JP6176986B2 - building - Google Patents

Description

  The present invention relates to a building having an outer wall and an inner wall.

  Conventionally, a roller is provided on the lower side of the outer wall panel of the building, and the lower side is relatively displaced in the horizontal direction with respect to the building frame to suppress the propagation of vibration from the outer wall panel to the inner wall panel when an earthquake occurs. A building capable of suppressing damage to the inner wall cloth around the section is known (see, for example, Patent Document 1).

JP 2008-303536 A (FIG. 3)

  However, in the building disclosed in the above-mentioned Patent Document 1, since the outer wall panel can be relatively displaced in only one horizontal direction, the outer wall panel is moved to the building in the case of vertical shaking due to an earthquake or the like. Cannot move relative to the frame. For this reason, when a vertical shaking occurs in the building, the shaking propagates from the building frame to the outer wall panel, and from the outer wall panel to the inner wall panel, and the inner wall stretched on the finished surface of the inner wall panel due to the influence. The cloth may be damaged.

  In consideration of the above facts, the present invention can suppress or prevent damage to the inner wall cloth stretched on the finished surface of the inner wall panel even when horizontal or vertical shaking occurs due to an earthquake or the like. Is the purpose.

The building according to the first aspect of the present invention comprises an inner wall panel that constitutes an inner wall by being erected in a predetermined number, and an outer wall that is erected in a predetermined number with a predetermined distance from the inner wall. The outer wall panel is interposed between the inner wall panel and the outer wall panel, and the inner wall panel and the outer wall panel can be relatively displaced in two directions, the horizontal direction and the vertical direction, and the inner wall panel is fixed. The seismic isolation device has a laminated structure in which rubber and a steel plate are stacked and has an elastic member that can be elastically deformed in response to the relative displacement in the two directions, The total thickness of the rubber is changed depending on the installation location .

  A building according to a second aspect of the present invention is the building according to the first aspect, wherein the seismic isolation device is provided at a peripheral portion of the opening in the outer wall and the inner wall, and a plurality of locations of the peripheral portion. Is arranged.

  A building according to a third aspect of the present invention is the building according to the second aspect, wherein a parting member is provided along a parting part between the opening and the inner wall panel, and the parting member is an opening. It is divided into a side parting member and an inner wall panel side parting member.

The building according to the invention of claim 4 is the building of the invention of claim 2 or claim 3 , wherein the seismic isolation device is arranged at a place other than the one arranged at the periphery of the opening. The total thickness of the rubber is made thicker than that formed.

A building according to a fifth aspect of the present invention is the building according to any one of the first to fourth aspects, wherein the outer wall panel includes an outer wall frame that fixes the outer wall panel to the building frame. In addition, the seismic isolation devices are disposed at a plurality of locations on the outer wall frame.

A building according to a sixth aspect of the present invention is the building according to any one of the first to fifth aspects, wherein the seismic isolation device is a pair of steel materials provided at both ends of the elastic member. Has a plate.

  According to the first aspect of the present invention, a predetermined number of inner wall panels are erected side by side to form an inner wall of a building, and a predetermined number of outer wall panels are arranged at a predetermined distance from the inner wall. The outer wall of the building is constructed by being erected. For this reason, various members can be interposed between the inner wall panel and the outer wall panel.

  Here, in the present invention, the seismic isolation device is interposed between the inner wall panel and the outer wall panel, but if wood or the like having no seismic isolation function is interposed between the inner wall panel and the outer wall panel. In this case, horizontal and vertical shaking due to an earthquake or the like propagates from the outer wall panel to the inner wall panel.

However, in the present invention, since the seismic isolation device is interposed between the inner wall panel and the outer wall panel, the inner wall panel and the outer wall panel can be relatively displaced in the horizontal direction and the vertical direction. In addition, the inner wall panel can be fixedly held. Thereby, in this invention, it can suppress or prevent that the shake of an outer wall panel propagates to an inner wall panel.
Further, according to the present invention, the seismic isolation device has an elastic member having a laminated structure in which rubber and a steel plate are stacked, and the total thickness of the rubber constituting the seismic isolation device is changed depending on the installation location. Has been. Thereby, the seismic isolation device can be elastically deformed corresponding to the relative displacement in the horizontal direction and the vertical direction of the outer wall panel, and the rigidity of the seismic isolation device can be changed according to the installation location.

  According to this invention of Claim 2, while the seismic isolation apparatus is provided in the peripheral part of the opening part, the said seismic isolation apparatus is arrange | positioned in the multiple places of the said peripheral part. Thereby, it can suppress or prevent that the shaking of an outer wall panel propagates to the peripheral part of an opening part.

  According to the third aspect of the present invention, the parting member provided along the parting part between the opening and the inner wall panel is divided into the part on the opening part side and the parting member on the inner wall panel side. Thereby, a parting member can be provided on each of the opening side and the inner wall panel side.

According to the present invention as set forth in claim 4 , the total thickness of the rubber constituting the seismic isolation device arranged at the peripheral portion of the opening is the rubber constituting the seismic isolation device arranged at other locations. It is thicker than the total thickness. Thereby, it is possible to make the seismic isolation device arranged at the peripheral edge of the opening more elastically deformable than the seismic isolation devices arranged at other locations, and as a result, the peripheral edge of the opening that has complicated behavior. Also in the part, the seismic isolation device can be elastically deformed flexibly, and it is possible to suppress or prevent the vibration of the outer wall panel from propagating to the peripheral part of the opening.

According to this invention of Claim 5 , the seismic isolation apparatus is arrange | positioned in several places of the outer wall frame which fixes an outer wall panel to a building frame. Thereby, while being able to arrange | position a seismic isolation apparatus in the high intensity | strength part in an outer wall, multiple support points of an inner wall panel can be provided.

According to this invention of Claim 6 , the seismic isolation apparatus has a pair of steel material plate provided in the both ends of the elastic member which comprises the said seismic isolation apparatus. Thereby, the seismic isolation device can use the steel plate for fixing the seismic isolation device.

As described above, in the building according to the first aspect of the present invention, the inner wall cloth stretched on the finished surface of the inner wall panel even when horizontal and vertical vibrations occur due to an earthquake or the like. It has an excellent effect that damage can be suppressed or prevented.
Further, in the present invention, after the shaking is settled, the positional relationship between the outer wall panel and the inner wall panel can be quickly returned to the original state, and the amount of elastic deformation of each seismic isolation device can be It has an excellent effect of being able to correspond to the amount of relative displacement with the inner wall panel.

  In the building which concerns on this invention of Claim 2, it suppresses that the shake of an outer wall propagates to the peripheral part of an opening part, and the inner wall cloth stretched on the finishing surface in the parting part of an opening part and an inner wall panel is damaged. Or it has the outstanding effect that it can prevent.

  In the building according to the third aspect of the present invention, the inner wall cloth can be divided and divided into the opening side parting member and the inner wall panel side parting member, and as a result, the building is shaken. However, it has the outstanding effect that the appearance quality of the parting part can be maintained.

In the building according to the present invention described in claim 4 , the vibration of the outer wall propagates to the peripheral portion of the opening, and the inner wall cloth stretched on the finished surface at the parting part between the opening and the inner wall panel is damaged. It has the outstanding effect that it can suppress or prevent also in the peripheral part of the opening part which carries out a complicated behavior.

In the building which concerns on this invention of Claim 5 , while being able to suppress or prevent the damage of the outer wall at the time of attachment and operation | movement of a seismic isolation apparatus, the outstanding effect that an inner wall panel can be supported stably. Have

In the building which concerns on this invention of Claim 6 , it has the outstanding effect that a seismic isolation apparatus can be fixed firmly.

It is a disassembled perspective view which shows the relationship between the outer wall panel of the building which concerns on this embodiment, and an inner wall panel. It is sectional drawing (sectional drawing which shows the state cut | disconnected along the 2-2 line | wire of FIG. 1) which shows the structure around the opening part of the building which concerns on this embodiment. It is an expanded sectional view (enlarged sectional view which shows a part of FIG. 2) which shows the parting part of the opening part and inner wall of a building which concern on this embodiment. (A) is sectional drawing which shows the attachment state before an action | operation (sectional drawing which shows the state cut | disconnected along the 4-4 line | wire of FIG. 2) regarding a seismic isolation apparatus which concerns on 1st Embodiment, (B) FIG. 5 is a cross-sectional view showing an attached state after operation. It is a perspective view which shows the building unit which comprises the building which concerns on this embodiment. It is a perspective view which shows the building which concerns on this embodiment. (A) is a schematic diagram which shows the arrangement | positioning location of the seismic isolation apparatus in the outer wall which concerns on 2nd Embodiment, (B) is a schematic diagram which shows the arrangement | positioning location of the seismic isolation apparatus in a modification. It is related with the seismic isolation apparatus which concerns on 2nd Embodiment, (A) is sectional drawing (sectional drawing which shows the state cut | disconnected along the 8-8 line of FIG. 7) which shows the attachment state before an operation | movement, (B) FIG. 5 is a cross-sectional view showing an attached state after operation.

<First Embodiment>
Hereinafter, 1st Embodiment of the building which concerns on this invention is described using FIGS.

  First, the overall structure of the building according to the present embodiment will be described. As shown in FIGS. 5 and 6, the building 10 according to the present embodiment has a plurality of lower floor side building units 14 installed on the foundation 12 and then a plurality of lower floor side building units 14. It is configured by installing individual building units 16 on the upper floor side.

  The construction of the building unit housing will be described taking the building unit 14 as an example. A column (not shown) standing at four corners, a ceiling frame (not shown) that connects the upper ends of the columns, and a lower end of the columns (not shown) are connected. And a floor frame. The ceiling frame has two types of long and short ceiling beams each made of channel steel arranged in a rectangular frame shape, and a plurality of ceiling beams are bridged between the longer ceiling beams at a predetermined interval. It is configured. Also, the floor frame has the same configuration as the ceiling frame, and is configured by arranging two types of long and short channel steel in a rectangular frame shape. Further, outer wall panels 20, 22, and 24 are attached to the floor frame and the ceiling frame along the outer peripheral surface of the building 10, and constitute a part of the outer wall 18 of the building 10. Among these, the opening part 56 which connects the inner side and the outer side of the building unit 14 is provided in the approximate center part of the outer wall panels 22 and 24, and the sliding window 60 is provided in the opening part 56. .

  FIG. 1 is an exploded perspective view showing the relationship between the outer wall panel and the inner wall panel of the building, and FIG. 2 is a sectional view showing the structure around the opening. The configuration of the outer wall panel will be described using the outer wall panel 20 as an example with reference to these drawings. As shown in FIGS. 1 and 2, the outer wall panel 20 includes an outer wall frame 28 and a rectangular flat plate-like outer wall material 26. It is configured by being fixed with a screw or the like (not shown). The outer wall frame 28 is configured by arranging horizontal frames 30, 32, 34, 36 and vertical frames 38, 40 formed of channel steel in a ladder shape. Specifically, the outer frame of the outer wall frame 28 is spanned between the horizontal frames 30 and 32 arranged so that the web surfaces face each other in the vertical direction, and both ends of the web surfaces of the horizontal frames 30 and 32 and the horizontal frame. And vertical frames 38 and 40 formed longer than 30 and 32. And between the vertical frames 38 and 40, the horizontal frames 34 and 36 are arrange | positioned in parallel with the horizontal frames 30 and 32, and are spanned at equal intervals. The outer wall frame 28 is fixed to the building unit housing with bolts or the like (not shown) in a state where the indoor flange surfaces of the horizontal frames 30 and 32 are in contact with the ceiling beam and the floor beam.

  The inner wall panel 44 provided at a predetermined interval from the outer wall panel 20 is constituted by an inner wall material 46 made of gypsum board, an inner wall frame 50 made of rectangular material having a rectangular cross section, and a heat insulating material 48. ing. Specifically, the inner wall frame 50 includes a border member 52 attached to the edge of the inner wall member 46 by attachment means (not shown), and a pair of two, and the inner wall frame 50 is vertically moved to both sides and the center on the horizontal side on the inner periphery of the border member 52. And a reinforcing member 54 spanned in the direction. Then, the heat insulating material 48 is arranged on the outdoor side surface of the inner wall material 46 so as to be surrounded by the edge member 52 and the reinforcing member 54, thereby forming the inner wall panel 44, and a predetermined number of the inner wall panels 44 are arranged. An inner wall 42 of the building 10 is configured.

  Here, seismic isolation devices 84 to be described later are arranged at a plurality of locations on the indoor side of the outer wall frame 28 described above, and the inner wall panel 44 is attached to the outer wall frame 28 via the seismic isolation devices 84. In this embodiment, as an example, the seismic isolation devices 84 are provided at a total of 10 locations including the center of each of the horizontal frames 34 and 36, the upper and lower ends of the vertical frames 38 and 40, and the joints with the horizontal frames 34 and 36. Has been placed.

  On the other hand, the accommodation around the opening 56 will be described with reference to FIG. 2. As shown in FIG. 2, the sash frame 62 and the sash frame 62 are attached to the outer wall frame 28 in the draw-in window 60 provided in the opening 56. A sash frame 100 to be fixed is provided. The sash frame 62 is configured in a rectangular frame shape, and has a sash frame main body portion 64 that is hollow inside, and a fin portion 66 that extends from the periphery of the sash frame main body portion 64 toward the center of the opening 56. And. The sash frame 100 is formed in a rectangular frame shape by channel steel, and is attached to the outer wall frame 28 by bolts 102 and nuts 104. The sash frame 62 is attached to the sash frame 100 by screws 106 and long screws 108. Here, in the present embodiment, the seismic isolation devices 84 are arranged at a plurality of locations along the joint portion (contact surface) between the outer wall frame 28 and the sash frame 100 in the peripheral portion of the opening 56. In addition, the arrangement | positioning location of the seismic isolation apparatus 84 in the peripheral part of the opening part 56 is demonstrated by 2nd Embodiment mentioned later.

  Further, a parting member 68 made of a rectangular flat plate material is disposed at a parting part 58 between the sash frame 62 and the inner wall panel 44 described above, and the parting member 68 is a parting member 70 as an opening side parting member. And a parting member 72 as a parting member on the inner wall panel side. The parting member 70 is fixed to the fin portion 66 with screws 74, and the parting member 72 is fixed to the inner wall panel 44 with an adhesive or the like (not shown).

  FIG. 3 is an enlarged sectional view showing a parting part between the opening 56 and the inner wall panel 44. As shown in FIG. 3, an inner wall cloth 76 for finishing the inner wall is stretched on the finished surface of the parting member 68, and the inner wall cloth 76, as with the parting member 68, It is divided into an inner wall cloth 80 on the inner wall panel side. At this time, the inner wall cloth 78 is sandwiched between the fin portion 66 and the parting member 70 described above. Further, the end portions of the inner wall cloth 78 and the inner wall cloth 80 are inserted into the boundary 82 between the parting member 70 and the parting member 72.

  As described above, the inner wall panel 44 is fixedly held only by the seismic isolation device 84 with respect to the outer wall of the building 10 including the outer wall 18 and the sliding window 60. Hereinafter, the structure of the seismic isolation apparatus 84 which comprises the principal part of this invention is demonstrated in detail.

  FIG. 4 shows the respective attachment states after the seismic isolation device 84 operates before the operation. As shown in FIG. 4A, a seismic isolation device 84 is interposed between the outer wall panel 20 and the inner wall panel 44. The seismic isolation device 84 includes a laminated rubber portion 90 as a columnar elastic member, and a flange member 86 that is integrally bonded to both ends of the laminated rubber portion 90 and is formed by a rectangular steel plate. , 88. The flange member 86 is set to be thicker than the flange member 88. The four corners of the flange member 86 are fastened to the outer wall frame 28 by screws (fixing members) 96, whereby the seismic isolation device 84 is fixed to the outer wall frame 28. It is fixed to. The inner wall panel 44 is fixed to the seismic isolation device 84 by driving a nail (fixing member) 98 into the four corners of the flange member 88 from the inner surface of the inner wall panel 44. Note that the flange member 86 is fixed to both the outer wall frame 28 and the sash frame 100 at the peripheral edge of the opening 56 described above.

The laminated rubber portion 90 is configured by integrally laminating a rubber plate 92 and a reinforcing plate 94 formed of a steel material plate. The laminated rubber portion 90 has a large spring constant in the plate thickness direction (compression and tension direction) of the inner wall panel 44 and in the width direction and height direction (shear direction) of the inner wall panel 44. The spring constant is smaller than that in the plate thickness direction. In other words, the laminated rubber portion 90 is configured to be less likely to be elastically deformed in the compression and tension directions but to be elastically deformable in the shear direction. In the laminated rubber portion 90, the larger the proportion of the rubber plate 92, the smaller the spring constant. In the present embodiment, the laminated rubber section 90 as an example, the reinforcing plate 94 and the four thicknesses A, a rubber plate 92 having a thickness of B ₁ is three, which is constituted by the laminated rubber section 90 The total thickness is T. In other words, in this embodiment, it is set to a total thickness 3B ₁ having a total thickness 4A + rubber plate 92 having a total thickness of T = the reinforcing plate 94 of the laminated rubber portion 90.

  Next, functions and effects of this embodiment will be described.

  In this embodiment, as shown in FIGS. 1 and 2, a predetermined gap is provided between the outer wall panel 20 constituting the outer wall 18 of the building 10 and the inner wall panel 44 constituting the inner wall 42 of the building 10. A plurality of seismic isolation devices 84 are interposed in the clearance.

  By the way, horizontal and vertical shaking may occur in the building 10 due to an earthquake or the like. At this time, if wood or the like having no seismic isolation function is interposed between the outer wall panel 20 and the inner wall panel 44, horizontal and vertical vibrations propagate from the outer wall panel 20 to the inner wall panel 44, The inner wall 42 may be damaged. More specifically, when a shaking occurs due to an earthquake or the like, the shaking from the ground is first transmitted to the foundation 12 and propagates to the building unit 14. Since the outer wall panel 20 is fixed to the housing of the building unit 14 as described above, the shaking of the housing propagates to the outer wall panel 20. At this time, when wood or the like is interposed between the outer wall panel 20 and the inner wall panel 44, the vibration is directly propagated from the outer wall panel 20 to the inner wall panel 44. As a result, the inner wall panel 44 and the inner wall cloth 76 stretched on the inner wall panel 44 may be damaged.

  However, in this embodiment, the seismic isolation device 84 is interposed between the outer wall panel 20 and the inner wall panel 44 as described above. As a result, even if horizontal or vertical shaking occurs in the building 10 due to an earthquake or the like, the inner wall panel 44 and the outer wall panel 20 are relatively displaced in two directions, the horizontal direction and the vertical direction, and the inner wall panel 44 is fixed. Retained.

Specifically, with reference to FIG. 4, the laminated rubber portion 90 of the seismic isolation device 84 has a building height as shown in FIG. 4 (B) when vertical shaking occurs in the building 10 when an earthquake occurs. S ₁ to shear deformation at a maximum directionally. Therefore, the outer wall panel 20 and the inner wall panel 44 is relatively displaced at the maximum building height direction bidirectional by S _1. In other words, if the displacement due to the shaking of the outer wall panel 20 is within the range of 2S _{1 in} the vertical direction, the inner wall panel 44 is positioned at the reference position with the position in the state of FIG. Fixedly held. The length T of the laminated rubber portion 90 does not change even if the laminated rubber portion 90 is sheared.

Next, a case where a horizontal shake occurs in the building 10 at the time of the earthquake will be described. In this case, if a plan sectional view is shown in FIGS. 4 (A) and 4 (B), the building 10 is shaken in the vertical direction. This is exactly the same as when the problem occurs. That is, since the laminated rubber portion 90 is not directional in shear deformation, even when horizontal shaking occurs, the laminated rubber portion 90 undergoes shear deformation in the same manner as when vertical shaking occurs, and the outer wall panel 20 and the inner wall panel 44 are separated from each other. most are relatively displaced by S ₁ in the horizontal direction bidirectional. In other words, if the displacement due to the shaking of the outer wall panel 20 is within the range of 2S _{1 in} the horizontal direction, the inner wall panel 44 is positioned at the reference position with the position in the state of FIG. Fixedly held. In addition, since the shear deformation of the laminated rubber portion 90 is elastic deformation, when the outer wall panel 20 or the like is not seriously damaged, the positional relationship between the outer wall panel 20 and the inner wall panel 44 is not affected regardless of the direction of the vibration. After being settled, the state immediately returns to the state of FIG.

  Thus, in this embodiment, the seismic isolation device 84 is interposed between the outer wall panel 20 and the inner wall panel 44. As a result, the outer wall panel 20 and the inner wall panel 44 can be relatively displaced in two directions, the horizontal direction and the vertical direction, and the inner wall panel 44 can be fixedly held. Even when the vibration occurs in two directions, the horizontal direction and the vertical direction, it is possible to suppress or prevent damage to the inner wall cloth 76 stretched on the finished surface of the inner wall panel 44.

  Moreover, in this embodiment, while the seismic isolation apparatus 84 is provided in the peripheral part of the opening part 56, the said seismic isolation apparatus 84 is arrange | positioned in the multiple places of the said peripheral part. Thereby, it is possible to suppress or prevent the shaking of the outer wall panel 20 from propagating to the peripheral edge portion of the opening 56, and as a result, the outer wall panel 20 is stretched on the finished surface at the parting portion 58 between the opening 56 and the inner wall panel 44. Damage to the inner wall cloth 76 can be suppressed or prevented.

  Furthermore, in this embodiment, the parting member 68 provided along the parting part 58 is divided into a parting member 70 as the opening part side parting member and a parting member 72 as the inner wall panel side parting member. Thereby, since the parting member can be provided on each of the opening 56 side and the inner wall panel 44 side, the inner wall cloth 76 can be divided and stretched into the parting member 70 and the parting member 72, respectively. The appearance quality of the parting part 58 can be maintained even when the vibration occurs.

  In this embodiment, the seismic isolation device 84 has a laminated structure in which a rubber plate 92 and a reinforcing plate 94 are stacked, and a laminated rubber portion 90 that can be elastically deformed in response to relative displacement in the horizontal direction and the vertical direction. have. Thereby, the seismic isolation device 84 can be elastically deformed corresponding to the relative displacement in the horizontal direction and the vertical direction of the outer wall panel 20, and as a result, the position of the outer wall panel 20 and the inner wall panel 44 after the shaking is settled. The relationship can be quickly returned to its original state.

  In addition, in the present embodiment, the outer wall panel 20 includes the outer wall frame 28 that fixes the outer wall panel 20 to the housing of the building unit 14, and the seismic isolation devices 84 are disposed at a plurality of locations on the outer wall frame 28. ing. As a result, the seismic isolation device 84 can be disposed at a high strength portion of the outer wall 18 and a plurality of support points for the inner wall panel 44 can be provided. As a result, the outer wall 18 at the time of installation and operation of the seismic isolation device 84 can be provided. Can be suppressed or prevented, and the inner wall panel 44 can be stably supported.

  In addition, in the present embodiment, the seismic isolation device 84 includes a pair of steel plates, that is, flange members 86 and 88 provided at both ends of the laminated rubber portion 90. Thereby, the seismic isolation apparatus 84 can use the flange members 86 and 88 for fixation of the seismic isolation apparatus 84, As a result, the seismic isolation apparatus 84 can be fixed firmly.

Second Embodiment
Next, 2nd Embodiment of the building which concerns on this invention is described using FIG.7 and FIG.8. In addition, about the same component as 1st Embodiment mentioned above, the same number is attached | subjected and the description is abbreviate | omitted.

  In the second embodiment, seismic isolation devices 140 in which the total thickness of the rubber is thicker than that of the seismic isolation device 84 are arranged at a plurality of locations on the peripheral edge of the opening 56 provided in the outer wall panels 22 and 24. There is a feature in the point.

  First, an example of the location of the seismic isolation device in the outer wall panels 22 and 24 will be described with reference to FIG. 7A. As shown in FIG. A seismic isolation device 84 is arranged. And the opening part 56 is provided in the approximate center part of the surface which consists of the outer wall panel 22 and the outer wall panel 24, and the seismic isolation apparatus 140 is located in the center of the four corners and upper and lower sides in the peripheral part of the opening part 56. Has been placed. In the first embodiment described above, the same seismic isolation device 84 is disposed.

  As described above, the seismic isolation device 140 has a total rubber thickness that is thick. However, in general, the seismic isolation device is provided below the building and supports the vertical load of the building. Therefore, if the total rubber thickness of the seismic isolation device is increased, the amount of compressive deformation increases, which is not suitable for supporting the vertical load of the building. However, in this embodiment, there is no disadvantage even if the total rubber thickness of the seismic isolation device is increased. In other words, the seismic isolation device 140 according to the present embodiment is different from a general seismic isolation device not only in the location of the seismic isolation device, but also in its usage of increasing the total thickness of rubber. Hereinafter, the structure of the seismic isolation device 140 will be described in detail.

FIG. 8 shows the respective attachment states after the seismic isolation device 140 operates before the operation. As shown in FIG. 8A, the seismic isolation device 140 differs from the seismic isolation device 84 only in the configuration of the laminated rubber portion 142. In the present embodiment, as an example, the laminated rubber portion 142 includes three reinforcing plates 94 having a thickness A and _two rubber plates 144 having a thickness B2 formed to be thicker than the rubber plate 92. The total thickness of the laminated rubber portion 142 is T as in the laminated rubber portion 90. In other words, in this embodiment, it is set to the total thickness 2B ₂ having a total thickness of 3A + rubber plate 144 of the total thickness T = the reinforcing plate 94 of the laminated rubber 142. That is, since the total rubber plate thickness 2B _{2 in} the laminated rubber portion 142 is set to be the total rubber plate thickness 3B ₁ in the laminated rubber portion 90, the laminated rubber portion 142 is more easily elastically deformed than the laminated rubber portion 90. It is set.

  Next, functions and effects of this embodiment will be described.

  Also in this embodiment, a seismic isolation device 84 is interposed between the outer wall panel 20 and the inner wall panel 44 as in the first embodiment described above. For this reason, even if horizontal or vertical shaking occurs in the building 10 due to an earthquake or the like, the inner wall panel 44 and the outer wall panel 20 are relatively displaced in two directions, the horizontal direction and the vertical direction, and the inner wall panel 44 is fixed. Retained. Therefore, also in this embodiment, the same operation and effect as the first embodiment described above can be obtained.

In addition, in the present embodiment, the peripheral edge of the opening 56 in the inner wall panel 44 and the outer wall panels 22, 24 are also in the peripheral edge of the opening 56 that behaves complicatedly when the building 10 is shaken due to an earthquake or the like. Are relatively displaced, and the peripheral edge portion is fixedly held. Specifically, referring to FIG. 8, the laminated rubber portion 142 of the seismic isolation device 140 is shown in FIG. 8B when a vertical or horizontal shake occurs in the building 10 when an earthquake occurs. up to _{S 2} to shear deformation. Here, since the laminated rubber portion 142 has a total rubber thickness larger than that of the laminated rubber portion 90 and is set to be easily elastically deformed, the same force is applied to the laminated rubber portion 90 and the laminated rubber portion 142. Has a relationship of S ₂ > S ₁ (see FIGS. 4B and 8B). That is, since the spring constant K ₁ of the laminated rubber portion 90 is set to be greater than the spring constant K ₂ of the laminated rubber portion 142, the laminated rubber portion 142 is deformed with a smaller force than the laminated rubber portion 90. Therefore, if the seismic isolation device 140 is not provided, deformation concentrates on the corners of the opening 56 and the like, and the peripheral portion of the opening 56 in the inner wall panel 44 may behave complicatedly. In this embodiment, the laminated rubber portion 142 is elastically deformed flexibly in response to the behavior. For this reason, also in the peripheral part of the opening part 56 in the inner wall panel 44 which carries out a complicated behavior, the said peripheral part and the outer wall panels 22 and 24 are displaced relatively. In other words, the peripheral edge of the opening 56 in the inner wall panel 44 is fixedly held at the reference position with the position in the state of FIG. 8A as the reference position.

  Thus, in this embodiment, the total thickness of the rubber plate is made thicker in the seismic isolation device 140 arranged in the peripheral portion of the opening 56 than in the seismic isolation device 84 arranged in other locations. Yes. Thereby, the seismic isolation apparatus 140 arrange | positioned at the peripheral part of the opening part 56 can be made to be elastically deformed more easily than the seismic isolation apparatus 84 arrange | positioned in the other location. As a result, the seismic isolation device 140 is also elastically deformed flexibly at the peripheral portion of the opening portion 56 that behaves in a complicated manner, thereby suppressing or preventing the vibration of the outer wall panels 22 and 24 from propagating to the peripheral portion of the opening portion 56. As a result, damage to the inner wall cloth 76 stretched on the finished surface of the parting portion 58 can be suppressed or prevented.

<Supplementary explanation of the above embodiment>

  (1) In the second embodiment described above, the opening 56 is provided in the outer wall panels 22 and 24. However, when the opening 56 is relatively small, as shown in FIG. It is good also as a structure which provides the opening part 56 only in the panel 22. FIG.

  (2) In addition, in the second embodiment described above, the opening 56 is provided at the substantially central portion of the outer wall panels 22 and 24. However, the present invention is not limited to this, and the opening 56 reaches the lower side of the outer wall panels 22 and 24. The seismic isolation device 140 may be arranged on the peripheral edge of the opening 56.

  (3) Furthermore, in 2nd Embodiment mentioned above, it was set as the structure by which the seismic isolation apparatus 140 is arrange | positioned at the peripheral part of the opening part 56, However, Not only this but even if it arrange | positions the seismic isolation apparatus 140 in a different location. Good. Moreover, it is good also as a structure which changes the total thickness of the rubber plate in a seismic isolation apparatus suitably according to an installation location. Thereby, the rigidity of a seismic isolation device can be changed according to the installation location, and as a result, the amount of elastic deformation of each seismic isolation device is made to correspond to the amount of relative displacement of the outer wall panel and inner wall panel in the arrangement location. be able to.

  (4) In the above-described embodiment, the seismic isolation devices 84 and 140 are configured to undergo shear deformation in response to shaking in the building height direction and the horizontal direction. It may be applied to fluctuations in the direction.

10 building 18 outer wall 20 outer wall panel 22 outer wall panel 24 outer wall panel 28 outer wall frame 42 inner wall 44 inner wall panel 56 opening 58 parting part 68 parting member 70 parting member (opening side parting member)
72 Parting material (Inner wall panel side parting member)
84 Seismic isolation device 86 Flange member (steel plate)
88 Flange member (steel plate)
90 Laminated rubber part (elastic member)
92 Rubber plate (rubber)
94 Reinforcement plate (steel plate)
140 Seismic isolation device 142 Laminated rubber part (elastic member)
144 Rubber plate (rubber)

Claims (6)

An inner wall panel that constitutes the inner wall by being erected in a predetermined number,
An outer wall panel constituting an outer wall by being erected side by side with a predetermined number of gaps from the inner wall; and
A seismic isolation device interposed between the inner wall panel and the outer wall panel, capable of relatively displacing the inner wall panel and the outer wall panel in two directions, a horizontal direction and a vertical direction, and fixedly holding the inner wall panel. Equipment,
Have,
The seismic isolation device has a laminated structure in which rubber and a steel plate are stacked and has an elastic member that can be elastically deformed corresponding to the relative displacement in the two directions, and the total thickness of the rubber is changed depending on the installation location. Yes,
building. The seismic isolation device is provided at a peripheral portion of the opening in the outer wall and the inner wall, and is disposed at a plurality of locations on the peripheral portion.
The building according to claim 1. A parting member is provided along a parting part between the opening and the inner wall panel, and the parting member is divided into an opening part parting member and an inner wall panel side parting member.
The building according to claim 2. In the seismic isolation device, the total thickness of the rubber is thicker than the one arranged at the peripheral portion of the opening than the one arranged at other locations.
The building according to claim 2 or claim 3 . The outer wall panel includes an outer wall frame that fixes the outer wall panel to the building frame,
The seismic isolation devices are arranged at a plurality of locations on the outer wall frame,
The building according to any one of claims 1 to 4 . The seismic isolation device has a pair of steel plates provided at both ends of the elastic member,
The building according to any one of claims 1 to 5 .