the web 243 . A rib plate 246 is provided to connect the pair of flanges 242 . The rib plate 246 is joined to the pair of flanges 242 and webs 243 by welding or the like. The rib plate 246 is formed in a plate shape. The rib plate 246 is formed in a substantially rectangular shape when viewed from the X direction. A plate surface of the rib plate 246 faces the X direction. A plurality of rib plates 246 are provided at intervals in the X direction. Local deformation of the deformation member 24 is suppressed by the rib plate 246 .

The pin joint portion 25 joins the second bundle 23 and the deformation member 24 . The pin joint 25 includes an upper splice plate 251, a lower splice plate 252 (see FIG. 4), long holes (loose holes) 243a (see FIG. 4) formed in the web 243 of the deformation member 24, and bolts 253. and have

As shown in FIG. 3, the upper splice plate 251 is arranged across the upper surface of the mounting plate 235 of the second bundle of materials 23 and the upper surface of the end of the web 243 of the deformation member 24 in the X direction (longitudinal direction). ing.

The upper splice plate 251 is formed in a plate shape. The plate surface of the upper splice plate 251 faces the vertical direction. The upper splice plate 251 is formed in a rectangular shape when viewed from the vertical direction.

The upper splice plate 251 is formed with a plurality of bolt holes 251a and 251b penetrating in the plate thickness direction. A plurality of bolt holes 251a are formed at intervals in the Y direction. A plurality of bolt holes 251b are formed at intervals in the Y direction. The row of bolt holes 251a and the row of bolt holes 251b are spaced apart in the X direction. The diameter of the bolt hole 251a corresponds to the diameter of the bolt 253 (see FIG. 5) described later. The diameter of the bolt hole 251b corresponds to the diameter of a bolt 256 (see FIG. 2), which will be described later.

As shown in FIG. 4, the lower splice plate 252 is joined to the second bundle 23 . For example, the lower splice plate 252 is joined to the second flange 231 of the second bundle 23, the cover plate 233, and the like by welding or the like. The lower splice plate 252 has substantially the same shape as the upper splice plate 251 . The lower splice plate 252 is formed in a plate shape. The plate surface of the lower splice plate 252 faces the vertical direction. The lower splice plate 252 has a substantially rectangular shape when viewed vertically. A portion of the lower splice plate 252 is arranged below the mounting plate 235, and the remaining portion of the lower splice plate 252 protrudes from the second bundle 23 toward the center in the X direction.

A plurality of bolt holes 252a are formed in the lower splice plate 252 at positions corresponding to the bolt holes 251a of the upper splice plate 251 so as to extend through the lower splice plate 252 in the plate thickness direction. A plurality of bolt holes 252a are formed at intervals in the Y direction. A plurality of bolt holes (not shown) are formed through the lower splice plate 252 in the plate thickness direction at positions corresponding to the bolt holes 251 b of the upper splice plate 251 .

A bolt 256 (see FIG. 2) is inserted through the bolt hole 251b of the upper splice plate 251, the bolt hole 235a of the mounting plate 235, and the bolt hole (not shown) of the lower splice plate 252 and fastened to a nut (not shown). there is Thereby, the upper splice plate 251 is fixed to the mounting plate 235 and the lower splice plate 252 of the second bundle of materials 23 .

Long holes 243a penetrating in the plate thickness direction are formed at both ends of the web 243 of the deformation member 24 in the X direction (longitudinal direction). The elongated hole 243a is elongated in the X direction.

The bolts 253 (see FIG. 5) are inserted from the lower side of the lower splice plate 252 into the bolt holes 252a, the elongated holes 243a formed in the web 243 of the deformation member 24, and the bolt holes 251a (see FIG. 3) of the upper splice plate 251. It is inserted and a nut 254 is tightened (see FIG. 2). The joint between the second bundle 23 and the deformation member 24 is a double shear joint via the upper splice plate 251 and the lower splice plate 252 . As shown in FIG. 5, the deformation member 24 can be rotationally deformed with respect to the second bundle of materials 23 .

In order to prevent the bolts 253 from interfering in the Y direction when the deformable member 24 rotates, the bolts 253 are arranged in a single row, and final tightening is not performed until the first tightening so that the bolts 253 can easily slip.

The deformation member 24 is pressed against the first bundle of materials 21 via the buffer member 22 when the amount of relative movement of the upper structure 2 with respect to the lower structure 3 reaches a predetermined value or more. The deformable member 24 is flexed when the vicinity of the center thereof is pressed by the first bundle of materials 21 via the buffer member 22, and is plastically deformed when the range of elastic deformation is exceeded. Since the deformable member 24 is joined to the second bundle of materials 23 by the pin joint portion 25, the deformable member 24 is capable of large plastic deformation. The deformation member 24 absorbs the kinetic energy generated by the relative movement of the upper structure 2 with respect to the lower structure 3 during plastic deformation. The deformable member 24 receives the first bundle 21 when deformed and restricts the amount of relative movement of the upper structure 2 with respect to the lower structure 3 to be less than the limit displacement of the seismic isolation layer.

The limit displacement is, for example, the amount of displacement at which the laminated rubber of the seismic isolation layer 10 is stretched and broken. The limit displacement is set to, for example, several tens of centimeters. As a result, the movement restricting device 20 prevents the movement of the upper structure 2 relative to the lower structure 3 when a large deformation of several tens of centimeters or more occurs in the relative movement of the upper structure 2 to the lower structure 3. Movement can be regulated and the seismic isolation layer 10 can be prevented from being destroyed. The movement restricting device 20 may be further provided in a direction perpendicular to the deformation member 24 or in another direction. A plurality of movement restricting devices 20 may be provided. The movement restricting device 20 may be retrofitted to a building in which the seismic isolation layer 10 is provided in the middle floor or foundation.

Next, a method for exchanging the deformation member 24 will be described.
The deformation member 24 is plastically deformed when it collides with the first bundle of materials 21, and residual deformation occurs. The deformable member 24 that has undergone residual deformation must be replaced in order to ensure the energy absorption capacity again.

When exchanging the deformable member 24, first, as shown in FIG. Remove plate 251 .

Next, as shown in FIG. 4, the deformation member 24 is replaced and the upper splice plate 251 is attached. When removing and attaching the upper splice plate 251, bolting can be performed from the hand holes 233a of the cover plate 233 of the second bundle 23. As shown in FIG. Also, the lower splice plate 252 is joined to the second bundle of materials 23 and is utilized as a support for the weight of the deformable member 24 at the time of replacement.

FIG. 6 shows a relationship diagram of the position of the bolt 253 during rotation of the long hole and the energy absorbing member (hereinafter the "deformable member" may be referred to as the "energy absorbing member"). Here, the outermost bolt core distance is D, the plasticity factor μ is (the maximum plastic deformation amount of the energy absorbing member/the elastic deformation amount of the energy absorbing member) + 1, and the end rotation amount at the time of elastic deformation of the energy absorbing member is θ defined as

In the case of both-end pin joining, if E is the Young's modulus of the energy absorbing member, I is the moment of inertia of area, P is the central concentrated load, and L is the span, then the end rotation amount θ is given by the following formula (1 ).

Further, when the total plastic moment of the energy absorbing member is M _P , M _P is expressed by the following equation (2).

Therefore, the end portion rotation amount θ can be transformed from the equations (1) and (2) to the following equation (3).

Since the amount of deformation at the center of the energy absorbing member is very small with respect to the span L, assuming that the amount of deformation at the center of the energy absorbing member and the rotation angle of the end portion are in a proportional relationship, the maximum plastic deformation of the energy absorbing member is The end portion rotation angle θ _P is expressed by the following equation (4).

As shown in FIG. 6, the horizontal displacement _δh of the outermost bolt at the time of maximum plastic deformation of the energy absorbing member is expressed by the following equation (5), and the vertical displacement _δV is expressed by the following equation (6). .

The length of the loose hole (hereinafter the "long hole" may be referred to as "loose hole") is set so as not to interfere with the bolt when deformed _{by δh} . Also, since the bolt hole size is usually bolt diameter +2 m, if _δV is 1 mm or less, interference can also be prevented in the loose orthogonal direction (Y direction). In order to prevent interference in the loose orthogonal direction, the geometrically determined maximum value of the plasticity factor μ is given by the following equation (7).

As an example, the loose hole length under the conditions in Table 1 is calculated. Structural experiments were conducted under these conditions, and the results will be described later.

The end portion rotation amount θ=0.0061 can be obtained from the equation (3). From the equation (7), the geometrically determined maximum value of μ is 14.6.

From equation (5), the horizontal displacement δ _h of the outermost bolt when μ=14.6 is 11.3 mm, and the necessary length of the straight portion of the loose hole is doubled to 22.6 mm. Therefore, it can be judged that under this condition that _the loose hole straight portion length L is 30 mm, there is no problem with the bolt movable amount.

Next, through structural experiments, the plastic deformation performance of the energy absorbing member and the amount of rotational deformation of the simple pin connection are confirmed. The experimental conditions are as shown in Table 1, and the center of the energy absorbing member was gradually loaded with a jack.

FIG. 7 shows the relationship between the amount of central deformation of the energy absorbing member and the load. In the figure, the yield load calculated value is the value of P (central concentrated load) calculated by Equation (2). Due to the effects of strain hardening and the fact that simple pin joints at the ends have a degree of fixation rather than complete pinning, the load increased to a load greater than the calculated yield load and then yielded. The maximum deformation amount was 101 mm. The elastic deformation amount δ=PL ³ /48EI=4.9 mm, and the plasticity rate was confirmed up to about 20.

FIG. 8 shows the relationship between the amount of rotation of the end portion of the energy absorbing member and the load. The maximum end portion rotation amount was 0.111 rad. The geometrically determined maximum end portion rotation amount μθ=0.09 is exceeded, but the reason for this is the influence of the loose portion sinking deformation and the bolt shear deformation.

As described above, structural experiments confirmed that the amount of plastic deformation of the energy absorbing member and the amount of rotational deformation of the simple pin joint exceeded the design amount of deformation and the design amount of rotational deformation, and that the required energy absorption performance was achieved. bottom.

Next, analysis results will be described.
As shown in FIG. 9, a model in which a seismic isolation layer 10 is provided in the intermediate layer of a building 1 is exemplified. The building 1 is set to have 46 floors, for example. The seismic isolation layer 10 is provided between the 34th and 35th floors of the building 1 . The primary natural period of building 1 is 6.85 seconds in the X direction and 6.77 seconds in the Y direction.

As for the seismic waves input to the building 1, the notification wave is set to the Kobe phase level 2, for example. A notification wave is a simulated seismic wave used for time history calculation. Notification waves are specified in Ministry of Construction Notification No. 1461 of 2000. The notification wave has an acceleration response spectrum (notification spectrum) with a damping constant of 5%.

For the building 1, the response is first analyzed without the movement control device 20. FIG. The seismic wave input to the building 1 is set to a wave scaled by 1.575 so that the maximum deformation of the intermediate floor seismic isolation is 75 cm without the movement restricting device 20 .

In the following, a "without stopper" model without a seismic isolation fail-safe stopper, a "with a stopper" model with this seismic isolation fail-safe stopper (movement restriction device 20), and a rigid body (modeling a retaining wall collision) are used for the stopper. The maximum inter-story deformation and maximum acceleration are shown for three types of "stopper stiffness" models, respectively, when seismic motion is input. Both the model with stopper and the rigid stopper model were set so that the maximum deformation of the seismic isolation layer was 700 mm.

10 and 11, in the stopper stiffness model, a large acceleration occurs in the seismic isolation layer due to collision of the seismic isolation layer, and the inter-story deformation angle and the acceleration response of the upper part of the seismic isolation layer increase. On the other hand, in the model with stoppers, the inter-story deformation angle and acceleration response of the seismic isolation layer are slightly increased compared to the model without stoppers, but the amount of increase is smaller than that of the stiffness model with stoppers. Therefore, the collision load is reduced by the effect of the collision-absorbing rubber and the energy-absorbing member, and the effect of the seismic isolation fail-safe stopper is effectively exhibited.

In the movement restricting device 20 configured in this way, when the relative movement amount between the upper structure 2 and the lower structure 3 occurs, the deformation jointed by the second bundle 23 and the pin joint portion 25 will occur. Since the member 24 rotates and the deformation member 24 restricts the amount of movement below the limit displacement of the seismic isolation layer 10, the seismic isolation device is damaged or broken due to excessive deformation, and the upper structure 2 does not become a retaining wall. It is possible to prevent damage to the building 1 and the retaining wall due to collision.

A plurality of rib plates 246 are fixed to the deformation member 24 at intervals in the X direction. Therefore, local deformation of the long member 241 can be suppressed.

Moreover, since the deformable member 24 is formed by providing the rib plate 246 between the flanges 242 of the H-shaped steel, the deformable member 24 can be easily manufactured.

Moreover, when residual deformation occurs in the deformation member 24 after exhibiting the effect as a seismic isolation fail-safe stopper, the deformation member 24 can be replaced.

In addition, the deformation member 24 bends and deforms plastically, so that the kinetic energy generated when a relative movement amount occurs with respect to the lower structure 3 can be absorbed.

Further, by joining the end portion of the deformation member 24 to the second bundle 23 with a simple pin joint portion 25, a large rotational deformation capability can be ensured at a low cost without using a clevis or a pin.

Moreover, it is possible to prevent an increase in interlayer deformation response and acceleration response of the upper part of the seismic isolation layer 10 more than when the stopper is a rigid body (assuming that it collides with a retaining wall).

The assembly procedures, shapes, combinations, etc. of each component shown in the above-described embodiment are merely examples, and various modifications can be made based on design requirements without departing from the gist of the present invention.

For example, the deformation member 24 may be attached to the first bundle 21 side instead of the second bundle 23 . In this case, the buffer member 22 may be provided on the second bundle 23 . That is, the buffer member 22 is fixed to one of the first bundle of materials 21 and the second bundle of materials 23, and the deformation member 24 is attached to the other of the first bundle of materials 21 and the second bundle of materials 23 to which the buffer member 22 is not fixed. should be fixed to The deformable member 24 moves either the first bundle of materials 21 or the second bundle of materials 23 through the cushioning member 22 when the amount of relative movement of the upper structure 2 with respect to the lower structure 3 reaches a predetermined amount or more. It is only required that the base isolation layer 10 is pressed and deformed to absorb the kinetic energy, and the amount of movement is restricted to the limit displacement of the seismic isolation layer 10 or less.

2 Upper structure 3 Lower structure 10 Seismic isolation layer 20 Movement restricting device 21 First bundle 22 Cushioning member 23 Second bundle 24 Deformable member 25 Pin joint 241 Long member 242 Flange 243 Web 243a Long hole 246 Rib plate 251 upper splice plate (splice plate)
252 lower splice plate (splice plate)
253 bolt 254 nut

Claims (5)

A movement restricting device installed in a seismic isolation layer between an upper structure and a lower structure arranged below the upper structure,
a first bundle of materials that moves in conjunction with the upper structure;
a pair of second bundles that move in conjunction with the lower structure and are arranged facing each other with a gap;
a cushioning member fixed to one of the first bundle of materials and the second bundle of materials;
a deformation member;
a pin joint portion that joins the second bundle of materials and the deformable member;
The deformation member is adapted to move one of the first bundle of materials and the second bundle of materials through the cushioning member when the amount of relative movement of the upper structure with respect to the lower structure reaches a predetermined amount or more. is pressed and deformed to absorb kinetic energy, and restricts the movement amount to below the limit displacement of the seismic isolation layer,
The pin joint is
a splice plate fixed to the second bundle of materials and having a bolt hole;
an elongated hole formed in the deformable member and elongated in the facing direction in which the pair of second bundles of material face each other;
and a bolt that is inserted through the bolt hole and the elongated hole and fastened with a nut. The deformation member is
a long member extending in the opposite direction and having both ends joined to the second bundle of materials;
2. The movement restricting device according to claim 1, further comprising a plurality of rib plates fixed to said elongated member at intervals in said facing direction. The elongated member is an H-shaped steel arranged with the plate surface of the web facing the vertical direction,
3. The movement restricting device according to claim 2, wherein the rib plate is arranged with a plate surface facing the opposing direction. The movement restricting device according to any one of claims 1 to 3, wherein the deformable member is replaceable. The movement restricting device according to any one of claims 1 to 4, wherein the deformable member plastically deforms to absorb the kinetic energy.

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