JP3127336U - Building floor structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the earthquake resistance of a building with high rigidity.
SOLUTION: A floor structure 1 of a building 10 according to the present invention has a joist 3 installed at predetermined intervals between floor beams 2 arranged in parallel so that the upper surface is flush with the upper surface of the floor beam 2. In addition, a floor plate portion 4 is supported by the floor beam 2 and the joists 3 in contact with the upper surfaces of the floor beams 2 and the joists 3, and the end portions of the joists 3 are upper side surfaces of the floor beams 2. It is fixed to the floor beam 2 by a nail 5 that is fitted to a joist hook 2a that is recessed in the end and that passes from both side surfaces of the end to the end of the end.
[Selection] Figure 2

Description

  The present invention relates to a floor structure of a building particularly suitable for floors of two or more floors.

  The floor structure 50 of the wooden building of a nonpatent literature 1 is illustrated as a floor structure of the conventional building. This floor structure 50 is a typical floor structure of a wooden building. As shown in FIG. 6, a floor joist 52 (for example, 45 mm in width and height) is placed on a floor beam 51 arranged in parallel. 60 mm) is installed at predetermined intervals, and a floor plate portion 53 is supported on the joists 52. There is also a configuration in which the floor plate portion 53 is supported on the floor beam 51 without the joist 52. As the structure of the floor board portion 53, many flooring is laminated on a structural plywood.

Koichi Onoe, “Illustrated Wooden Building Techniques”, 40th edition, Rigakusha, January 25, 2001, p. 5

  However, in the conventional floor structure 50, since the floor board part 53 is supported by the floor beam 51 via the joist 52, and the floor board part 53 and the floor beam 51 are not integrated, resistance to rolling and twisting tends to be insufficient. There is a problem. Moreover, the floor board part 53 has the subject that the resistance with respect to a pitching tends to be insufficient when the flooring is only laminated on the structural plywood.

  An object of the present invention is to provide a building floor structure that solves the above-described problems, has high rigidity, and can improve the earthquake resistance of the building.

In order to achieve the above object, the floor structure of the building of the present invention is
Between the floor beams arranged in parallel, the joists are installed at predetermined intervals so that the upper surface is flush with the upper surfaces of the floor beams, and the floor beams are in contact with the upper surfaces of the floor beams and the joists. The floor board is supported by the beam and joists,
The end of the joist is fitted into a joist hook that is recessed in the upper part of the side surface of the floor beam, and is attached to the floor beam by a nail or a screw that passes from both side surfaces of the end to the end of the end. It is fixed.

  According to this configuration, the floor plate portion and the joists are brought into contact with the upper surfaces of the floor beams and joists, thereby integrating the floor beams and joists and the floor plate portions, and the floor beams and joists and the joists. The number of joints with the floor board can be increased. In addition, the end of the joist is fixed to the floor beam by a nail or a screw that is fitted to the joist hook and that passes from both side surfaces of the end to the end of the end, respectively. The beam and the joist can be firmly integrated. And by these structures, the intensity | strength of a floor structure can be improved significantly, deformation | transformation, such as a twist of a building, can be prevented, and the earthquake resistance of a building can be improved.

  The floor board portion exemplifies a mode in which a structural plywood, a plaster board, and a flooring are laminated in order from the bottom.

  According to this structure, since the said plaster board is laminated | stacked between the said structural plywood and the said flooring, the rigidity of the said floor board part can be improved. Thereby, especially the resistance with respect to pitching can be improved. The plaster board also acts to improve the soundproofing of the floor.

  The floor board portion exemplifies a mode in which a sound insulation sheet is laid between the plaster board and the flooring.

  According to this configuration, the sound insulation of the floor can be further improved by the sound insulation sheet.

  According to the floor structure of a building according to the present invention, there is an excellent effect that it has high rigidity and can improve the earthquake resistance of the building.

  Hereinafter, an embodiment embodying the present invention will be described. 1-5 has shown the wooden building 10 provided with the floor structure 1 of this invention. The wooden building 10 in this example has two floors, and the features are as follows.

《Basic structure》
As shown in FIG. 1, the foundation 11 of the building 10 of this example is a so-called “solid foundation” in which reinforcing bars 12 are arranged in a lattice shape and concrete 13 is poured from the assembled. In general, reinforcing bars with a diameter of 10 mm are arranged with a 300 mm square pitch, but in this example, reinforcing bars 12 with a diameter of 13 mm are arranged with a high density at a 150 mm square pitch in order to increase the strength. The thickness of the flat part of the plane is 150 mm, which is more robust than ordinary 120 mm concrete casting. In addition, in order to suppress the occurrence of corrosion and termites under the floor, a gap is created between the foundation 11 and the base 14 with a packing (not shown), and the ventilation under the floor is about twice that of the case where a ventilation opening is provided in the foundation. Secured. This provides excellent durability.

《Basic construction method》
As shown in FIG. 1, the building 10 of this example employs a so-called conventional wooden construction method. In this construction method, the upward force and the lateral force applied to the building 10 are received by structural materials such as columns 16, beams 2 and 17, and braces (not shown). In the building 10 of this example, the structural panel 24 (9 mm) is further attached to the shaft assembly so that the force applied to the building 10 is received and dispersed. Thereby, it will be in the state like the box with which the building 10 was united, a very strong building will be made, and high earthquake resistance will be exhibited.

《Shaft assembly》
In the building 10 of this example, the through pillars (not shown) are all 4 inch squares, and laminated wood engineering wood is used. Since this engineering wood has a strength about 1.5 times that of the lumber, durability in all directions is greatly improved. The beams 2 and 17 are dry beams. The dry beam is a desiccant with an average moisture content of 18% or less (35% or more for the undried material that is generally used), and can greatly extend the life of the building without shrinkage or deformation.

《Floor structure》
As shown in FIGS. 2 to 4, the floor structure 1 of the building 10 of this example illustrates the setting of a predetermined interval (910 to 1000 mm. In this example, 1000 mm), the floor beams 2 are arranged in parallel. It is installed. The joists 3 are installed between the floor beams 2 with a predetermined interval (303 to 333 mm. In this example, 333 mm) so that the upper surface is flush with the upper surface of the floor beam 2. Thus, the floor beam 2 and the joists 3 are assembled in a lattice shape. The ends of the joists 3 are fitted into joist hooks 2a that are recessed in the upper part of the side surface of the floor beam 2, and a plurality of (in this example) the both ends of both ends of the joists 3 pass into the end of the end. It is fixed to the floor beam 2 by two nails 5 on each side (see FIG. 3 and FIG. 4B). In this example, the joist 3 is fitted into the floor beam 2 with a large insertion. However, the present invention is not limited to this, and the convex portion formed at the end of the joist 3 is used as a concave portion provided on the side surface of the floor beam 2. The structure fitted to the joisting hook 2a can also be suitably employed. Further, if the nail 5 for fixing the joist 3 to the floor beam 2 enters from the upper surface of the joist 3, the joist 3 will rattle up and down with respect to the floor beam 2 when the nail 5 is loosened due to vertical vibration or the like. In this example, the nail 5 is provided so as to come out from the side of the end of the joist 3 to the end of the end. Such a phenomenon can be prevented. Further, in this example, the nails 5 entering from both side surfaces of the end of the joist 3 are provided so that the axial directions of the nails 5 intersect with each other, so that the joist 3 can be prevented from coming off from the floor beam 2. Thus, the floor beam 2 and the joist 3 can be firmly integrated.

  As the joist 3, it is exemplified that wood having a width of 30 to 45 mm and a height of 30 to 105 mm is used. In this example, wood having a width of 45 mm and a height of 105 mm is used as the joist 3, and by setting the height to be particularly large (about twice the width), the beam property against pitching is improved. Yes.

  A floor plate portion 4 is supported on the floor beam 2 and the joists 3 in contact with their upper surfaces. As shown in FIG. 4, the floor board portion 4 is formed by laminating a structural plywood 6, a plaster board 7, a sound insulation sheet 8, and a flooring 9 in order from the bottom. In this example, the structural plywood 6 and the plaster board 7 are laid so that their long side directions are orthogonal to each other. Thereby, the rigidity of the floor board part 4 is improved. As a method for fixing the structural plywood 6, the plaster board 7, the sound insulation sheet 8, and the flooring 9, a known method such as a nail or a screw can be appropriately employed. As the structural plywood 6, the plaster board 7, and the flooring 9, it is exemplified that a material having a thickness of 9.5 to 12.5 mm is used. In this example, as the structural plywood 6, the plaster board 7, and the flooring 9, those having a thickness of 12.5 mm are used. Further, as the sound insulating sheet 8, a sheet having a thickness of 1 to 2 mm is used in this example.

《Wall structure》
As shown in FIG. 5, the wall 20 of the building 10 of this example employs an outer wall ventilation method in which a ventilation layer 22 (width of about 16 mm in this example) is provided on the siding 21 side as an outer wall. Since moisture is a small particle of about 1/25 million of raindrops, indoor moisture enters the wall through the interior material 26. However, when the wall is sealed, there is no escape from moisture in the wall. Condensation may occur. By adopting the ventilation method, moisture that has entered from the room passes through the ventilation layer 22 and is quickly released to the outside to suppress dew condensation in the wall. Moreover, since outside air is naturally taken into the ventilation layer 22 in the wall and the air is circulated, there is no condensation in the wall and the durability of the wall structure is greatly improved. In addition, by adopting a ventilation method, a space is created between the siding 21 and the moisture-permeable waterproof paper 23 affixed to the outer surface of the structural panel 24. Even if rainwater enters the back side of the water, it can be quickly discharged. Further, according to the outer wall ventilation method, when the siding 21 is exposed to direct sunlight and the siding 21 receives a considerable amount of heat, an upward air flow is generated in the ventilation layer 22, and a part of the received heat is generated in the ventilation layer 22. It is discharged outdoors by the ventilation of the inside (heat shielding action). Furthermore, by using rock wool (thickness of about 55 mm in this example) having excellent heat insulation for the heat insulating material 25 in the wall together with this ventilation method, significant energy saving is realized with regard to cooling and heating of the building 10. I am doing so.

  According to the floor structure 1 of the building 10 of the present invention configured as described above, the floor plate portion 4 is in contact with the upper surfaces of the floor beam 2 and the joists 3, so that the floor beams 2, the joists 3 and the While integrating the floor board part 4, the joint location of this floor beam 2, this joist 3, and this floor board part 4 can be increased. Further, the end of the joist 3 is fixed to the floor beam 2 by a nail 5 that is fitted to the joist hook 2a and that passes from both side surfaces of the end to the end of the end. And the joist 3 can be firmly integrated. And the intensity | strength of the floor structure 1 is improved significantly by these structures, deformation | transformation, such as a twist of the building 10, can be prevented, and the earthquake resistance of the building 10 can be improved.

  Moreover, since the plaster board 7 is laminated | stacked between the structural plywood 6 and the flooring 9, the rigidity of the floor board part 4 can be improved. Thereby, especially the resistance with respect to pitching can be improved. The plaster board 7 also acts to improve the soundproofing of the floor.

  Moreover, since the sound insulation sheet 8 is laid between the plaster board 7 and the flooring 9, the floor board part 4 can further improve the sound insulation of a floor.

  In addition, this invention is not limited to the said embodiment, In the range which does not deviate from the meaning of invention, it can change suitably and can be actualized.

[BRIEF DESCRIPTION OF THE DRAWINGS] It is a partially broken perspective view which shows the building provided with the floor structure based on one Embodiment which actualized this invention. It is a perspective view which shows the same floor structure. FIG. 3 is a view taken in the direction of arrow III in FIG. 2. (A) is the IVa-IVa sectional view taken on the line of FIG. 2, (b) is the IVb-IVb sectional view taken on the line of FIG. It is sectional drawing of the wall of the building. It is a perspective view which shows the floor structure of the conventional building.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Floor structure 2 Floor beam 2a joisting 3 joist 4 floor board part 5 nail 6 structural plywood 7 plaster board 8 sound insulation sheet 9 flooring 10 building 11 foundation 12 reinforcing bar 13 concrete 14 foundation 16 pillar 20 wall 21 siding 22 ventilation layer 23 moisture permeability Waterproof paper 24 Structural panel 25 Heat insulation material 26 Interior material

Claims (3)

Between the floor beams arranged in parallel, the joists are installed at predetermined intervals so that the upper surface is flush with the upper surfaces of the floor beams, and the floor beams are in contact with the upper surfaces of the floor beams and the joists. The floor board is supported by the beam and joists,
The end of the joist is fitted into a joist hook that is recessed in the upper part of the side surface of the floor beam, and is attached to the floor beam by a nail or a screw that passes from both side surfaces of the end to the end of the end. The floor structure of a fixed building.   The building floor structure according to claim 1, wherein the floor board portion is formed by laminating a structural plywood, a plaster board, and flooring in order from the bottom.   The floor structure of a building according to claim 2, wherein the floor board portion is formed by laying a sound insulation sheet between the plaster board and the flooring.

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