KR200324567Y1 - Heat insulating board for building - Google Patents

Abstract

The present invention relates to a thermal insulation board for building, in particular, the base sheet is installed on the wall surface of the building, and a plurality of micropores are formed, the aluminum pearl layer formed by coating the aluminum particles on the base sheet with a uniform thickness, and the aluminum An air layer forming sheet for forming an air layer by each of the air chambers comprising a sheet portion attached to the upper side of the pearl layer and a plurality of cell portions that are formed at intervals on the sheet portion and formed in a tubular shape to form an air chamber therein, wherein the air layer is formed. Since it is composed of aluminum foil attached to the upper side of the sheet to seal the air chamber, it is possible to maximize the thermal insulation effect by the combined action of the air layer and aluminum, and to increase the soundproof and dustproof effect by canceling the noise and vibration of the air layer. Moisture-proof and flame-retardant, excellent moisture-proof effect Modification also relates to building insulation board can be minimized.

Description

Heat insulating board for building}

The present invention relates to a thermal insulation board for building, and more specifically, by forming an air layer inside and covering the upper and lower sides with aluminum, it provides a sound insulation, dustproof, and moisture proof effect as well as maximized insulation effect by the combined action of the air layer and aluminum. The present invention relates to a building insulation board.

In general, a wall for dividing the interior of the building into a number of spaces is installed with a heat insulating material to reduce the heat loss or heat inflow to the outside.

In this case, it is better to use a material with a small thermal conductivity of the material itself, but in most cases, it is not so. It is common to obtain an insulation effect by using an ideal insulation effect.

As such a heat insulating material, expanded poly-styrene (expanded polystyrene), which is widely used because it is not only cheap but easy to purchase, is a representative example.

However, foamed styrene reduces the thermal conductivity and exerts thermal insulation effect only by relying solely on the thermal insulation of air present in a plurality of micropores, so the effect is limited, which does not meet the general psychology of residents expecting higher thermal insulation effect. have.

In addition, foamed styrene does not sufficiently absorb vibrations and noises generated on the wall and does not effectively block moisture, and thus, it is not possible to provide a satisfactory dust, soundproofing, and moistureproof effect, thereby creating a more comfortable indoor environment. There is this.

Meanwhile, foamed styrene is vulnerable to fire, as it is widely known, and there is a problem that it is not only burned in a short time when a fire occurs, but also generates toxic gases harmful to the human body.

The present invention was devised to solve the problems of the prior art, and the air layer is formed inside, and the upper and lower sides of the air layer are composed of aluminum coated structures, thereby maximizing the insulation effect by the combined action of the air layer and aluminum. It is possible to increase the soundproofing and dustproofing effect by offsetting the noise and vibration of the air layer, and to provide the insulation board for building that is excellent in moistureproofing effect as well as minimizing thermal deformation by moistureproof and flame retardant property of aluminum. .

1 is a perspective view of a building insulation board according to the present invention,

Figure 2 is a partial cutaway perspective view showing a building insulation board according to the present invention,

3 is a cross-sectional view taken along the line "ga-ga" of FIG.

4 is an enlarged view of a portion “I” of FIG. 3;

Figure 5 is a state diagram showing the building insulation board according to the present invention.

<Explanation of symbols on main parts of the drawings>

10: basic sheet 11: fine pores

20: aluminum pearl layer 21: aluminum particles

30: air layer forming sheet 31: sheet portion

32: cell part 32 ': air chamber

40: aluminum foil 41: stopper

A: Air layer W: Wall surface

The present invention for achieving the above technical problem is the base sheet is installed on the wall surface of the building and a plurality of micropores are formed, the aluminum pearl layer formed by coating the aluminum particles on the base sheet with a uniform thickness, and the aluminum An air layer forming sheet for forming an air layer by each of the air chambers comprising a sheet portion attached to the upper side of the pearl layer and a plurality of cell portions that are formed at intervals on the sheet portion and formed in a tubular shape to form an air chamber therein, wherein the air layer is formed. It is possible to be characterized by consisting of an aluminum foil attached to the sheet upper side to seal the air chamber.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

Building insulation board according to the present invention is shown in Figures 1 to 5.

1 to 5, the building insulation board 1 of the present invention includes a base sheet 10, an aluminum pearl layer 20 covering the upper side of the base sheet 10, and the aluminum pearl layer. (20) It is composed of an air layer forming sheet (30) attached to the upper side to form an air layer (A), and an aluminum foil (40) attached to the upper side of the air layer forming sheet (30).

The base sheet 10 is formed in a rectangular shape and is firmly installed on the wall surface W by an adhesive or the like, and forms a myriad of fine pores 11 therein, and thus the outside of the base sheet 10 is insulated from the air in the fine pores 11. It is made of a flexible foam made of about 4mm thick by cross-linking polyethylene (polyethylene) and acrylic stock solution to block heat loss or heat entering the room (R).

At this time, the base sheet 10 may be achieved using a non-woven fabric (non-woven fabric) that can replace the foam.

The base sheet 10 also serves as a cushion for absorbing the impact applied to the present invention.

The aluminum pearl layer 20 is formed by coating aluminum particles 21 powdered with aluminum, which are known to be excellent in moisture resistance, corrosion resistance, and flame resistance, with a uniform thickness by applying an adhesive over the upper side of the base sheet 10. It is a plate-like layer that not only blocks moisture but also reflects and blocks heat by its own heat reflection.

The air layer forming sheet 30 includes a sheet portion 31 attached with an adhesive throughout the upper side of the aluminum pearl layer 10, and a plurality of cell portions standing at close intervals above the sheet portion 31. It consists of 32.

Here, each cell portion 32 is formed in a pipe shape having a height of about 2 mm so that an air chamber 32 'may be formed therein, and the aluminum pearl layer 20 and the aluminum foil (20) are formed by each air chamber 32'. 40) forms an air layer A having a thickness of about 2 mm that blocks heat and of course cancels noise and vibration.

In this case, the cell part 32 is illustrated in a cylindrical shape, but may be formed in a polygonal shape such as square or hexagon.

Meanwhile, the cell part 32 supports the aluminum foil 40 to protect the air layer A from the pressure applied to the air layer A from the outside. For example, the cell part 32 has a large volume of the air chamber 32 '. If 32 is formed, the aluminum foil 40 cannot be sufficiently supported, and the size thereof should be determined in consideration of this.

The air layer forming sheet 30 is made of polyvinyl chloride.

The aluminum foil 40 is also made of the same aluminum as the aluminum pearl layer 20, and is made of a thin strip using a rolling roll, which is rolled and rolled.

The aluminum foil 40 seals the upper side of the cell portion 32 of the air layer forming sheet 30 and prevents loss of air in the air chamber 32 '.

In other words, the convection of the air is suppressed to obtain an ideal heat insulation effect by the heat insulation of the air layer (A).

On the other hand, the aluminum foil 40 is formed with a stopper 41 surrounding the upper end of each cell portion 32 to close the air chamber 32 'tightly.

Here, the stopper 41 is formed by recessing the aluminum foil 40 to match the shape of the cell part 32, whereby a pattern like the cell part 32 is formed on the surface of the aluminum foil 40.

Architectural insulation board (1) of the present invention is configured as described above can be installed between the wall (W) and gypsum board (B), the heat flowing into the interior (R) from the outside or vice versa is necessarily the base sheet 10, the aluminum pearl layer 20, the air layer (A) and the aluminum foil (40) must pass through the combined action of these to minimize the thermal conductivity.

And noise and vibration are deflected, absorbed and offset in the air layer (A) during the present invention, moisture is blocked by the aluminum pearl layer 20 and the aluminum foil 40.

On the other hand, Table 1 below is a test report showing the results of the test of the thermal conductivity of the subject innovation commissioned by the Korea Institute of Chemical Testing and Materials.

For reference, the sample provided by the applicant to the Korea Testing Institute is 6 mm thick as in this embodiment, and the following results are referred to as thermal conductivity exhibited by foamed styrene having a thickness of 70 mm.

Table 1

The present invention as described above (1) Maximize the blocking of heat introduced into the room from the outside or lost to the outside due to the complex thermal conduction action of the base sheet, aluminum pearl layer, air layer and aluminum foil each formed with a microporous hole (2) As the noise and vibration are absorbed and absorbed by the air layer, it is possible to increase the soundproofing and dustproofing effect. (3) The moisture resistance of the aluminum pearl layer and the aluminum foil is excellent, as well as the moisture-proofing effect and the flame retardancy of the aluminum foil. There is an advantage that can minimize the thermal deformation caused by the fire.

Therefore, the present design must be a very useful design with improved thermal properties as well as soundproofing, dustproofing and moisture proofing effect, as well as thermal deformation.

Claims (4)

A base sheet 10 installed on the wall surface W of the building and having a plurality of micropores 11 formed therein; An aluminum pearl layer (20) formed by coating aluminum particles (21) with a uniform thickness on the base sheet (10); The sheet portion 31 attached to the upper side of the aluminum pearl layer 20 and the plurality of cell portions 32 that are formed at intervals above the sheet portion 31 and formed in a tubular shape to form an air chamber 32 ′ therein. An air layer forming sheet 30 formed to form an air layer A by the air chambers 32 '; Building insulation board (1), characterized in that consisting of an aluminum foil (40) attached to the upper side of the air layer forming sheet (30) to seal the air chamber (32 '). The method of claim 1, The base sheet 10 is a building insulation board, characterized in that the foam cross-linked polyethylene and acrylic stock solution. The method of claim 1, The base sheet 10 is a building insulation board (1), characterized in that the non-woven fabric. The method of claim 1, The aluminum foil 40 is a building insulation board (1), characterized in that the plug portion 41 is formed so as to surround the upper end of each cell portion (32).