JPH02108747A - Heat insulating structure for building made of steel frame - Google Patents

Abstract

PURPOSE:To prevent formation of dew by a method wherein an airtight layer having a heat insulating layer is continuously formed throughout the whole of a building body. CONSTITUTION:An airtight plywood 11 on which damp proof paint is applied is laminated to an outdoor side B of a framework material 7 throughout the whole of a wall part. A heat insulating material 13 formed through extrusion of foamed polyethylene is laminated to the whole of the outer surface of the airtight polywood 11 to form an airtight layer A', and the lower end of the heat insulating material 13 is continued to a heat insulating material 3 disposed at continuous footing 1. An air gap part is formed at the outside of the airtight layer A' to form a ventilation layer 15, and siding 16 with which an outer wall surface is formed is laminated to the outside of the ventilation layer 15 to form a wall body part 6.

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Application Field) The present invention relates to a heat insulating structure in steel frame buildings such as houses.

(Prior art) Conventionally, in steel-framed houses, a heat insulating layer such as a heat insulating material 12 is formed on the indoor side A of a steel frame, which is basically made of frame members 7, etc., as shown in Fig. 8. It had a so-called internal insulation structure.

(Problems to be Solved by the Invention) However, in conventional structures in which a heat insulating layer is formed on the inside, the steel frame is cooled by the outside air, and when warm, humid air comes into contact with it, condensation immediately occurs. Moreover, the heat-insulating airtight layer has problems such as the presence of many break points in small places, such as partitions, pillars, joints, and holes in the inner wall caused by equipment. In reality, condensation was prevented in various parts by increasing the amount of ventilation in the attic, under the floor, and in the walls, but this resulted in many problems, such as a large amount of indoor heat being lost due to ventilation. Ta.

The present invention was developed in view of the above circumstances, and an object of the present invention is to provide a heat insulating structure that has excellent heat insulating effects and does not cause dew condensation.

(Means for Solving the Problems) In order to achieve the above object, in this invention, an airtight layer having heat insulating properties is continuously formed over the entire building frame, and the airtight layer is formed on the steel frame frame. It is installed on the outside. Furthermore, the heat insulating material is attached to the outside of the airtight plywood, and the seams of the airtight plywood are interposed with airtight tape, and the heat insulating material is attached to the airtight plywood using nails coated with synthetic resin. It is said that

(Example) A description will be given below based on the illustrated embodiment.

Figure 1 is a partial longitudinal cross-sectional view of a steel-framed house, and ■ indicates a cloth foundation. This cloth foundation 1 is sandwiched between foundation concrete 2 over its entire rising portion, and a heat insulating material 3 made of extruded polystyrene foam is disposed in the vertical direction from the lower part to the upper end surface. The interior surrounded by the cloth foundation 1 is filled with soil, and on the top surface of this soil, a concrete floor 4 is poured over the entire floor surface, continuing from the upper end of the inside of the cloth foundation 1.
A flooring material 5 is pasted on the upper surface of this concrete floor 4.

A wall portion 6 is formed from the upper end surface of the cloth foundation 1. A frame member 7 made of shaped steel is vertically erected on this wall portion 6, forming the steel frame of the first floor, and an H-shaped steel frame member 7 is installed horizontally at the upper end of the first floor frame member 7. A floor beam 8 is erected, and frame members 7 are vertically erected further above the floor beam 8 to form the steel frame of the second floor, and H-beams are installed horizontally at the upper end. The roof beams 9 are installed. A shed IJIIO is formed on the top of the shed beam 8.

In the wall portion 6, as shown in FIG. 2, an airtight plywood board 11 is attached to cover the entire wall portion in contact with the outdoor side surface B of the frame member 7. And the joint part between the airtight plywood is the third
As shown in the figure, a butyl-based airtight tape 12 is interposed between the airtight plywood 11 and the frame member 7.

A heat insulating material 13 made of extruded polystyrene foam is further attached to the entire outer surface of the airtight plywood 11, and the lower end of this heat insulating material 13 is continuous with the heat insulating material 3 disposed on the cloth foundation 1.

The heat insulating material 13 is fixed to the building frame using nails 1 shown in Figures 4 and 5.
According to 4. This nail 14 has a washer 14 attached to the iron round nail 14a.
b is fixed, and the area from the fixed part 14c to the back surface of the head washer 14b is covered with a synthetic resin 14d such as soft vinyl chloride, except for the tip of the fixed part 14c. Then, the nails 14 are driven through the airtight plywood 11 from the outer surface of the heat insulating material 13 and up to the frame member 7, thereby fixing the heat insulating material 13. Then, an airtight layer A made of airtight plywood 11 and heat insulating material 13 is formed over the entire wall portion on the outer side of the steel frame formed from the frame material 7 and the like.

A void part is formed in the outer part of the airtight layer A to a required thickness, and this void part is used as the ventilation layer 15. Furthermore, siding 1. which forms an outer wall surface on the outside of this ventilation layer 15.
6 is attached to form the wall portion 6.

Furthermore, a gypsum board is pasted on the inner surface of the framework member 7 as a base material 17 for the inner wall.

FIG. 5 is a longitudinal cross-sectional view of a balcony 18 provided on the second floor. In this palconi 18 portion, a beam 19 made of H-beam steel is installed horizontally at the upper end of the frame member 7 forming the wall portion 6. Iron joists 2 are placed at regular intervals on this beam 19.
0 is constructed, and an airtight plywood 11 is pasted on top of it through iron joists 20, and a heat insulating material 13 is pasted over the entire upper surface of this airtight plywood 11. The airtight plywood 11 is continuous with the heat insulating material 13 attached to the wall portion 6 and the airtight plywood 11, respectively.

Furthermore, a T-shaped arm 20 for attaching external accessories as shown in FIG. 6 is attached to the outer end of the beam 19 in the balcony part 18. Resin 21 (thickness 5nun in the example)
). A handrail frame 22 is vertically fastened to the armrest 20 with bolts 23.

As shown in FIG. 7, in the roof frame 10 part, a foundation 24 is attached along the upper surface of the upper flange 9a of the roof beam 9 made of H-beam steel, and the upper surface of this upper platform 24 has an inclined surface corresponding to the roof slope. The flange 9a is fixed with bolts so as to sandwich the flange 9a with the lower stand 25 disposed on the back surface of the upper flange 9a. The top surface of the base 24 is covered with airtight plywood 1.
1 is pasted over the entire hut Mi10, a heat insulating material 13 is pasted on the surface of this airtight plywood 11, and wooden rafters 26 are erected.
Field plywood 27 is pasted on the surface of field plywood 27.
A roofing material (not shown) is laid on the surface of the roof. The airtight plywood 11 attached to this roof frame part 10 is attached to the base 24.
The airtight plywood 11, 11 of the wall portion 6 is in contact with the airtight plywood 11, and each airtight plywood 11, 11 is continuous with the base 24 with the airtight tape 12 affixed therebetween. Similarly, the heat insulating material 13 is continuous with the heat insulating material 11 of the wall portion 6 at the base 24 portion.

(Effects of the Invention) As described above, this invention continuously forms an airtight layer made of airtight plywood and heat insulating material over the entire building frame, resulting in high airtightness, low heat loss, and insulation. Everything inside the material has heat capacity and works to stabilize the room temperature.

By forming an airtight layer on the outside of the steel frame, the steel frame is not cooled by cold air, so there is no risk of heat bridges or condensation, which are the thermal weaknesses of steel structures, and a larger heat capacity can be obtained. . In addition, since the airtight layer is only on the outer peripheral surface of the building frame, it can be easily constructed.
High airtightness is possible, and since the steel frame is not exposed to outside air, the conditions are the same as indoors, and there is no risk of corrosion or rust, resulting in excellent durability.

In addition, by providing high heat insulation and high airtightness, the number of members that make up the wall increases, greatly improving sound insulation performance.

Furthermore, since the nails that fix the heat insulating material to the building frame are coated with synthetic resin, the nails are blocked from cold and hot air from the outside, so there is no risk of heat bridge condensation from the nails.

Furthermore, the surface of the arms used to attach external accessories such as handrail frames in the balcony area is coated with synthetic resin, which blocks cold and hot air from outside, resulting in damage from heat bridges and condensation from the balcony area. In addition, the coated parts are not exposed to the outside air, so rust and corrosion can be prevented.

[Brief explanation of drawings]

Figure 1 is a vertical cross-sectional view of an example part of a building frame, Figure 2 is an exploded perspective view of a wall part, Figure 3 is a cross-sectional view thereof, and Figure 4
Figure 5 is a perspective view of nails for fixing the insulation material, Figure 5 is a vertical sectional view of the foundation, outer wall, and part of the balcony showing how the nails are fixed and the brackets are fixed. Figure 6 is a perspective view of the brackets. The figure is a partial vertical sectional view of the roof frame, and FIG. 8 is a perspective view showing the wall portion of a conventional example. l...Cloth foundation, 2...Foundation concrete, 3...
Insulation material, 4...Earth floor concrete, 5...Flooring material, 6
...Wall part, 7. Frame material, 8. Floor beam, 9.
...Shed beam, 10 ... Shelf frame, 11 ... Airtight plywood,
12...Airtight tape, 13...Insulating material, 14...
Nail, 15... Ventilation layer, 16... Siding, 17
...Inner wall base material, 18...Balcony 19...
・Beam, 20... Bracelet, 21... Synthetic resin, 22...
・Handrail frame, 23...Bolt, 24...Foundation,
25...Lower stand, 26...Rafts, A...Airtight layer. Figure 3 Garden Figure 7 Figure 8I1

Claims (5)

[Claims] (1) A heat insulating structure for a steel frame building, characterized in that an airtight layer having heat insulating properties is continuously formed over the entire building frame. (2) A heat insulating structure in a steel frame building according to claim 1, wherein the airtight layer is provided outside the steel frame. (3) A heat insulating structure in a steel frame building according to claim 2, wherein the airtight layer is formed by pasting a heat insulating material on the outside of the airtight plywood. (4) A heat insulating structure for a steel frame building according to claim 3, wherein an airtight tape is interposed between the joints of the airtight plywood. (5) The heat insulating structure for a building according to claim 3 or 4, wherein the heat insulating material is fixed to the airtight plywood by nails coated with synthetic resin from the head to the back attachment part.