JPH0249835A - Heat insulative construction panel and method for installation - Google Patents

Abstract

PURPOSE:To simplify execution of panel installation and enhance the heat insulating performance by fitting a front surface member with a rear surface member consisting of hard material producing plastic deformation at normal temp., and providing the rear surface member at its external surface with a plurality of ridges partitioning the ridges at the periphery up and down. CONSTITUTION:A rear surface member 12 consisting of a hard material producing plastic deformation at normal temp. is installed at a front surface member 11 consisting of gypsum board, plyboard, insulation board, metal plate, etc. A plurality of ridges 12c partitioning ridges 12b at the periphery up and down is formed at the external surface of the rear surface member 12. The profile of each ridge 12c reduces thickness from the base toward the tip, and adhesives 13 is coated at the tip in the form of globe edge. Accordingly the ridges 12b, 12c absorb discontinuity of a concrete wall 1 to facilitate execution of panel installation, and provision of a number of voids by these ridges 12b, 12c accomplishes a heat insulating wall hard to produce convection.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to an architectural heat insulating panel for use in the interior of a concrete building and to be attached to the wall surface of the building with an adhesive, and a method for constructing the same.

(Prior Art) The exposed walls of concrete buildings have many irregularities and high surface roughness. Various methods are known for attaching heat insulating panels to such walls. In the Dango pasting method shown in Fig. 4, a large number of Dango-shaped lumps 2 of adhesive are arranged in a matrix pattern on the surface of the concrete wall 1, and a heat insulating panel 3 is pressed on top of them.
The adhesive mass 2 absorbs the irregularities in the wall 1.

In the heat insulating panel 3, 3a is a fireproof board made of gypsum, and 3b is a heat insulating board made of a foam such as hard polyurethane. In addition, in the direct attachment method shown in Fig. 5, mortar 4 is applied to the rough surface of the concrete wall 1 to make the surface smooth, and the insulation panel 3 is adhered thereon via a thin adhesive layer. . It is also known that the insulation panel 3 is fixed to the wall 1 by standing the insulation panel 3 vertically slightly in front of the wall 1 and pouring fresh concrete into the gap between the wall 1 and the insulation panel 3 and hardening it. ing.

(Problem to be Solved by the Invention) The Dango pasting method shown in FIG. It does not require any troublesome work to make the concrete wall 1 and the insulation panel 3.
A heat insulating space is formed between the two, but since this space is not divided into small parts and the entire back of the heat insulating panel 3 is in communication through the adhesive lumps 2, convection occurs and the heat insulating space is dew condensation occurs on the surface of the concrete wall 1, flows downward through the adhesive lumps 2, collects on the floor, flows out from the gap at the bottom, and dews on the floor of tatami mats, carpets, etc. There was a problem with getting the material wet.

In addition, in the direct pasting method shown in FIG. 5, the work of applying cement mortar to the concrete wall 1 and adjusting the unevenness is troublesome, requires skill, prolongs the construction period, and increases costs.
When repairing or replacing the insulation panels, the above finishing work was required again.

Furthermore, the method of pouring fresh concrete between the concrete wall 1 and the heat insulating panel 3 requires a large number of man-hours, increases costs, and has the problem that the heat insulating panel cannot be repaired or replaced at all.

This invention can be applied relatively easily without adjusting the unevenness of the concrete wall as in the conventional Dango pasting method, creates a heat insulating space between the wall and the concrete wall, and generates less convection. An object of the present invention is to provide a thermal insulation panel for construction that can confine generated dew condensation within a narrow enclosure, and a method for constructing the same.

(Means for Solving the Problems) In the architectural insulation panel of the present invention, the backing material is made of a hard material that undergoes plastic deformation at room temperature, and the backing material has protrusions surrounding the four circumferences on the outer surface thereof, and protrusions on the four circumferences. A large number of protrusions are formed that partition the inner side of the strip into upper and lower sections.

The method of constructing the above-mentioned architectural insulation panel is to apply adhesive in a bead shape to the tips of the protrusions on the back side of the above-mentioned architectural insulation panel, or to apply adhesive to at least the recessed part on the back side of the above-mentioned architectural insulation panel and to the building. A bump-shaped lump of adhesive is interposed between the panel and the wall, and this architectural insulation panel is pressed so that the ridges are in contact with the wall of the building, causing partial plastic deformation at the tips of the ridges. It is characterized by applying pressure to absorb unevenness.

The above-mentioned architectural insulation panels are made by laminating a surface material, an intermediate material, and a backing material in this order, or are made by laminating a facing material and a backing material. It is a plate material with a smooth surface such as a metal plate.

Further, as the intermediate material, a heat insulating material such as a foam made of polyurethane, phenol, polyisocyanurate, polystyrene, polyethylene, polypropylene, polyvinyl chloride, natural rubber, synthetic rubber, etc., cardboard, or glass wool is used.

When the intermediate material is omitted, a hard foam made of polyurethane or the like that undergoes plastic deformation at room temperature is used, and the protrusions are integrally formed by foam molding.

On the other hand, as a back material when using an intermediate material.

Hard plastics such as polyethylene, polystyrene, and polyvinyl chloride, and cardboard are used, and the above-mentioned ridges are formed by post-processing. The cross-sectional shape of the protrusion is arbitrary, but preferably has a cross-sectional shape that tapers from the base to the tip, such as a triangle, semicircle, semiellipse, or trapezoid. Also,
The above-mentioned protrusion may be either hollow or solid, and its preferred height is 5 to 50 cm, particularly 10 to 30 cm,
The vertical pitch of the protrusions in the width direction is preferably 20 to 400 m, and these heights and pitches are appropriately set depending on the material of the backing material. In addition, the longitudinal protrusions can be provided in the center as well as on both side edges to form a lattice shape.

When constructing the above architectural insulation panels, the adhesives applied to the ends of the protrusions include gypsum bond, rubber adhesive, urea resin adhesive, melamine resin adhesive, phenolic resin adhesive, polyester resin adhesive, epoxy resin adhesive, etc. It is a drug. The preferred coating amount (solid dosage) is 5 to 100 g per 1 m of the length of the ridge. Note that a double-sided adhesive tape may be used in place of the above-mentioned application, or a Dango pasting method may be used in combination.

(Function) When the architectural heat insulating panel of the present invention is strongly pressed and adhered to a concrete wall surface, the protrusions of the backing material deform according to the unevenness of the concrete wall surface. In other words, the part of the above-mentioned ridge that touches the convex part of the concrete wall is compressed and undergoes plastic deformation, and the part that touches the concave part is bonded with almost no deformation, and the unevenness of the concrete wall causes the plastic deformation of the ridge. Absorbed by deformation. In other words, the back surface material has such hardness and brittleness that plastic deformation occurs in the protrusions during such construction work.

However, due to the construction of the above-mentioned thermal insulation panel for construction, a large number of small spaces are formed independently between the above-mentioned panel and the concrete wall, partitioned vertically by the above-mentioned ridges, and convection may occur. In addition to creating a heat-insulated space,
Contains condensation formed on the concrete wall within the small space.

(Example) In FIGS. 1 and 2, 11 is a surface material made of gypsum board, and 12 is a back material made of hard polyurethane.
Vertical ridges 12b with a triangular cross section along the left and right edges of a, and a large number of horizontal ridges 12 with a triangular cross section connecting the left and right vertical ridges 12b, 12b from the upper end to the lower end at equal intervals.
It is equipped with c.

In the above structure, a gypsum board with a thickness of 9 mm is used as the surface material 11, and as the back material 12, the thickness of the plate-shaped portion 12a is 10 cm, the height of the protrusions 12b and 12c is 15 m5, the tip angle is 60 degrees, and the horizontal A hard polyurethane foam molded product with a Loom pitch is used for the protrusions 12c, and gypsum bond is used as the adhesive 13 (see Figure 2), and the above protrusions 12b, 1
2c at a rate of 60 g per Im, and this heat insulation panel was pressed against the concrete wall 1 with a pressure of 0.5 kg/cj, and good unevenness absorption was obtained by plastic deformation of the ridges 12b and 12c.

In the embodiment shown in FIG. 3, a heat insulating intermediate material 15 made of hard polyurethane with a thickness of 15 m is laminated on the surface material 11 similar to the above, and a polyethylene sheet with a thickness of 1.0 m is press-molded on the back side. The back material 16 is formed by forming a hollow protrusion 16a with a length of 15 m.

(Effects of the Invention) The invention as claimed in claim 1 is characterized in that the four circumferences of the backing material made of a material that undergoes plastic deformation at room temperature and the four circumferences of the four circumferences are formed with protrusions so as to partition the four circumferences into upper and lower sections. By carrying out the construction according to the method according to claim 3 or 4, the ridges absorb the unevenness of the concrete wall and the heat insulating panel is bonded, eliminating the need for troublesome unevenness adjustment work. Moreover,
After construction, a large number of vertically partitioned small spaces will be formed between the insulation panel and the concrete wall.
A heat insulating wall is constructed that does not easily generate convection, and condensation is confined within the small space and does not seep out from the lower end of the panel. Further, when the cross-sectional shape of the protrusion is formed into a tapered shape as described in claim 2, the shaping and construction thereof become even easier. Furthermore, when the Dango pasting method is used as described in claim 4, the adhesive force increases, so that the panel can be reliably fixed even when the panel is heavy and when there are few ridges.

[Brief explanation of the drawing]

Fig. 1 is a perspective view of a heat insulating panel of the present invention, Fig. 2 is a longitudinal cross-sectional view of the heat insulating panel during construction, Fig. 3 is a longitudinal cross-sectional view of another embodiment, and Figs. 4 and 5 are conventional FIG. 2 is a cross-sectional view illustrating a construction method. 1: Concrete wall, 11: Surface material, 12, 16: Back material. 12b, 12c, 15: Intermediate material. 16a: protrusion,

Claims (1)

[Scope of Claims] [1] The backing material is made of a hard material that undergoes plastic deformation at room temperature, and the outer surface of the backing material has ridges surrounding the four circumferences thereof and a number of ridges dividing the inside of the four periphery ridges into upper and lower parts. A thermal insulation panel for construction, characterized in that each of these ridges is formed. [2] The thermal insulation panel for construction according to claim 1, wherein the cross-sectional shape of the protrusion is tapered from the base to the tip. [3] Adhesive is applied in a bead shape to the tips of the protrusions on the back side of the architectural heat insulating panel according to claim 1 or 2, and this architectural heat insulating panel is made such that the protrusions touch the wall of the building. A method of constructing a heat insulating panel for construction, characterized in that the unevenness is absorbed by applying pressure so that partial plastic deformation occurs at the tips of the protrusions. [4] A lump-shaped lump of adhesive is interposed between at least the concave portion of the back surface of the architectural insulation panel according to claim 1 or 2 and the wall of the building, and the construction insulation panel is
A method of constructing a heat insulating panel for construction, characterized in that the protrusions are pressed against the wall of a building, and pressure is applied so that partial plastic deformation occurs at the tips of the protrusions to absorb unevenness.