JPH10331279A - Heat-insulating structure of building - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide the heat-insulating structure of a building, in which no opening is formed between abutted end faces at the time of the execution of works and the execution of works is simplified, in the heat-insulating stricture in which the end faces of tabular heat-insulating materials are abutted mutually and arranged. SOLUTION: In the heat-insulating structure of the building, end faces 13 at the side edges of heat-insulating materials 12 are abutted mutually in a plurality of the tabular heat-insulating materials 12, and the heat-insulating materials 12 are disposed on the rear side of the surface material of an exterior wall bard material 16, etc. The end faces at the mutual side edges of the heat- insulating materials are formed in inclined planes capable of being mutually abutted and abutted at that time. The inclined planes 13 can be formed in mutually engaged irregular surfaces. Recessed venting grooves 15 may also be formed to one surfaces in the tabular heat-insulating materials 12.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat insulating structure for a building, and more particularly to a heat insulating structure provided on a building outer wall, a roof, a floor, etc., using a foamed material such as urethane foam as a heat insulating material. Regarding the structure.

[0002]

2. Description of the Related Art Conventionally, as a heat insulating structure on an outer wall of a general building constructed by, for example, a wooden frame method, a cotton-like material such as glass wool is packed between pillars or studs.
A heat insulating structure (hereinafter referred to as an internal heat insulating structure) covered with an outer wall material via a moisture-proof paper from above, and a plate-like foam material such as urethane foam is attached to the outside of the pillar or stud, and the moisture-proof paper is similarly applied from above. There is known a heat insulation structure (hereinafter, referred to as an external heat insulation structure) that is covered with an external wall material.

In the inner heat insulating structure, an inorganic fibrous cotton heat insulating material such as glass wool or rock wool, and sometimes a plate heat insulating material such as urethane foam are inserted and filled between columns and studs of the outer wall frame. Is the most widely adopted insulation method. In this inner heat insulating structure, an inner wall base material such as a gypsum board is fixed on the inner wall side with a heat insulating material therebetween, and a decorative outer wall material such as a siding material is fixed on a pillar or stud with a screw or the like on the outer wall side. Therefore, the heat insulating material is interrupted at the pillars and studs, and a so-called heat bridge is formed there. However, in a relatively warm region, a sufficient heat insulating method is adopted.

[0004] However, since high heat insulating properties are required in cold and hot regions, an external heat insulating structure that does not interrupt the heat insulating material at pillars and studs is required. FIG. 2 shows an example of a conventional external heat insulating structure. A plate-like heat insulating material 50 made of a foamed plastic board is attached to the outdoor side (upper side in FIG. 2) of the pillars 51 and the studs 52. It is pressed and fixed to the pillar 51 and the stud 52 with a nail 54 together with the body edge 53 while being held down by the body edge 53 described later. The decorative outer wall plate 55 is fixed to the pillar 51 or the stud 52 with a nail 56 from above the fixed body edge 53 and the heat insulating material 50 via these. The body edge 53 is interposed to form a ventilation space between the plate-shaped heat insulating material 50 and the decorative outer wall material 55 in order to prevent dew condensation, and has a thickness of 5 mm.
A ventilation path 57 having a depth of about 12 mm is often provided for a plate-like heat insulating material 50 of about 0 mm. Usually, the interval between the pillars 51 is often set at an integral multiple of 910 mm, and the studs 52 are inserted at a pitch of 455 mm between them, and the plate-shaped heat insulating material 50 is also rectangular in shape according to its dimensions. So that the joint is at the position of the pillar or stud. The plate-shaped heat insulating material 50 is joined by abutting the side edges cut off at right angles, and is joined between the joints via a moisture-proof sealing tape. Reference numeral 58
Is an interior base material such as a gypsum board.

[0005]

In the conventional heat insulating structure for a building as described above, the side edges cut off at right angles of the plate-shaped heat insulating material are connected to each other, so that the fixing by nailing is performed by a plate. It is necessary to perform this for each heat insulator. Therefore, nailing is required for each of the two plate-shaped heat insulating materials at the joint. At the seam, a seal tape for moisture prevention is stuck between the butt end faces, but when nailing, a large force at the moment of shock is applied to the plate-like heat insulating material, so the butt seam may open. In some cases, the moisture resistance is impaired even though the seal tape is attached, or the heat insulation is interrupted in spite of the external heat insulation structure.

[0006] In addition, as described above, the work of attaching the body edge to form the ventilation space involves complicated workability, which leads to a decrease in work efficiency.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned conventional technical problems, and secures a moisture-proof function by a sealing tape at a butt portion of a plate-like heat insulating material, and allows the adjacent plate-like heat insulating material to be used at one time. An object of the present invention is to provide an economical and high-performance heat insulating structure of a building which can be connected and fixed by nailing or screwing, and the joints thereof are hardly opened and the insulating material is not interrupted.

It is a further object of the present invention to provide a heat insulating structure for a building which can easily perform a ventilation method without using a spacer member such as a rim.

[0009]

SUMMARY OF THE INVENTION A heat insulating structure for a building by a wooden frame method according to the present invention has the following structure to solve the above-mentioned conventional technical problems and to achieve the above object. Have. That is, in a heat insulating structure of a building in which a plurality of plate-like heat insulating materials are abutted on end faces of side edges of the heat insulating material and arranged on the back side of the surface material at a construction target point, the side edges of the heat insulating materials are Are provided and abutted against each other with inclined surfaces that can abut each other.

[0010] The inclined surface can be formed by an uneven surface that meshes with each other.

Preferably, the plate-like heat insulating material has a concave ventilation groove formed on one surface thereof.

[0012]

FIG. 1 is a partial sectional plan view showing a heat insulating structure of a building according to a first embodiment of the present invention. This heat insulating structure is based on the external heat insulating structure of the outer wall, and a plate-like heat insulating material 12 is attached to a pillar 10 and a stud 11 in a wooden frame construction method with a nail or the like on a surface on the outer wall side. Plate heat insulating material 12,1
The two are joined together with their side edges abutting on each other, and the abutting end surface 13 is a 45-degree inclined surface.
This inclination angle can be applied at about 20 degrees to 70 degrees,
Although it depends on the material strength of the heat insulating material, if it is smaller than 20 degrees in general, the strength of the end portion of the plate-shaped heat insulating material becomes weak, and processing becomes difficult, resulting in a problem in productivity. On the other hand, if it is larger than 70 degrees, a sufficient contact area cannot be obtained, and a sufficient effect cannot be expected in terms of moistureproofness and airtightness. And it is particularly preferably in the range of 40 degrees to 60 degrees. The joint structure in which the inclined end faces 13 are joined to each other is advantageous in terms of moisture proofness or airtightness by forming a joint with a larger contact area than the conventional joint structure using right-angled end faces. In addition, since the adjacent heat insulating materials 12 and 12 are driven together by the nail 14 penetrating both at the overlapped portion to the column 10 or the stud 11, the contact surfaces of both are brought into a pressure contact state, and the heat insulating materials 12 and 12 are nailed. There is no separation between each other.

A sealing material, for example, a tape-shaped sealing material (not shown) is sandwiched between the inclined end surfaces. Thereby, the moisture-proof property and airtightness can be further improved. The sealing material is, for example, a double-sided adhesive tape, and one of the heat insulating materials 12 is used.
It may be attached to In this case, since the two heat insulating materials 12 and 12 to be abutted are temporarily fixed, the nailing operation can be performed efficiently. Note that this sealing material may be omitted if the airtightness and moistureproofness between the inclined end surfaces are sufficient.

The dimensions of the plate-like heat insulating material 12 are 455 mm wide according to the pitch between the columns 10 or the studs 11, and the thickness is 30 to 50 mm. Also,
The plate-like heat insulating material 12 has a ventilation groove 15 having a width of 255 mm and a depth of about 10 mm formed at the center in the width direction. Since the ventilation groove 15 is formed in the heat insulating material itself,
Conventionally, a ventilation space was provided by attaching a spacer member such as a rim, but a ventilation space can be taken without performing such a work of attaching a spacer member, which is advantageous in terms of both materials and construction man-hours. .

Note that the plate-like heat insulating material 12 is made up of the pillar 10 and the stud 11.
In this state, the heat insulating material 12 is applied to both the indoor side (lower side in FIG. 1) and the outdoor side (upper side in FIG. 1) of the heat insulating material 12, and the moisture-proof sheet material ( (Not shown). For these moisture-proof sheets, a polyethylene film or a perforated polyethylene film on which aluminum is deposited is used,
These may be pasted on both surfaces of the plate-shaped heat insulating material 12 in advance. In addition, the code | symbol 17 in a figure has shown the interior base material, such as a gypsum board.

The inclined end face does not need to be flat,
For example, the inclined end surface may be constituted by a corrugated uneven surface or a jagged uneven surface such as meshing with each other, in which case the connectivity between the butted end surfaces is further strengthened, and the moistureproofness or airtightness is further improved Enhanced.

In the above-described embodiment, the heat insulation structure applied to the outer wall has been described. However, in a building, heat insulation is generally applied to the roof and floor, and the back surface of the surface material at such a location is also provided. The same structure can be applied to the plate-like heat insulating material provided on the side.

[0018]

According to the heat insulation structure for a building according to the present invention,
For example, since the butted ends of the plate-shaped heat insulating material attached to a pillar or a stud by nailing are constituted by slanted butted end faces, these slanted end faces have a larger contact area than conventional right-angled end faces. It can have high moisture resistance or airtightness, and when nailing, it will be in a state of overlapping each other and will be nailed in a pressed state, so that continuous heat insulation can be ensured, and conventionally, each plate-shaped heat insulating material The nailing is advantageous in nailing workability because it can be fixed by nailing once with the adjacent ends overlapping.

Further, by forming the inclined end face with an uneven surface, it is possible to obtain higher bonding property, moisture-proof property and airtightness.

By forming a concave ventilation groove on one surface of the plate-like heat insulating material, a ventilation space can be provided without using a spacer member such as a rim, and is suitable for severe climatic conditions in a cold region or a hot region. It is possible to easily apply the ventilation method.

[Brief description of the drawings]

FIG. 1 is a partial cross-sectional plan view showing a heat insulating structure of a building according to the present invention.

FIG. 2 is a partial cross-sectional plan view showing a heat insulating structure of a building according to the related art.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Pillar 11 Stud 12 Plate-shaped heat insulating material 13 Butt end face at the side edge of heat insulating material 14 Nail 15 Vent groove 16 Exterior wall material 17 Interior base material

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification code FI E04B 2/56 644 E04B 2/56 644B 645 645B

Claims (5)

[Claims] 1. A building in which a plurality of plate-like heat insulating materials (12) are abutted against end surfaces (13) of side edges of the heat insulating materials and disposed on the back side of a surface material (16) at a location to be constructed. The heat insulating structure according to any one of claims 1 to 3, wherein end surfaces of side edges of the heat insulating materials are provided and abutted to each other with inclined surfaces that can contact each other. 2. The heat insulating structure according to claim 1, wherein the inclined surface of the end surface (13) of the side edge is formed by an uneven surface that meshes with each other. 3. The heat insulating structure according to claim 1, wherein the angle of inclination of the inclined end surface of the side edge is in a range of 20 to 70 degrees. 4. The heat insulating structure according to claim 1, wherein a tape-shaped sealing material is previously attached to the end surface (13) of the side edge. 5. The heat insulating structure according to claim 1, wherein the plate-like heat insulating material has a concave ventilation groove formed on one surface thereof.