JP6265735B2 - Consolidated building - Google Patents

Description

  The present invention relates to a connected building.

Conventionally, in a connected building in which a plurality of buildings are connected by a connecting portion, a plurality of buildings are connected to the connecting portion using an expansion joint, and the difference in displacement of each building is absorbed. For this reason, at the time of an earthquake, there is a fear that the finishing material of the building may be damaged due to the difference in displacement generated in the connecting portion of the building due to the twisting deformation of the building.
As a technique for connecting a plurality of building units apart from each other to form one building without using an expansion joint, for example, there is Patent Document 1.

JP 2010-84465 A

  However, Patent Document 1 is a technique related to a connection structure in which a plurality of building units arranged on both sides with a passage interval are connected to each other by a connection beam and a horizontal brace to ensure the rigidity of the horizontal surface. Specifically, the connecting structure is provided horizontally in a region surrounded by a plurality of connecting beams that connect the ceiling beams of the lower-floor building unit, and a pair of opposing connecting beams and the ceiling beam of the lower-floor building unit. The torsional deformation that occurs in the building during an earthquake cannot be suppressed.

  An object of this invention is to provide the connection building which suppresses the twist deformation | transformation which arises in a building at the time of an earthquake in view of the said fact.

The connected building which concerns on invention of Claim 1 connects the adjacent building, the column beam frame of the said building, and the connection column beam frame provided with the steel column and the steel beam, and the said column. Connecting slabs with braces spanned horizontally, the connecting slabs being connected to respective floors of the building and entering at least one of the buildings, It is characterized by constituting a part.

According to the first aspect of the present invention, the column beam frames of the building are connected to each other by the connecting column beam frames. Moreover, the connection slab which comprises the floor of a connection column beam frame enters into at least one of the buildings connected, and comprises a part of floor of the buildings connected. Thereby, the building in which the connection slab entered and the connection column beam frame can be connected with high rigidity.
As a result, at the time of an earthquake, the connected buildings behave integrally and the torsional deformation between the buildings is suppressed.

According to a second aspect of the invention, in the connecting building according to claim 1, wherein the connecting slab is supported with pre-Symbol beam to the brace has the beam and the brace integral with been reinforced concrete slab It is characterized by being.

  According to invention of Claim 2, the rigidity of the horizontal direction between the columns of a connection column beam frame is improved with a brace. In addition, the reinforced concrete floor slab integrates the beams and braces, further enhancing the horizontal rigidity of the connecting column beam frame.

  A third aspect of the present invention is the connected building according to the second aspect, wherein the reinforced concrete floor slab is an iron plate joined to the beam and the brace, and concrete placed on the iron plate to which a stud is welded. It is characterized by having.

  According to the invention described in claim 3, the iron plate is joined to the beam and the brace, and the concrete is placed on the iron plate to which the stud is welded. Thereby, the intensity | strength of a reinforced concrete floor slab can be made high.

  Since this invention is set as the said structure, the connection building which suppresses the twist deformation | transformation which arises in a building at the time of an earthquake can be provided.

It is an external appearance perspective view which shows the basic composition of the connection building which concerns on embodiment of this invention. It is a top view which shows the connection slab of the connection building which concerns on embodiment of this invention. It is a perspective view which shows the basic composition of the connection slab of the connection building which concerns on embodiment of this invention. It is sectional drawing which shows the basic composition of the connection slab of the connection building which concerns on embodiment of this invention.

The connection building 10 which concerns on embodiment of this invention is demonstrated using FIGS. 1-4.
Here, FIG. 1 is an external perspective view of the column beam frame of the connected building 10, FIG. 2 is a plan view of the floor slab 24, FIG. 3 is a perspective view of the floor slab 24, and FIG.

As shown in FIG. 1, a connected building 10 is a building in which two large-scale multi-storey buildings 12 and 14 constructed adjacent to each other are connected and integrated by a connecting body 20.
The building 12 includes a foundation 43 and an underground structure 44. The column beam frame 16 is constructed of columns 51 and beams 53, and a floor slab (floor) 40 is provided on each floor. A part of the column beam frame 16 of the building 12 is connected to a column beam frame (connected column beam frame) 22 of the connection body 20 by a beam member 48.

  The building 14 adjacent to the building 12 has a foundation 45 and an underground structure 46, and the column beam frame 18 is constructed by columns 52 and beams 54, and floor slabs (floors) 42 are provided on each floor. Yes. A part of the column beam frame 18 of the building 14 is connected to the column beam frame 22 of the connector 20 by a beam member 50. Thereby, the column beam frames 16 and 18 are integrated via the column beam frame 22, and the connection building 10 is made into one highly rigid building.

  As shown in the plan view of the representative floor in FIG. 2, the floor slab (connection slab) 24 constituting the floor of the column beam frame 22 is a portion surrounded by a broken line. The floor slab 24 is connected to the floor slab 40 of the column beam frame 16 to be connected at the position of the beam 48. As will be described later, the floor slab 24 is a connecting floor slab with increased rigidity, and the floor slab 40 is a floor slab of a generally structured building. The floor slab 24 and the floor slab 40 are integrally formed by placing slab concrete.

Further, the floor slab 24 is connected to the floor slab 42 of the column beam frame 18 at the position of the beam 50. The floor slab 42 is a floor slab of a building having a general configuration, and the floor slab 24 and the floor slab 42 are integrally formed by placing slab concrete.
Thereby, the floor slab 40 and the floor slab 42 are formed as one floor surface that is continuous through the floor slab 24.

At this time, a part of the floor slab 24 enters the inside of the column beam frame 18 and constitutes a part of the floor slab 42 of the column beam frame 18 as a floor slab of the columns 52 and 54 of the column beam frame 18. . At this time, as will be described later, the floor slab 24 has a steel plate 34, and the column beam frame 18 and the column beam frame 22 in which the floor slab 24 enters can be connected with high rigidity.
Here, the amount of entry of the floor slab 24 into the floor slab 42 (the area into which the floor slab 24 enters) is determined according to the required joint strength between the column beam frame 18 and the column beam frame 22.

  The floor slab 24 may be configured to enter the inside of the building 12 instead of the inside of the building 14. Moreover, the structure which the floor slab 24 penetrates into the inside of each of the buildings 12 and 14 may be sufficient. Furthermore, the floor where the floor slab 24 enters the inside of the building 14 may be different from the floor where the floor slab 24 enters the inside of the building 12 for each floor of the column beam structure 22.

Here, the configuration of the floor slab 24 will be described with reference to FIGS.
As shown in the perspective view of FIG. 3, the floor slab 24 constitutes a floor of the column beam frame 22, and the column beam frame 22 passes between the steel column 28 and the column 28 in a plan view in a rectangular shape. The steel beam 30 is made of steel. In addition, a brace 26 passed between the pillars 28 is provided in the horizontal direction inside the space surrounded by the beam 30 in a rectangular shape. Here, the column 28 and the beam 30 and the column 28 and the brace 26 are welded.

  The brace 26 is formed of a steel material such as H-shaped steel, for example, and is spanned between the pillars 28 and 28 at an angle. Further, the braces 26 intersect at a central portion (inside surrounded by the four pillars 28) arranged diagonally. Thereby, the horizontal rigidity of the floor slab 24 can be increased.

A reinforced concrete floor slab 32 is supported on the beam 30 and the brace 26 of the column beam frame 22.
As shown in the cross-sectional view of FIG. 4, the reinforced concrete floor slab 32 has an iron plate 34 joined to the beam 30 and the brace 26 of the column beam frame 22. The iron plate 34 is sized to cover the entire surface of the beam 30 and the brace 26 of the column beam frame 22 in plan view, and the lower surface is welded to the beam 30 and the brace 26. By setting it as this structure, the rigidity of the reinforced concrete floor slab 32 can be adjusted by changing board thickness T1 of the iron plate 34. FIG.

  A plurality of studs 36 are welded to the upper surface of the iron plate 34. In this state, the concrete 38 is cast on the iron plate 34, and the iron plate 34 and the concrete 38 are integrated. Thereby, the rigidity of the reinforced concrete floor slab 32 can be increased by the iron plate 34 welded and joined to the beam 30 and the brace 26 and the concrete 38 integrated on the iron plate 34. At this time, the rigidity of the reinforced concrete floor slab 32 can be adjusted by changing the thickness T2 of the concrete 38. Below the reinforced concrete floor slab 32, a lower floor ceiling board 56 is provided.

As described above, the column beam frame 22 of the connecting body 20 is connected to the column beam frames 16 and 18 of the plurality of buildings 12 and 14 to be connected, and the floor slab 24 constituting the floor of the column beam frame 22 is provided. The floor slabs 40 and 42 of the plurality of buildings 12 and 14 to be connected are respectively connected.
At this time, the floor slab 24 enters the interior of the connected building 14 and constitutes a part of the floor slab 42 of the connected building 14. Thereby, the building 14 in which the floor slab 24 enters and the column beam frame 22 are connected with high rigidity.

  Since the present invention is configured as described above, the connected building 10 can be made to behave integrally during an earthquake, a strong wind, a long-term load, and the like, and a displacement difference generated in the connecting portion can be suppressed. As a result, torsional deformation that occurs in each building can be suppressed.

  In addition, in this embodiment, the connection building 10 demonstrated the example which connects two buildings 12 and 14 adjacent. However, the present invention is not limited to this, and a configuration in which three or more adjacent buildings are connected by one connecting body 20 may be used. In this case, at least one floor slab 24 may enter the building.

Moreover, in this embodiment, the height of the buildings 12 and 14 demonstrated the case where all were the same height. However, the present invention is not limited to this. Even in the case of buildings having different heights, the same height range may be connected by the connecting body 20.

  Moreover, the connection building 10 demonstrated the example which connects the ground floor part of the adjacent buildings 12 and 14. FIG. However, the present invention is not limited to this, and may be adopted in the basement floor portions of the adjacent buildings 12 and 14. That is, although illustration is omitted, only the basement part may be connected by a connecting body, or a part or all of both the ground floor part and the basement part may be connected by a connecting body.

Further, in the present embodiment, the column beam frame 22 is configured such that the floor slabs 24 are arranged on all the floors from the lower floor to the upper floor of the connected buildings. However, it is not limited to this, The structure which includes the floor in which the floor slab 24 is not arrange | positioned in the middle may be sufficient.

10 consolidated buildings 12 buildings (consolidated buildings)
14 buildings (consolidated buildings)
16 Column-beam frame 18 Column-beam frame 20 Linkage (linkage building)
22 Column beam frame (Linked column beam frame, Linked building)
24 Floor slabs (concatenated slabs)
26 Brace (Linked Slab)
28 columns 30 beams 32 reinforced concrete slabs (connected slabs)
34 Iron plate 36 Stud 38 Concrete 40 Floor slab (building floor)
42 Floor slabs (building floors)

Claims (3)

Adjacent buildings,
Connecting the column beam frames of the building and connecting column beam frames comprising steel columns and steel beams;
A connecting slab having a brace horizontally spanning the pillar;
The connected slab is connected to each floor of the building and enters at least one of the buildings to form a part of the floor of the building. The connecting slab, connecting the building of claim 1, supported with the previous SL beam on the brace has the beam and the brace integral with been reinforced concrete deck. The reinforced concrete floor slab is
An iron plate joined to the beam and the brace;
Concrete placed on the steel plate to which the stud is welded;
The connected building according to claim 2, comprising:

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