JP7565871B2 - Building structure - Google Patents

Description

The present invention relates to a building structure in which a multi-story earthquake-resistant wall is installed on the inside of the building.

When the framework of a building is constructed using a rigid-frame structure, the beams protrude below the slab, lowering the ceiling height at the beams and narrowing the living space.
In response to this, for example, Patent Document 1 discloses a flat slab structure that includes a floor slab and columns that support the floor slab.
Furthermore, Patent Document 2 discloses a configuration in which precast concrete slab supports are placed on all four sides of a column, and opposing slab supports sandwiched between the columns are joined by prestressed PC steel rods, with the slab supports acting as the supporting structure for constructing flat slab concrete.
Patent Document 3 discloses a structure including columns constructed on foundation beams and a flat slab having a flat plate shape without a beam form.
In all of the configurations disclosed in Patent Documents 1 to 3, a flat slab is used to prevent beams from protruding below the slab.
When such flat slabs are used over a large span and area, a certain number of columns are required to support the load of the flat slab and ensure its strength. However, installing too many columns may result in the living space being narrowed by the columns.

JP 2013-234506 A Japanese Patent Application Publication No. 6-81470 JP 2000-310057 A

The problem that this invention aims to solve is to provide a building structure that has a slab structure without beams, which allows for a large living space while still being sturdy.

In order to solve the above problems, the present invention employs the following means.
In other words, the building structure of the present invention is a building structure in which a multi-story earthquake-resistant wall is provided on the interior side of a building, and is characterized in comprising a first multi-story earthquake-resistant wall and a second multi-story earthquake-resistant wall arranged opposite each other, a flat slab of roughly uniform thickness joined to the first multi-story earthquake-resistant wall and the second multi-story earthquake-resistant wall, and partition posts installed on the outer periphery of the building and supporting the underside of the flat slab.
In a building structure with such a configuration, the slab is realized as a flat slab with a roughly uniform thickness, so that no beams are visible inside the living space.
The flat slab is supported on the inside of the building by being joined to a sturdy multi-story shear wall. In particular, the multi-story shear wall includes a first shear wall and a second shear wall arranged opposite each other, and the flat slab is supported at a plurality of positions by the first shear wall and the second shear wall. This allows a structure in which the load of the flat slab is supported, for example, only by the multi-story shear wall. In this case, the number of columns as structural materials supporting the load of the flat slab other than the multi-story shear wall is reduced, or columns as structural materials are not required. This prevents the space of the living room from being narrowed by columns provided on the inside of the living room.
Furthermore, studs are provided on the periphery of the building to support the underside of the flat slab. This prevents the flat slab from deflecting due to its own weight at the outer end of the flat slab, which is far from the associated earthquake-resistant wall, and allows the distance from the supporting earthquake-resistant wall to the outer end of the flat slab to be longer, thereby making the living space larger.
Even if studs are installed in this way, the living space can still be kept spacious because the studs are installed on the outer periphery of the building as described above.
The above effects work synergistically to provide a building structure in which the slab does not have a beam, making the living space larger while still achieving a strong structure.

In one aspect of the present invention, PC steel members are embedded in the flat slab, and tensioning fasteners or fixing fasteners for introducing prestress into the PC steel members are provided within the wall cross section of the multi-story earthquake-resistant wall.
With this structure, the PC steel members are embedded in the flat slab, which further reduces the deflection of the flat slab and increases its rigidity, and the distance between the multi-story earthquake-resistant wall and the partition pillars can be further increased, which makes it possible to further expand the living space without pillars.
In addition, since the PC steel members are fixed within the wall cross section of the multi-story earthquake-resistant wall, they can more firmly support the flat slab.

In one aspect of the present invention, a building common area is provided including the multi-story earthquake-resistant wall, a double floor constituting a living space is provided on the upper side of the flat slab, and equipment piping is arranged inside the double floor, and one end of the equipment piping is routed between the ceiling structure and ceiling material of the building common area through a penetration portion provided in the multi-story earthquake-resistant wall.
According to this configuration, the equipment piping is arranged in the double floor inside the living room, and is installed between the ceiling framework and ceiling material of the building's common area formed including the multi-story earthquake-resistant wall outside the living room. Therefore, the equipment piping can be easily moved when changing the room division of the building or updating the equipment. In addition, the equipment piping can be accommodated below the floor material that constitutes the double floor inside the living room, or above the ceiling material that constitutes the ceiling structure of the building's common area.

In one aspect of the present invention, a core shear wall structure is formed so as to be surrounded in a rectangular shape by the first multi-story shear wall and the second multi-story shear wall, and a mat slab is provided at the foundation of the core shear wall structure.
According to this configuration, by providing a mat slab in the foundation of the core shear wall structure, even if an excessive axial force (compressive force or pull-out force) acts on the multi-story shear walls that form the core shear wall structure during an earthquake, a constant ground pressure can be applied to the ground over the entire mat slab in the foundation, thereby preventing the building from rising upward.

The present invention makes it possible to provide a building structure in which the slab does not have beams, making it possible to enlarge the living space while still achieving a strong structure.

1 is a standard floor plan view showing the configuration of a building to which a building structure according to an embodiment of the present invention is applied. 2 is a longitudinal sectional view taken along the line II in FIG. 1 . FIG. 2 is a longitudinal section showing a flat slab of the building structure of FIG. 1; FIG. 2 is a vertical cross-sectional view showing the configuration of a joint between a flat slab and a multi-story earthquake-resistant wall. A vertical cross-sectional view showing the configuration of the end of the flat slab on the outer periphery of the building. FIG. 2 is a vertical cross-sectional view showing a joint between a partition wall and a flat slab.

The present invention is a building structure comprising a first multi-story earthquake-resistant wall and a second multi-story earthquake-resistant wall arranged opposite each other, a flat slab joined to each of the two multi-story earthquake-resistant walls, and partition posts provided on the outer periphery of the building to support the underside of the flat slab.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of a building structure according to the present invention will be described with reference to the accompanying drawings.
A standard floor plan showing the configuration of a building to which the building structure according to the embodiment of the present invention is applied is shown in Fig. 1. Fig. 2 is a vertical cross-sectional view of the portion shown by the arrows II in Fig. 1.
1 and 2, a building 1 to which a building structure A according to an embodiment of the present invention is applied includes a foundation structure 2 and a superstructure 3. In this embodiment, the building 1 is formed, for example, in a rectangular shape when viewed from above.
The foundation structure 2 is constructed in the ground G. The foundation structure 2 includes foundation piles (not shown) and the like as necessary. The foundation structure 2 supports the superstructure 3 from below. In this embodiment, the foundation structure 2 includes a mat slab 21. The mat slab 21 is disposed in the center of the building 1 when viewed from above. The mat slab 21 is made of reinforced concrete having a predetermined thickness in the vertical direction, and is rectangular when viewed from above. In this embodiment, the outer periphery of the mat slab 21 in the foundation structure 2 is not limited to a particular structure, and may include, for example, a foundation beam 22 or the like. The dwelling unit span is the distance E between the main wall portion 43 and the partition 6 as shown in FIG. 1 and FIG. 2.

The upper structure 3 has a plurality of stories F1 to F6 in the vertical direction. The upper structure 3 mainly includes multi-story earthquake-resistant walls 40A and 40B, a flat slab 5, and studs 6.
The multi-story earthquake-resistant wall 40A and the multi-story earthquake-resistant wall 40B are disposed at a distance from each other in the center of the longitudinal direction D1 of the building 1. The multi-story earthquake-resistant walls 40A and 40B each include a first multi-story earthquake-resistant wall 41 and a second multi-story earthquake-resistant wall 42. The first multi-story earthquake-resistant wall 41 and the second multi-story earthquake-resistant wall 42 are disposed opposite each other in the short direction D2 of the building 1 that is perpendicular to the longitudinal direction D1. The first multi-story earthquake-resistant wall 41 and the second multi-story earthquake-resistant wall 42 each extend continuously upward from the foundation structure 2 to the topmost story F6 of the superstructure 3.
The first multi-story earthquake-resistant wall 41 and the second multi-story earthquake-resistant wall 42 each have a main wall portion 43 and a pair of side wall portions 44. The main wall portion 43 is provided along a surface parallel to the longitudinal direction D1 and perpendicular to the transverse direction D2. The side wall portions 44 extend in the transverse direction D2 from both sides of the longitudinal direction D1 of the main wall portion 43. Each side wall portion 44 of the first multi-story earthquake-resistant wall 41 extends from the main wall portion 43 toward the second multi-story earthquake-resistant wall 42. In addition, each side wall portion 44 of the second multi-story earthquake-resistant wall 42 extends from the main wall portion 43 toward the first multi-story earthquake-resistant wall 41. As a result, the side wall portion 44 of the first multi-story earthquake-resistant wall 41 and the side wall portion 44 of the second multi-story earthquake-resistant wall 42 are provided opposite each other with a gap in between in the transverse direction D2.
Specifically, for example, in a five-story reinforced concrete building, the first multi-story earthquake-resistant wall 41 or the second multi-story earthquake-resistant wall 42 has a wall thickness of about 400 to 900 mm. The flat slab 5 has a slab thickness of about 350 mm. The partition 6 is made of reinforced concrete and, in the case of a rectangular cross section, is about 400 mm x 400 mm, and the ceiling height of each floor is about 2800 mm. The distance from the wall surface of the first multi-story earthquake-resistant wall 41 or the second multi-story earthquake-resistant wall 42 to the tip of the flat slab 5 extending toward the outer periphery of the building is about 11 m.
In each of the multi-story shear walls 40A, 40B, a generally cylindrical core shear wall structure 4 that is continuous in the vertical direction is formed by the first multi-story shear wall 41 and the second multi-story shear wall 42. The core shear wall structure 4 includes the multi-story shear walls 40A, 40B and is formed so as to be surrounded in a rectangular shape by the first multi-story shear wall 41 and the second multi-story shear wall 42. More specifically, in each of the multi-story shear walls 40A, 40B, the core shear wall structure 4 is surrounded by main wall portions 43 that face each other and side wall portions 44 that are provided so as to extend from the main wall portions 43 toward each other, and is provided so that the outer contour follows the virtual rectangle R when viewed in a plan view.
As shown in Fig. 2, the core shear wall structure 4 is provided on the mat slab 21 as already described. In other words, the mat slab 21 is provided in a portion of the foundation structure 2 that corresponds to the foundation portion directly below the core shear wall structure 4 and supports it. The multi-story shear walls 40A, 40B are integrally joined to the mat slab 21.

As shown in FIG. 1, outer perimeter earthquake-resistant walls 8 are provided at both ends of the building 1 in the longitudinal direction D1. Each outer perimeter earthquake-resistant wall 8 extends continuously upward from the foundation structure 2 to story F5 of the superstructure 3. The outer perimeter earthquake-resistant walls 8 are provided along a plane perpendicular to the longitudinal direction D1. Multiple outer perimeter earthquake-resistant walls 8 are provided at intervals in the transverse direction D2 at both ends of the building 1 in the longitudinal direction D1.

FIG. 3 is a vertical cross-sectional view showing a flat slab of the building structure.
The flat slabs 5 form floor slabs for each of the stories F2 to F6 of the superstructure 3. The flat slabs 5 are provided to match the floor shapes of the stories F2 to F6 of the superstructure 3. As shown in Figs. 2 and 3, the flat slabs 5 are joined to the first multi-story earthquake-resistant wall 41 and the second multi-story earthquake-resistant wall 42 of the multi-story earthquake-resistant walls 40A and 40B inside the building 1. The flat slabs 5 extend from the multi-story earthquake-resistant walls 40A and 40B on both sides in the short direction D2. The flat slabs 5 extend from the multi-story earthquake-resistant walls 40A and 40B to the outer periphery 1s of the building 1 in the short direction D2.
The flat slab 5 is any one of a prestressed flat slab, a prestressed flat plate, and a prestressed hollow core slab, each having a rectangular uniform slab thickness T. In this embodiment, the flat slab 5 is, for example, a prestressed flat slab in which prestress is introduced. The lower surface 5b of the flat slab 5 is flat, and no beam protrudes downward. In other words, the flat slab 5 does not have a beam.

Fig. 4 is a vertical cross-sectional view showing the structure of the joint between the flat slab and the multi-story earthquake-resistant wall. Fig. 5 is a vertical cross-sectional view showing the structure of the flat slab and the end portion on the outer periphery side of the building.
4 and 5, the flat slab 5 includes concrete 51 and slab reinforcement 52 embedded in the concrete 51. The slab reinforcement 52 is embedded in the upper and lower parts of the flat slab 5. The slab reinforcement 52 is configured by vertical reinforcement 52a extending in the short direction D2 and horizontal reinforcement 52b extending in the longitudinal direction D1 arranged in a lattice pattern when viewed from above.

A plurality of PC steel members 7 are embedded in the flat slab 5. Each PC steel member 7 extends in the short direction D2. As shown in FIG. 4, one end 7a of the PC steel member 7 on the multi-story shear wall 40A, 40B side is joined to a fixing fixture 71 provided in the wall cross section of the first multi-story shear wall 41 and the second multi-story shear wall 42 constituting the multi-story shear wall 40A, 40B, and is fixed in the first multi-story shear wall 41 and the second multi-story shear wall 42. The fixing fixture 71 is embedded (fixed) inward from the wall main reinforcement 43s provided to extend vertically in the wall cross section of the main wall portion 43 of the first multi-story shear wall 41 and the second multi-story shear wall 42.
As shown in Figure 5, the other end 7b of the PC steel 7 is fixed within the outer end 5s of the flat slab 5, which forms the outer periphery 1s of the building 1, by a tensioning fixing device 72 provided within the outer end 5s of the flat slab 5, with a predetermined tension force (prestress) being introduced.

2 and 3, a plurality of partition studs 6 are installed on the outer periphery 1s of the building 1. The partition studs 6 are arranged at intervals in the longitudinal direction D1 on both sides of the multi-story earthquake-resistant walls 40A, 40B in the short direction D2. In this embodiment, each partition 6 is arranged on the multi-story earthquake-resistant walls 40A, 40B side, i.e., offset toward the inside of the building 1, from the outer end 5s of the flat slab 5 in the short direction D2.
Each partition 6 extends in the vertical direction, and its upper end is connected to the lower surface 5b of each flat slab 5. The lower end of each partition 6 is connected to the lower flat slab 5. Each partition 6 supports the flat slab 5 from the lower surface 5b, thereby suppressing deflection of the flat slab 5. Each partition 6 is a non-structural material, and is a vertical material that is not expected to support a vertical load acting on the superstructure 3 like an ordinary column.
Particularly in this embodiment, the building 1 does not have any columns other than the first and second multi-story shear walls 41 and 42, the outer periphery shear wall 8, and the partition 6. That is, in this embodiment, the load of the flat slab 5 is supported only by the first and second multi-story shear walls 41 and 42 (and the outer periphery shear wall 8).

As shown in FIG. 2, the flat slab 5 is supported at two points in its central portion in the short side direction D2 by a first multi-story earthquake-resistant wall 41 and a second multi-story earthquake-resistant wall 42.
2, a force acts on the right side of the first multi-story earthquake-resistant wall 41 of the flat slab 5, tending to lower the right side due to the load of that part. Since the flat slab 5 has a certain rigidity, this force is transmitted as an upward force to the left side of the first multi-story earthquake-resistant wall 41 of the flat slab 5, with the joint between the flat slab 5 and the first multi-story earthquake-resistant wall 41 as a fulcrum, but this force is resisted and supported by the second multi-story earthquake-resistant wall 42 joined to the flat slab 5 on the left side of the first multi-story earthquake-resistant wall 41.
Similarly, a force acts on the left side of the second multi-story earthquake-resistant wall 42 of the flat slab 5, tending to lower the left side of the wall due to the load of the said part. This force is transmitted as an upward force to the right side of the second multi-story earthquake-resistant wall 42 of the flat slab 5, with the joint between the flat slab 5 and the second multi-story earthquake-resistant wall 42 as a fulcrum, but this force is resisted and supported by the first multi-story earthquake-resistant wall 41 joined to the flat slab 5 on the right side of the second multi-story earthquake-resistant wall 42.

FIG. 6 is a vertical cross-sectional view showing a joint between a stud and a flat slab.
As shown in Fig. 6, a plurality of punching reinforcement bars 55 are provided around the portion of the flat slab 5 where the partition 6 is joined. Each punching reinforcement bar 55 extends in the vertical direction within the flat slab 5, and has, at its upper and lower ends, upper hooks 55a that engage with the slab reinforcement bars 52 at the upper part of the flat slab 5 and lower hooks 55b that engage with the slab reinforcement bars 52 at the lower part of the flat slab 5. By providing a plurality of punching reinforcement bars 55 around the portion of the flat slab 5 where the partition 6 is joined, the occurrence of punching (punching) cracks in the flat slab 5 can be suppressed without providing a capital.

In the building 1 as described above, as shown in Fig. 1, in each of the stories F2 to F6, a plurality of dwelling units 100 are formed on the flat slab 5 in the area outside the multi-story earthquake-resistant walls 40A, 40B. The plurality of dwelling units 100 are separated from each other by partition walls 105. As shown in Figs. 1 to 3, each dwelling unit 100 has a living room 110 and a balcony 120. The living room 110 and the balcony 120 are separated by a partition 130 consisting of a sliding door, a window, a wall, etc. In addition, the dwelling units 100 on the lower floors of the building 1 do not have a balcony 120 and only have the living room 110.
The living space 110 is disposed on the inner side of the building 1 with respect to the partition 130. The living space 110 is surrounded by the flat slab 5, which are positioned above and below each other, the multi-story earthquake-resistant walls 40A and 40B, and the partition 130. The floor of the living space 110 is constituted by a double floor 113. The double floor 113 is disposed above the flat slab 5 with a gap therebetween and includes a floor material 113p that forms the floor surface of the living space 110, and a support material (not shown) that is provided on the flat slab 5 and supports the floor material 113p from below.

The balcony 120 is disposed on the outer periphery 1s side of the building 1 relative to the partition 130. A parapet wall 140 is provided at the outer end 5s of the flat slab 5. The parapet wall 140 extends upward from the upper surface of the flat slab 5. A gap is formed in the vertical direction between the upper end of the parapet wall 140 and the flat slab 5 above. The balcony 120 is open toward the outside of the building 1 above the parapet wall 140. The floor surface of the balcony 120 is formed by a balcony floor material 123. The balcony floor material 123 is supported on the upper surface of the flat slab 5 via a spacer (not shown) or the like.

On each of the floors F2 to F6, on the flat slab 5, the inside of the core earthquake-resistant wall structure 4, i.e., the multi-story earthquake-resistant walls 40A, 40B, is the building common area 300 where the staircase, elevator, elevator hall, etc. are located. The building common area 300 is provided to include the multi-story earthquake-resistant walls 40A, 40B. The building common area 300 is not limited to the inside of each of the multi-story earthquake-resistant walls 40A, 40B, but may be set to include, for example, the area between the multi-story earthquake-resistant walls 40A, 40B.

As shown in Figures 3 and 4, the equipment pipes 9, such as water supply, sewerage, electric cables, and gas pipes, are led from the building common area 300 through the penetrations 48 provided in the first and second multi-story earthquake-resistant walls 41 and 42 of the multi-story earthquake-resistant walls 40A and 40B, into the living room 110. The equipment pipes 9 are arranged inside the double floor 113 in the living room 110. In the building common area 300, the equipment pipes 9 are arranged below the ceiling structure 303, which is the common area slab. One end of the equipment pipes 9 led into the building common area 300 through the penetrations 48 is bent downward in a recess 309 formed on the underside of the ceiling structure 303, and is housed between the underside of the ceiling structure 303 and the ceiling material 303p arranged at a distance below it.

(Action and Effect)
The building structure A as described above is a building structure A in which multi-story earthquake-resistant walls 40A, 40B are provided on the interior side of the building 1, and comprises multi-story earthquake-resistant walls 40A, 40B in which a first multi-story earthquake-resistant wall 41 and a second multi-story earthquake-resistant wall 42 are arranged opposite each other, a flat slab 5 of roughly uniform thickness which is joined to the first multi-story earthquake-resistant wall 41 and the second multi-story earthquake-resistant wall 42, and a partition wall 6 which is installed on the outer periphery 1s of the building 1 and supports the underside 5b of the flat slab 5.
In the building structure A having such a configuration, the slab is realized by the flat slab 5 having a roughly uniform thickness. Therefore, no beams are visible in the living space 110.
In addition, the flat slab 5 is supported by being joined to the sturdy multi-story earthquake-resistant walls 40A and 40B on the inside side of the building 1. In particular, the multi-story earthquake-resistant walls 40A and 40B are provided with a first multi-story earthquake-resistant wall 41 and a second multi-story earthquake-resistant wall 42 arranged opposite each other, and the flat slab 5 is supported at a plurality of positions by these first multi-story earthquake-resistant wall 41 and second multi-story earthquake-resistant wall 42. For this reason, it is possible to construct a structure in which the load of the flat slab 5 is supported, for example, only by the multi-story earthquake-resistant walls 40A and 40B. In this case, the number of columns as structural materials supporting the load of the flat slab 5 other than the multi-story earthquake-resistant walls 40A and 40B is reduced, or columns as structural materials are not required. This makes it possible to prevent columns from being provided on the inside of the living room 110, thereby narrowing the living space.
Furthermore, studs 6 supporting the underside 5b of the flat slab 5 are provided on the outer periphery 1s of the building 1. This suppresses deflection of the outer end 5s of the flat slab 5 away from the associated earthquake-resistant walls 40A, 40B due to its own weight, so that the distance from the multi-story earthquake-resistant walls 40A, 40B supporting the flat slab 5 to the outer end 5s of the flat slab can be increased, thereby making the living space larger.
Even if studs 6 are provided in this way, the living space can still be kept spacious because, as described above, studs 6 are provided on the outer periphery 1s of building 1. Furthermore, studs 6 are not structural members that support the weight of the building itself and the load of the loads placed on them, but are set as auxiliary materials to suppress cracks and deflections in the floor slab, which allows for a reduction in the cross section of the studs.
The above effects work synergistically to provide a building structure A in which the flat slab 5 has a structure without beams, thereby widening the living space while realizing a sturdy structure.

Additionally, PC steel members 7 are embedded in the flat slab 5, and fixing fasteners 71 for introducing prestress into the PC steel members 7 are provided in the wall cross sections of the multi-story earthquake-resistant walls 40A, 40B.
According to this configuration, the PC steel 7 is embedded in the flat slab 5 in an unbonded manner, which further reduces the deflection of the flat slab 5 and increases its rigidity, and the distance between the multi-story earthquake-resistant walls 40A, 40B and the partition 6 can be further increased. This allows the column-free living space to be further expanded. Furthermore, by embedding the PC steel 7 in the flat slab 5, cracks in the concrete forming the flat slab 5 can be prevented, and creep deformation of the flat slab 5 can be suppressed. Specifically, in order to solve the above problem, the installation position of the PC steel 7 and the wiring height position in the floor slab are determined so that the average prestress stress in the cross section of the floor slab is 1.0 N/ ^mm2 or less, and the tensile stress generated on the bottom surface of the floor slab is reduced, thereby ensuring structural stability.
In addition, the ends of the PC steel members 7 are fixed within the wall cross sections of the multi-story earthquake-resistant walls 40A, 40B using fixing fasteners 71, so that the flat slab 5 is supported more firmly.

In addition, a building common area 300 is provided including the multi-story earthquake-resistant walls 40A, 40B, and a double floor 113 constituting the living space 110 is provided on the upper side of the flat slab 5, and equipment piping 9 is arranged inside the double floor 113, with one end of the equipment piping 9 passing through a penetration part 48 provided in the multi-story earthquake-resistant walls 40A, 40B and being piped between the ceiling structure 303 of the building common area 300 and the ceiling material 303p.
According to this configuration, the equipment piping 9 is arranged in the double floor 113 in the living room 110, and is installed between the ceiling framework 303 and the ceiling material 303p of the building common area 300 formed including the multi-story earthquake-resistant walls 40A, 40B outside the living room 110. Therefore, the equipment piping 9 can be easily moved when changing the room division of the building 1 or updating the equipment. Also, the equipment piping 9 can be stored below the floor material 113p that constitutes the double floor 113 in the living room 110, or above the ceiling material 303p that constitutes the ceiling structure of the building common area 300.

In addition, a core earthquake-resistant wall structure 4 is formed so as to be surrounded in a rectangular shape by the first multi-story earthquake-resistant wall 41 and the second multi-story earthquake-resistant wall 42, and a mat slab 21 is provided on the foundation of the core earthquake-resistant wall structure 4.
According to this configuration, by providing the mat slab 21 at the foundation of the core shear wall structure 4, even if excessive axial force (compressive force or pull-out force) acts on the multi-story shear walls 40A, 40B that form the core shear wall structure 4 during an earthquake, only one of the multi-story shear walls 4 out of the first multi-story shear wall 41 and the second multi-story shear wall 42 that form the core shear wall structure 4 will not rise up, and a compressive force can be applied to the ground G with a constant ground pressure over the entire mat slab 21 at the foundation. This makes it possible to suppress the building 1 from rising up upward.
In addition, the first multi-story earthquake-resistant wall 41 and the second multi-story earthquake-resistant wall 42 are arranged at a certain distance apart to form a rectangular core earthquake-resistant wall structure 4, so that the multiple multi-story earthquake-resistant walls together provide shear resistance to seismic forces acting from various directions, ensuring excellent earthquake resistance performance.

In addition, a plurality of punching reinforcement bars 55 are provided around the portion of the flat slab 5 where the partition 6 is joined.
With this configuration, the joint between the flat slab 5 and the stud 6 is strengthened by the punching reinforcement 55, which suppresses the occurrence of punching cracks in the flat slab 5. For this reason, it is suggested that a capital should be formed by thickening the periphery of the joint between the flat slab 5 and the stud 6, for example. This allows the living space to be made even larger.

(Modification of the embodiment)
The building structure A of the present invention is not limited to the above-described embodiment explained with reference to the drawings, and various modifications are possible within the technical scope.
For example, in the above embodiment, the fixing fasteners 71 for introducing prestress to the PC steel members 7 are provided in the wall cross sections of the multi-story earthquake-resistant walls 40A, 40B, but this is not limited thereto. For example, tensioning fasteners for introducing prestress to the PC steel members 7 may be provided in the wall cross sections of the multi-story earthquake-resistant walls 40A, 40B.
In the above embodiment, the partition 6 is arranged at intervals on both sides of the multi-story shear walls 40A, 40B in the short direction D2, but this is not limited to the above. The partition 6 may be arranged only on one side of the multi-story shear walls 40A, 40B in the short direction D2, and support from below the flat slab 5 extending from the multi-story shear walls 40A, 40B to one side in the short direction D2. The partition 6 may be arranged at intervals in the longitudinal direction D1 with respect to the multi-story shear walls 40A, 40B, and support from below the flat slab 5 extending from the multi-story shear walls 40A, 40B in the short direction D2.
Furthermore, the studs 6 are arranged offset from the outer end 5s of the flat slab 5 toward the multi-story earthquake-resistant walls 40A, 40B, but this is not limited to the above. The studs 6 may be arranged so as to support the outer end 5s of the flat slab 5 from below. Although the studs 6 are made of reinforced concrete, they may be made of concrete-filled steel pipes or hollow steel pipes.

In the present invention, the flat slab may be any one of a prestressed flat slab, a prestressed flat plate, and a prestressed hollow core slab, each having a rectangular uniform slab thickness.
In addition, the configurations described in the above embodiments can be selected or changed as appropriate without departing from the spirit of the present invention.

1 Building 41 First multi-story earthquake-resistant wall 1s Outer periphery 42 Second multi-story earthquake-resistant wall 4 Core earthquake-resistant wall structure 48 Penetration portion 5 Flat slab 71 Fixing fastener 5b Underside 110 Living room 6 Stud 113 Double floor 7 PC steel material 300 Building common portion 9 Equipment piping 303 Ceiling structure 21 Mat slab 303p Ceiling material 40A, 40B Multi-story earthquake-resistant wall A Building structure

Claims (3)

A building structure in which a multi-story earthquake-resistant wall is provided on the inside of the building,
a first multi-story earthquake-resistant wall and a second multi-story earthquake-resistant wall disposed opposite each other;
a flat slab having a roughly uniform thickness, joined to the first multi-story earthquake-resistant wall and the second multi-story earthquake-resistant wall and having PC steel embedded therein;
and a stud installed on the outer periphery of the building and supporting the underside of the flat slab ;
A building structure characterized in that tensioning fasteners or fixing fasteners for introducing prestress into the PC steel members are provided within the wall cross section of the multi-story earthquake-resistant wall . A building structure in which a multi-story earthquake-resistant wall is provided on the inside of the building,
a first multi-story earthquake-resistant wall and a second multi-story earthquake-resistant wall disposed opposite each other;
a flat slab having a roughly uniform thickness that is joined to the first multi-story earthquake-resistant wall and the second multi-story earthquake-resistant wall;
and a stud installed on the outer periphery of the building and supporting the underside of the flat slab;
A building common area is provided including the multi-story earthquake-resistant wall,
A building structure characterized in that a double floor constituting a living space is provided on the upper surface side of the flat slab, and equipment piping is arranged inside the double floor, and one end of the equipment piping is routed between the ceiling structure and ceiling material of the building common area through a penetration part provided in the multi-story earthquake-resistant wall . The building structure described in claim 1 or 2, characterized in that a core earthquake-resistant wall structure is formed so as to be surrounded in a rectangular shape by the first multi-story earthquake-resistant wall and the second multi-story earthquake-resistant wall, and a mat slab is provided at the foundation of the core earthquake-resistant wall structure.

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