JP6556982B2 - Building unit installation structure - Google Patents

Description

  The present invention relates to an installation structure for a building unit.

  Conventionally, in a floor structure of a building unit, a plurality of floor beams are bridged between a pair of opposing floor beams, and a plurality of floor joists are installed on the floor beams so as to be orthogonal to the floor beams. The configuration is known (see, for example, Patent Document 1). By providing a plurality of floor beams in this way, even if a heavy object is installed in the building unit, it can be stably supported.

Japanese Patent Laid-Open No. 4-198538

However, if the structure has a plurality of floor beams, the number of members inevitably increases. In addition, even if a plurality of floor beams are simply installed, if a heavy object is installed, bending occurs, and there is a limit to the weight that can be supported. Furthermore, since the load of heavy objects is received by the building unit itself, the burden on the building unit is large.
Moreover, in order to suppress a burden, the structure which forms soil concrete so that it may continue on the upper surface of a foundation, and installs a heavy article by making the upper surface of the soil concrete into a floor surface is also considered. However, with such a configuration, not only the floor surface of the adjacent normal building unit and the upper surface between the soil have a step, but also when the soil concrete straddles multiple building units. Since the floor beam is lost, the rigidity of the building unit itself is reduced.
An object of the present invention is to provide a building unit that can suppress the burden while maintaining the rigidity of the building unit even if the number of members for supporting the heavy object is reduced, and can stably support the heavy object. Is to provide an installation structure.

The installation structure of the building unit according to the invention described in claim 1 is, for example, as shown in FIGS.
In the installation structure of the building unit installed on the foundation 30,
The building unit includes a normal unit 10 and a floor height unit 20 having a height higher than that of the normal unit 10.
When the normal unit 10 and the floor height unit 20 are arranged adjacent to each other on the foundation 30,
The foundation 30 on which the floor height unit 20 is installed is set to be higher than the upper surface 31 of the foundation 30 on which the normal unit 10 is installed so that the normal unit 10 and the floor height unit 20 have the same height. The upper surface 32 of the substrate is formed lower,
A floor slab 22 is installed in a space surrounded by a plurality of floor beams 13 constituting the floor height unit 20, and a support layer 70 that is supported directly below the floor slab 22 is disposed on the ground G.
The upper surface of the floor beam 13 of the floor height unit 20 is provided at a position lower than the upper surface of the support layer 70,
In an upper surface of a floor body (floor plate) 17 installed in a space surrounded by a plurality of floor beams 13 forming the normal unit 10 and a space surrounded by a plurality of floor beams 13 forming the floor height unit 20. The upper surface of the installed floor slab 22 is substantially flush,
An interference prevention material 60 is interposed between the upper surface of the floor beam 13 of the floor height unit 20 and the lower surface of the floor slab 22 located on the upper surface of the support layer 70 ,
The interference preventing member 60 is also interposed between the side surface of the foundation 30 and the side surfaces of the support layer 70 and the ground G ,
Further, the interference preventing member 60 is also interposed between the side surface of the floor beam 13 of the normal unit 10 and the side surface of the floor slab 22 of the floor height unit 20,
The interference preventing material 60 is continuous .

According to the first aspect of the present invention, the upper surface 32 of the foundation 30 on which the floor height unit 20 is installed is formed lower than the upper surface 31 of the foundation 30 on which the ordinary unit 10 is installed. Since the heights of the unit 10 and the floor height unit 20 are the same, even when the normal unit 10 and the floor height unit 20 having different heights are arranged adjacent to each other on the same foundation 30, they have the same height. can do.
Since the floor slab 22 is supported by the support layer 70, heavy object placed on the floor slab 22, to be supported by the support layer 70 through the floor slab 22 with increased strength of the floor body become. Therefore, even if the number of members for supporting a heavy object that has been conventionally required is reduced, the heavy object can be stably supported.
Moreover, since it is the structure which supports the floor slab 22 only with the support layer 70, a building unit can be used as it is and the rigidity of a building unit can also be maintained.
Then, in order to heavy in the supporting layer 70 immediately below the floor slab 22 is supported, the deflection of the floor slab 22 itself would be inhibited, load on the building unit (floor height unit 20) can be suppressed.
Furthermore, since the upper surface of the floor beam 13 is provided at a position lower than the upper surface of the support layer 70, most of the load applied to the floor slab 22 is supported by the support layer 70 and the ground G below the floor beam 13. Will be. Therefore, while being able to support a heavy article more stably, the burden with respect to a building unit (floor height unit 20) can also be suppressed.
In addition, the upper surface of a floor body (floor board) 17 installed in a space surrounded by a plurality of floor beams 13 forming the normal unit 10 and a space surrounded by the plurality of floor beams 13 forming a floor height unit 20 are provided. Since the upper surface of the installed floor slab is substantially flush, even when the normal unit 10 and the floor height unit 20 having different heights are arranged adjacent to each other on the same foundation 30, the floor height is made the same. be able to.
In addition, since the interference prevention material 60 is interposed between the upper surface of the floor beam 13 of the floor height unit 20 and the lower surface of the floor slab 22 positioned on the upper surface of the support layer 70, the upper surface of the floor beam 13 and the floor slab It is possible to prevent the lower surface located on the upper surface of the support layer 70 of 22 from interfering. The load of the heavy object placed on the floor slab 22 is transmitted not to the floor beam 13 but to the support layer 70 directly below and the ground G below it by the interference preventing member 60. Thereby, it can prevent that the floor beam 13 will be damaged by the load of a heavy article.
Moreover, if the interference preventing material 60 is a heat insulating material, heat transfer between the floor beam 13 and the floor slab 22 can be prevented, and a thermal bridge can be prevented.

The invention according to claim 2 is the installation structure of the building unit according to claim 1 , for example, as shown in FIG.
An anchor 50 for fixing the partition wall 40 is attached to the floor slab 22.

According to the invention described in claim 2 , since the anchor 50 for fixing the partition wall 40 is attached to the floor slab 22, the partition wall 40 can be easily attached to the floor slab 22 by using the anchor 50. Can be installed.

  According to the present invention, even if the number of members for supporting heavy objects is reduced, the burden can be suppressed while maintaining the rigidity of the building unit, and the heavy objects can be stably supported. .

It is a perspective view which shows only two adjacent building units among the several building units which comprise the unit type building which concerns on this embodiment. It is a fragmentary sectional view which shows the installation structure of two adjacent building units of FIG. It is explanatory drawing which shows the other example of arrangement | positioning of the interference prevention material which concerns on this embodiment. It is explanatory drawing which shows the other example of arrangement | positioning of the interference prevention material which concerns on this embodiment.

Hereinafter, the building unit installation structure according to the present embodiment will be described with reference to the drawings.
FIG. 1 is a perspective view showing only two adjacent building units among a plurality of building units constituting a unit type building. FIG. 2 is a partial cross-sectional view showing the installation structure of two adjacent building units.
Note that, of the two building units shown in FIGS. 1 and 2, one building unit is the normal unit 10, and the other unit is the floor height unit 20 having a height higher than that of the normal unit 10.
The floor height unit 20 is a building unit having a column longer than that of the normal unit 10, and is used to increase the ceiling height of the living room higher than usual, to lower the floor level, and the like. The floor height unit 20 has a height dimension that is an upper limit of transportation restrictions, and the normal unit 10 has a height dimension for comfortably living space.

As shown in FIGS. 1 and 2, the normal unit 10 and the floor height unit 20 are arranged on a foundation 30. The base 30 is higher than the upper surface 31 of the base 30 on which the normal unit 10 is installed so that the upper end of the normal unit 10 and the upper end of the floor unit 20 have the same height position. The upper surface 32 of the foundation 30 to be installed is formed lower. That is, in the upper end portion of the foundation 30, a portion where the floor height unit 20 is installed is notched and is one step lower than a portion where the normal unit 10 is installed.
And since the height position of the upper end part of the normal unit 10 and the upper end part of the floor height unit 20 is the same, it is possible to install the same building unit on these upper floors in the same height position. it can. Thereby, the ceiling surface and floor surface of a plurality of building units on the upper floor can be made substantially flush. The building unit on the upper floor, the normal unit 10 and the floor height unit 20 are appropriately connected by a positioning pin, a connecting plate, a bolt or the like (not shown).

The normal unit 10 has four columns 11, four ceiling beams 12 that connect the upper ends of the columns 11, and four floor beams 13 that connect the lower ends of the columns 11. And.
The four ceiling beams 12 are composed of two long-side ceiling beams 12a and 12a arranged on the long side and two short-side ceiling beams 12b shorter than the long-side ceiling beam 12a arranged on the short side. , 12b. The four floor beams 13 are composed of two long side floor beams 13a and 13a arranged on the long side and two short side floor beams 13b shorter than the long side floor beam 13a arranged on the short side. , 13b. Each column 11 is formed in a square cylindrical shape, and the ceiling beam 12 and the floor beam 13 are each formed in a U-shaped cross section.
Between the two long-side ceiling beams 12a and 12a, a plurality of ceiling field edges 14 are laid in parallel with the short-side ceiling beams 12b, and these ceiling field edges 14 are in the longitudinal direction of the long-side ceiling beams 12a. Are provided at predetermined intervals. A ceiling plate 15 is fixed to the lower surface of the ceiling field edges 14.
Between the two long side floor beams 13a and 13a, a plurality of joists 16 are laid in parallel to the short side floor beams 13b, and these joists 16 are arranged at predetermined intervals in the longitudinal direction of the long side floor beams 13a. Is provided. Floor plates 17 are attached to the upper surfaces of the joists 16... And the floor beams 13.
Note that the upper end portion of the column 11 and the end portion of the ceiling beam 12 are joined by a column head joining member 18, and the lower end portion of the column 11 and the end portion of the floor beam 13 are joined by a column base joining member 19.

The floor height unit 20 has substantially the same configuration as the normal unit 10. For this reason, about the same part, the code | symbol same as the structural member of the normal unit 10 is attached | subjected, and the description is abbreviate | omitted.
The four columns 21 of the floor height unit 20 are formed longer than the columns 11 of the normal unit 10. Thereby, the floor height unit 20 has a height higher than the normal unit 10.
In the floor height unit 20, the joist 16 is not installed between the long side floor beams 13a and 13b.
Further, a floor slab 22 as a floor body is attached to the upper surface of the floor beam 13 of the floor height unit 20. The floor slab 22 is formed to have a thickness such that the upper surface of the floor slab 22 and the upper surface of the floor plate 17 of the normal unit 10 are substantially flush.

  An anchor 50 for fixing the partition wall 40 is attached to a predetermined location on the upper surface of the floor slab 22. The partition wall 40 has a U-shaped runner 41 whose upper part is open, a plurality of studs 42 that are spaced apart from the runner 41 by a predetermined distance, and a pair of runners 41 and the studs 42 that cover the studs 42. A face material 43 is provided. The plurality of studs 42 are connected via a steady rest (not shown). A heat insulating material is disposed in the internal space formed by the runner 41, the stud 42 and the face material 43. The runner 41 is provided with an engagement hole with which the anchor 50 is engaged.

And between the floor slab 22 of the floor height unit 20 and the floor beam 13 of the normal unit 10, between the floor slab 22 and the floor beam 13 of the floor height unit 20, for example, heat insulation such as foamed polystyrene foam is provided. The interference prevention material 60 which has has intervened. The interference preventing member 60 is also continuously attached to the floor beams 13 of the floor height unit 20 and the side surfaces of the foundation 30.
As shown in FIG. 3, when the floor slab 22 is supported by the foundation 30 via the pair of floor beams 13, the upper surface and the side surface of the pair of floor beams 13 and the side surface of the foundation 30 are continuously provided. It is preferable to dispose the interference preventing material 60 so as to cover and prevent interference between the floor beam 13 and a support layer 70 described later.
Further, as shown in FIG. 4, when the support layer 70 is supported by the foundation 30, the interference prevention material 60 is disposed so as to continuously cover the upper surface and the side surface of the foundation 30, and the floor beam 13 is supported. It is preferable to prevent interference with the layer 70.

Further, in a space below the floor slab 22 of the floor height unit 20, that is, a space surrounded by a plurality of floor beams 13 forming the floor height unit 20, the position of the ground G 1 below the floor plate 17 of the normal unit 10 is higher. Filling has been done so that it becomes high. A support layer 70 made of, for example, crushed stone is formed over the entire surface of the ground G2 of the embankment. Since the support layer 70 is formed of crushed stone, the load can be evenly transmitted to the ground G2. The ground G forming the ground G1 and the ground G2 is continuous with the ground G supporting the foundation 30.
In addition to crushed stone, mortar, concrete, or the like can be used as the support layer 70. Furthermore, as the support layer 70, the ground can be used as it is. In such a case, it is possible to make a columnar improvement on the ground and install the floor slab 22 directly on the upper surface of the columnar improvement, or to install a steel pipe pile and install the floor slab 22 directly on the upper surface of the steel pipe pile. preferable.
The thickness of the support layer 70 is set to a thickness at which the upper surface of the support layer 70 contacts the lower surface of the floor slab 22. Further, since the upper surface of the floor beam 13 is provided at a position lower than the upper surface of the support layer 70, most of the load applied to the floor slab 22 is supported by the support layer 70.
Here, the support layer 70 supports the floor of the floor closest to the ground in the building.
The range in plan view in which the support layer 70 is provided is in a region surrounded by the floor beams 13 of at least one building unit. The support layer 70 may be provided below all floor bodies on the floor closest to the ground. Thus, when the support layer 70 is provided in a wide range with respect to the building, the building unit is supported by the foundation 30 and the floor beam 13 is embedded in the wide support layer 70. It becomes.

As described above, according to the present embodiment, since the floor slab 22 is supported by the support layer 70, heavy objects placed on the floor slab 22 are supported by the support layer 70 via the floor slab 22. Will be. Therefore, even if it is necessary in the past and the number of members for supporting heavy objects is reduced, the heavy objects can be stably supported. In addition, since the floor slab 22 is simply supported by the support layer 70, the floor height unit 20 can be used as it is, and the rigidity of the floor height unit 20 can be maintained.
And since a heavy article is supported by the support layer 70 directly under the floor slab 22, the bending of the floor slab 22 itself is also suppressed, and the burden on the floor height unit 20 can also be suppressed.

  Further, since the upper surface of the floor beam 13 is provided at a position lower than the upper surface of the support layer 70, most of the load applied to the floor slab 22 is supported by the support layer 70 rather than the floor beam 13. Therefore, it is possible to support a heavy object more stably and to suppress a burden on the floor height unit 20.

Moreover, since the interference preventing material 60 is interposed between the floor beam 13 and the floor slab 22 of the floor height unit 20, it is possible to prevent the floor beam 13 and the floor slab 22 from interfering with each other. The load of the heavy object placed on the floor slab 22 is transmitted not to the floor beam 13 but to the support layer 70 directly below and the ground G below it by the interference preventing member 60. Thereby, it can prevent that the floor beam 13 will be damaged by the load of a heavy article.
Moreover, since the interference preventing material 60 is a heat insulating material, heat transfer between the floor beam 13 and the floor slab 22 can be prevented, and a thermal bridge can be prevented.

  In addition, the upper surface 32 of the foundation 30 on which the floor height unit 20 is installed is formed lower than the upper surface 31 of the foundation 30 on which the normal unit 10 is installed. Since the height is the same, even when the normal unit 10 and the floor height unit 20 having different heights are arranged on the same foundation 30, both can be made the same height.

  Further, the upper surface of the floor plate 17 installed in the space surrounded by the plurality of floor beams 13 forming the normal unit 10 and the floor installed in the space surrounded by the plurality of floor beams 13 forming the upper floor unit 20. Since the upper surface of the slab 22 is substantially flush, the floor height can be made the same even when the normal unit 10 and the floor height unit 20 having different heights are arranged on the same foundation 30.

  Further, since the floor body is the floor slab 22, the strength of the floor body can be increased.

  Moreover, since the anchor 50 for fixing the partition wall 40 is attached to the floor slab 22, the partition wall 40 can be easily installed on the floor slab 22 by using the anchor 50.

Note that the present invention is not limited to the above embodiment, and can be modified as appropriate.
For example, in the above-described embodiment, the case where the support layer 70 supports the floor slab 22 by the support layer 70 contacting the entire lower surface of the floor slab 22 is described as an example. Can be stably supported, the support layer 70 may not be in contact with the entire lower surface of the floor slab 22.
Moreover, it is also possible to provide a support layer for the normal unit 10 so that the floor plate 17 is supported by the support layer. Also in this case, the heavy object placed on the floor board 17 can be supported by the support layer 70 via the floor board 17, and the burden on the normal unit 10 can also be suppressed.

DESCRIPTION OF SYMBOLS 10 Normal unit 11 Pillar 12 Ceiling beam 13 Floor beam 14 Ceiling edge 15 Ceiling board 16 joist 17 Floor board 20 Floor high unit 21 Pillar 22 Floor slab (floor body)
30 Foundation 31 Upper surface 32 Upper surface 40 Partition wall 50 Anchor 60 Interference prevention material 70 Support layer

Claims (2)

In the installation structure of building units installed on the foundation,
The building unit includes a normal unit and a floor height unit having a height higher than the normal unit.
When the normal unit and the floor height unit are arranged adjacent to each other on the foundation,
The upper surface of the foundation on which the floor height unit is installed is formed lower than the upper surface of the foundation on which the normal unit is installed so that the normal unit and the floor height unit have the same height. And
Wherein the enclosed space into a plurality of floor beams constituting the floor height units, with the floor slab is placed, a support layer for supporting directly under the floor slab is placed on the ground,
The upper surface of the floor beam of the floor height unit is provided at a position lower than the upper surface of the support layer,
An upper surface of a floor body installed in a space surrounded by a plurality of floor beams forming the normal unit, and an upper surface of the floor slab installed in a space surrounded by the plurality of floor beams forming the floor height unit Is substantially the same,
An interference prevention material is interposed between the upper surface of the floor beam of the floor height unit and the lower surface located on the upper surface of the support layer of the floor slab ,
The interference preventing material is also interposed between the side surface of the foundation and the side surface of the support layer and the ground ,
Furthermore, the interference preventing material is also interposed between the side surface of the floor beam of the normal unit and the side surface of the floor slab of the floor height unit,
An installation structure of a building unit, wherein the interference preventing material is continuous . In the building unit installation structure according to claim 1 ,
An installation structure for a building unit, wherein an anchor for fixing a partition wall is attached to the floor slab .

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