JP2006348618A - Thermal insulating material and its application method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a thermal insulating material having a waterproofing effect and adhesion property. <P>SOLUTION: The thermal insulating material exhibits a thermal insulating effect, the waterproofing effect and a heat insolation effect by applying a thermal insulating material obtained by mixing a hollow bead such as a ceramic bead, a fly-ash and a plastic bead or the like with an acrylic resin or the like as a binder on an external wall such as a building or the like, and it can be used as an adhesive. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a heat insulating material having a waterproof effect and an adhesive effect.

  Conventionally, heat insulating materials have been used for building roofs, outer walls, interiors, and other structures (for example, Patent Document 1, Patent Document 2, and Patent Document 3). By using a heat insulating material for the outer wall or the like, heat transfer between the inside and outside of the outer wall can be limited.

  FIG. 2 is a diagram for explaining heat insulation of a conventional building wall. FIG. 2A shows the state of internal heat insulation. The indoor side wall surface is an interior base 10, and a heat insulating material 15 is provided inside thereof. Concrete (ALC) 14 or the like is provided on the outdoor side wall surface, and tiles 12 are attached to the concrete (ALC) 14 wall surface with mortar or tile adhesive 11. Further, a waterproof sheet is provided between the heat insulating material 15 and the concrete 14.

FIG.2 (b) shows the state of external heat insulation. In this case, a heat insulating material 15 is provided on the outdoor side of the concrete (ALC) 14. Further, the tile base panel 20 is supported by the anchor 21 on the outdoor side of the heat insulating material, and the tile 12 is attached to the tile base panel 20 with the mortar or the tile adhesive 11. A waterproof sheet is provided between the heat insulating material 15 and the concrete 14.
JP 2004-25791 A JP 2005-89579 A Japanese Patent Laid-Open No. 11-80599

  As described above, the waterproof sheet 13, the adhesive 11, and the heat insulating material 15 are necessary regardless of whether the heat insulation is internal heat insulation or external heat insulation, and the cost is high, the construction period is long, and the environment is highly loaded. there were.

  In view of the above problems, the present invention provides a simple and inexpensive heat insulating material and a coating method thereof.

  The present invention is configured by mixing hollow beads and an acrylic resin. The hollow beads are ceramic beads, fly ash, or plastic beads, and the acrylic resin is a styrene acrylic acid alkyl ester copolymer emulsion.

  Furthermore, this invention can exhibit the heat insulation effect, the waterproof effect, and the heat-shielding effect by apply | coating said heat insulating material to the outer wall of a building. Furthermore, the present invention further functions as an adhesive by applying the above-described heat insulating material to the outer wall of the building and then sticking a predetermined building member on the applied heat insulating material.

  By using the heat insulating material of the present invention, it is possible to easily and inexpensively perform heat insulating treatment that also serves as waterproof treatment on the outer wall or the like. It also functions as an adhesive. Therefore, it can be used in applications such as heat insulation, heat insulation, aesthetics, sound insulation, prevention of dew condensation, mold prevention, crack repair, and semi-waterproofing.

  The present invention is a generic term for solid particulate matter contained in combustion waste gas, such as ceramic beads and fly ash (soot, ash, etc .. Dust collection ash and boiler, gas cooling chamber, and recombustion chamber. It is a heat insulating material obtained by mixing hollow beads such as plastic beads and acrylic resin as a binder (binding material).

The heat insulating material according to the present invention can achieve waterproof and heat insulation on the roof at the same time by integrating the waterproof effect and the heat insulating effect. As a result, the construction is simplified, leading to cost reduction, and as a result, reducing CO _{2 in} the global environment.

In addition, by using the heat insulating material according to the present invention, when the material having a heat insulating effect and the adhesive are integrated in the tile sticking / stone sticking in the building, the tile / stone sticking is performed at the same time as the external heat insulation. The outer wall is made. This simplifies construction and leads to cost reduction, and as a result, reduces CO _{2 in} the global environment.

  FIG. 1 shows a state in which a heat insulating material according to the present invention is used for an outer wall. The heat insulating material 1 is a composition having three roles, which is a heat insulating material and also a waterproof material and an adhesive. In other words, the heat insulating material 1 according to the present invention can be applied as an adhesive to the outer wall side surface of the concrete (ALC) 14 and the tile 12 can be attached. As a result, since the heat insulating material 1 exists at the boundary between the outer wall side and the inner wall side, a heat insulating effect and a waterproof effect are exhibited.

  Therefore, since it is not necessary to provide the waterproof sheet 13, the adhesive 11, and the heat insulating material 15 described in FIG. 2 separately and independently, space saving, low cost, and a short construction period can be achieved.

<The manufacturing method of the heat insulating material concerning this invention>
The components shown in Table 1 were mixed and stirred until uniform. At this time, in order to facilitate stirring, depending on circumstances, stirring may be performed at a predetermined temperature by heating.

  In Table 1, a styrene acrylic acid alkyl ester copolymer emulsion was used as the styrene acrylic ester polymer. Further, as the inorganic compound, micro ceramic beads (manufactured by Kyumak Co., Ltd.) or expand cell micro sphere (vinyl chloride compound) were used. The expander microsphere can be changed in diameter in the range of, for example, about 20 to about 50 μm depending on the heating temperature.

  Thus, the heat insulating material concerning this invention can be obtained.

  In this example, the solar reflectance was determined for the coating film of the heat insulating material (hereinafter referred to as sample S) manufactured in Example 1. The obtained solar reflectance is shown in Table 2.

  Accordingly, in the film of the sample S having a thickness of 0.6 mm, a difference was observed in the reflectance between the white ground and the black ground of the concealment rate test paper particularly in the near infrared region. That is, the reflectance on the black ground is reduced. This means that the light in the near infrared region is transmitted when the film thickness of the sample S is 0.6 mm, and is absorbed by the black background.

  In this example, the thermal conductivity of the coating film of sample S is measured to confirm the degree of the heat shielding effect. Table 3 shows the measurement results of the thermal conductivity of Sample S.

  The thermal conductivity of “Stucco” is “0.6”, the thermal conductivity is “Gypsum plaster” is “0.5”, and the thermal conductivity is “Gypsum board” is “0.71-0.1” On the other hand, the sample S is “0.121 (Kcal / h · m · ° C.)” from Table 3. Therefore, it can be said that this sample S is a coating material of a relatively low thermal conductivity.

  The adhesive strength of sample S to galvanized copper plate and concrete plate was evaluated. The results are shown in Table 4.

Then, the adhesive strength of the sample S vs. steel 1.7 N / mm ^2, a pair of concrete 1.5N / mm ² (JIS standard is 0.5 N / mm ² or higher). Therefore, this sample S has an adhesive strength that sufficiently satisfies the JIS standard.

<Effects of Examples 2, 3, and 4>
From Examples 1 and 2, the effectiveness of the heat insulating effect of the heat insulating material according to the present invention could be confirmed. Moreover, the heat conductivity of the said heat insulating material is 0.12 (Kcal / hm degreeC) (when the coating film is 0.6 mm). On the other hand, the thermal conductivity of concrete is 1.40, the thermal conductivity of gypsum is 0.5, and the thermal conductivity of thermal insulation bricks is 0.12.

The adhesive strength of the insulation, versus steel 1.7 N / mm ^2, a pair of concrete 1.5N / mm ² (JIS standard is 0.5 N / mm ² or higher). Moreover, the sunlight reflection degree of the said heat insulating material is 90% or more, 90% or more of sunlight containing an ultraviolet-ray is reflected, and deterioration of structures, such as a building, can be prevented.

  This heat insulating material also has the following effects. Since the heat insulating material has excellent elasticity, it is finished in a wall that is more resistant to shock and vibration, which is harder to crack. Moreover, it can counteract any obstacle that deteriorates the coating film, and can exhibit outstanding durability.

  Moreover, when the heat insulating material is applied to the wall by a thickness of 0.9 mm, the sound passing through the roof, ceiling, and wall is reduced by about 10 decibels, and a quiet environment can be secured. Moreover, the said heat insulating material is environmentally friendly water-soluble, and does not contain the causative substance of sick house syndrome. Moreover, the coating film of the said heat insulating material can form the coating film of 3 layers-4 layers (0.6 mm-0.9 mm), and can prevent the penetration | invasion of water.

  In addition, it has a wide range of painting suitability for concrete, iron, iron plate, wood, etc. It can also handle a wide range of paint designs such as brush rollers, spraying, and wrinkles. Moreover, in addition to a wide range of coating suitability such as concrete, it can exhibit excellent adhesion to old paint films such as repainting of color tones, oiliness, acrylics and urethanes. The said heat insulating material can be used for uses, such as heat insulation, heat insulation, aesthetics, sound insulation, dew condensation prevention, mold prevention, crack repair, semi-waterproofness.

  The target of construction of the insulation is, for example, the exterior and interior of the roofs of large buildings such as factories, general warehouses, cold storage warehouses, laboratories, schools, meeting places, gymnasiums, frozen containers, dry containers, cold cars, grains Silos, frozen / refrigerated warehouses, storage tanks, livestock buildings, interior / exterior of vehicles, plant piping (LP gas / steam), iron, concrete, foamed concrete, wood, tile, slate, siding, brick, tile, aluminum, It may be stainless steel, block, gypsum board or the like. It can also be used as a paint by mixing pigments of various colors.

A mode that the heat insulating material concerning this invention was used for the outer wall is shown. It is a figure explaining the heat insulation of the wall of the conventional building.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Heat insulating material 10 Interior base material 11 Adhesive for mortar or tile 12 Tile 13 Waterproof sheet 14 Concrete (ALC)
15 Insulation

Claims (4)

  A heat insulating material comprising a mixture of hollow beads and acrylic resin. The hollow beads are ceramic beads, fly ash, or plastic beads,
The heat insulating material according to claim 1, wherein the acrylic resin is a styrene acrylic acid alkyl ester copolymer emulsion.   The construction method using the heat insulating material which apply | coats the heat insulating material of Claim 1 to the outer wall of a building as a waterproofing material. A method for bonding a heat insulating material, comprising: applying a heat insulating material according to claim 1 to an outer wall of a building; and attaching a predetermined building member on the applied heat insulating material.

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