KR101313983B1 - Insulation material for building and the method thereof - Google Patents

Abstract

The present invention, the first insulation panel is formed of a rigid material, the second insulation panel is spaced apart to face the first insulation panel, the second insulation panel is formed of a rigid material to form a skeleton with the first insulation panel, A first groove pattern and a second interposed between the first insulation panel and the second insulation panel and forming an air layer on first and second surfaces facing the first insulation panel and the second insulation panel, respectively; Provided is a building insulation comprising an intermediate panel having a groove pattern formed thereon, and a radiant heat reflecting sheet inserted between the first surface and the first insulation panel or between the second surface and the second insulation panel.
Therefore, by the first insulation panel and the second insulation panel, the basic skeleton can be maintained to ensure rigidity and stability. Furthermore, since the air layer may be formed by the first groove pattern and the second groove pattern, the radiant heat reflected by the first radiant heat reflecting sheet and the second radiant heat reflecting sheet is dissipated to block the movement of radiant heat. do.

Description

Insulation material for building and method for manufacturing thereof

The present invention relates to a building heat insulating material and a method for manufacturing the same, and more particularly, to a building heat insulating material and a method for manufacturing the same, the overall rigidity, the thickness can be adjusted, the heat insulating performance is also improved.

In general, in order to block heat from the outside or to prevent the heat from being emitted inside, a heat insulating material is used on the inner wall and the outer wall. Styrofoam insulation of the plate-like among the heat insulating material is light, easy to handle and excellent heat insulation performance, but does not reflect the heat from the inside and outside, there is a disadvantage that can not block the loss of radiant heat.

In order to prevent such loss of radiant heat, reflective insulation has been actively developed recently. The reflective insulating material is generally provided in a roll type by bonding an aluminum foil to a nonwoven fabric or a foamed crosslinked sheet. As an example of the reflective insulating material, a hollow composite functional reflective thermal insulating material is disclosed in Korean Utility Model Model No. 2009-00088431.

However, the reflective heat insulating material has a high radiant heat reflectance, which is effective to block heat loss, and has a merit of being easy to be rolled and rolled. On the other hand, since the film is thin, the rigidity is very small and attached to a separate plate member. Since it must be used, there is a problem that is difficult to work. In addition, in the case of the reflective insulating material, it is generally used to cut, there is a problem that the non-woven fabric is broken when cutting, there is a disadvantage in difficult on-site work.

SUMMARY OF THE INVENTION An object of the present invention is to provide a building insulation and a method of manufacturing the same, which has a large rigidity, is capable of controlling thickness, and improves insulation performance.

The present invention, the first insulation panel is formed of a rigid material, the second insulation panel is spaced apart to face the first insulation panel, the second insulation panel is formed of a rigid material to form a skeleton with the first insulation panel, A first groove pattern and a second interposed between the first insulation panel and the second insulation panel and forming an air layer on first and second surfaces facing the first insulation panel and the second insulation panel, respectively; Provided is a building insulation comprising an intermediate panel having a groove pattern formed thereon, and a radiant heat reflecting sheet inserted between the first surface and the first insulation panel or between the second surface and the second insulation panel.

According to another aspect of the invention, the present invention, the step of attaching the first radiation sheet and the second radiation sheet reflecting sheet on one surface of the first insulation panel and the second insulation panel formed of a rigid material, and the upper and lower surfaces Preparing an intermediate panel having a first groove pattern and a second groove pattern, each of which forms an air layer, and formed of a rigid material; and wherein the first radiation heat reflecting sheet and the second radiation heat reflecting sheet are respectively It provides a method of manufacturing a building insulation comprising the step of heat-sealing the intermediate panel between the first insulation panel and the second insulation panel while facing the first groove pattern and the second groove pattern.

According to still another aspect of the present invention, the present invention is disposed spaced apart from each other in the vertical direction, a plurality of insulation panels formed of a rigid material to form a skeleton with each other, respectively inserted between the insulation panels, the upper surface And a first groove pattern and a second groove pattern, each of which forms an air layer on a lower surface thereof, between intermediate panels formed of a rigid material, at least one of upper and lower surfaces of each of the intermediate panels, and an insulating panel facing the lower panel. It provides a building insulation comprising a radiation heat reflecting sheet inserted in the.

Architectural insulation and its manufacturing method according to the invention has the following effects.

First, since the first insulation panel, the second insulation panel, and the insulation panel are formed of a rigid material, the basic skeleton can be maintained to ensure rigidity and stability.

Second, since the air layer can be formed by the first groove pattern and the second groove pattern respectively formed on both sides of the intermediate panel, the heat insulating performance is improved, and the reflected radiant heat is easily dissipated.

Third, the radiant heat is reflected by the first radiant heat reflecting sheet and the second radiant heat reflecting sheet, and the movement of radiant heat through the indoor and outdoor is blocked.

Fourth, since the thickness of the building insulation can be adjusted by adjusting the number of the insulation panel and the intermediate panel, the building insulation of various standards can be easily manufactured.

Fifth, since the first insulation panel (or the second insulation panel, the insulation panel) and the intermediate panel can be attached to each other by heat fusion, the manufacturing of the building insulation is facilitated.

1 is an exploded perspective view of a building insulation according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along the line II-II of FIG. 1.
3 is a cross-sectional view of the building insulation in accordance with another embodiment of the present invention.
4 is a perspective view of the first radiation heat reflecting sheet illustrated in FIG. 3.
5 is a cross-sectional view of the building insulation in accordance with another embodiment of the present invention.

1 and 2 show a building insulation 100 according to an embodiment of the present invention. 1 and 2, the building insulation material 100 includes a first insulation panel 110, a second insulation panel 120, an intermediate panel 130, a first radiation heat reflecting sheet 141, and a second radiation heat. Reflective sheet 142. The first insulation panel 110 and the second insulation panel 120 are spaced apart from each other in parallel in the vertical direction.

The first insulation panel 110 and the second insulation panel 120 have a rectangular plate shape, respectively, and have high rigidity such as expanded polystyrene (EPS), expanded polyurethane, expanded polypropylene (EPP), and the like. It is formed of a material having excellent heat insulating properties. Conventional reflective insulation is produced using polyester, which is used in the form of a flexible film because of its very small rigidity. Therefore, the conventional reflective heat insulating material has to be attached to a separate rigid member to be used, there is a disadvantage that the work is complicated.

The intermediate panel 130 is inserted between the first insulation panel 110 and the second insulation panel 120. The intermediate panel 130 is also formed of a material having high rigidity such as expanded polystyrene (EPS), expanded polypropylene (EPP), expanded polyurethane, and the like, and having excellent thermal insulation.

First and second groove patterns are formed on the first surface (top surface) 130a and the second surface (bottom surface) 130b of the intermediate panel, respectively. The first groove pattern and the second groove pattern may have various shapes, may be a matrix arrangement such as a checkerboard arrangement, or may have an irregular arrangement. In the present embodiment, the first groove pattern includes a plurality of first grooves 131 having a checkerboard arrangement, and the second groove pattern includes a plurality of second grooves 132 having a checkerboard arrangement. The cross-sections of the first grooves 131 and the second grooves 132 may have a rectangular shape to facilitate manufacturing, but are not limited thereto and may have various shapes such as a triangle and a hexagon.

The first groove pattern and the second groove pattern form an air layer to improve heat insulation. In particular, the air layer is disposed adjacent to the first radiation heat reflecting sheet 141 and the second radiation heat reflecting sheet 142, respectively, so that the first radiation heat reflecting sheet 141 and the second radiation heat reflecting sheet 142 are provided. The space reflected by the radiant heat is dissipated.

In the present exemplary embodiment, the first grooves 131 and the second grooves 132 are alternately disposed so that the first grooves 131 and the second grooves 132 are different from each other in the vertical direction. Is placed on. That is, the first grooves 131 and the second grooves 132 are not arranged in a line in the vertical direction. However, the first grooves 131 and the second grooves 132 may be disposed to overlap only a portion in the vertical direction. That is, the first grooves 131 and the second grooves 132 may be arranged to be offset by a predetermined interval in the left and right directions.

As described above, since the air layer formed by the first grooves 131 and the air layer formed by the second grooves 132 are alternately arranged with each other, thermal insulation performance is improved regardless of the horizontal position of the building insulation material 100. Has the effect of improving.

The first radiation heat reflecting sheet 141 is inserted between the first insulation panel 110 and the intermediate panel 130. The second radiation heat reflecting sheet 142 is inserted between the second insulation panel 120 and the intermediate panel 130. The first radiation heat reflecting sheet 141 and the second radiation heat reflecting sheet 142 may be attached to one surface of the first insulation panel 110 and one surface of the second insulation panel 120 with adhesive or the like. Heat-sealed. The first radiation heat reflecting sheet 141 and the second radiation heat reflecting sheet 142 are aluminum thin film sheets (eg, aluminum foil) having excellent radiation heat reflecting ability. Since the first radiant heat reflecting sheet 141 and the second radiant heat reflecting sheet 142 reflect the radiant heat, when the building insulation is used for the exterior wall of the building, the radiant heat from outside the summer is reflected and blocked to flow into the room. Can be prevented. When used for the inner wall of the building to prevent the warm air from flowing out to the outside to improve the insulation effect.

Hereinafter, the method of manufacturing the said building insulation material 100 is demonstrated.

First, the first radiation heat reflecting sheet 141 is attached to one surface of the first insulation panel 110, and the second radiation heat reflecting sheet 142 is attached to one surface of the second insulation panel 120. do. Then, polystyrene or the like is foamed in a mold to manufacture the intermediate panel 130. Since the size, thickness, and shape of the first and second groove patterns 131 and 132 of the intermediate panel 130 need only be modified in the mold, it is possible to manufacture intermediate panels of various standards. Thereafter, the first insulation panel 110 and the second insulation panel 120 are heat-sealed with the intermediate panel 130 therebetween to complete the building insulation 100.

Since the building thermal insulation material 100 has high rigidity of the first insulation panel 110, the second insulation panel 120, and the intermediate panel 130, the worker may easily install the wall without breaking. In addition, since the standard of the intermediate panel 130 can be variously modified, it is possible to manufacture a building insulation according to various requirements.

3 and 4 show a building insulation 200 according to another embodiment of the present invention. Hereinafter, differences from the above-described embodiment will be mainly described.

3 and 4, the building insulation material 200 may include a first insulation panel 210, a second insulation panel 220, an intermediate panel 230, a first radiation heat reflecting sheet 241, and a second radiation heat. Reflective sheet 242. In the case of thermal fusion between the intermediate panel 230 and the first insulation panel 210, the adhesive force may be reduced by the first radiation heat reflecting sheet 241. Accordingly, holes 241a of the checkerboard array are formed in the first radiation-heat reflecting sheet 241 so that the upper surface of the intermediate panel 230 is heat-sealed in a state of directly contacting the first insulation panel 210. . The pattern of the holes 241a is substantially the same as the pattern of the second grooves 232.

Holes 242a having a checkerboard arrangement substantially the same as the first grooves 231 are formed in the second radiation-heat reflecting sheet 242, so that the bottom surface of the intermediate panel 230 is the second insulation panel 220. Heat-sealed in direct contact with the Therefore, since the intermediate panel 230 is strongly fixed to the first insulation panel 210 and the second insulation panel 220, the possibility of breakage of the building insulation 200 is greatly reduced.

In Figure 5 is shown a building insulation 300 according to another embodiment of the present invention. Hereinafter, differences from the above-described embodiment will be mainly described.

Referring to FIG. 5, the building insulation material 300 includes insulation panels 350, intermediate panels 360, first radiation reflection sheets 371, and second radiation reflection sheets 372. Four insulation panels 350 are spaced apart from each other in the vertical direction. The insulation panels 350 are formed of a rigid material such as expanded polystyrene.

The intermediate panel 360 is inserted between the insulation panels 350. First and second groove patterns are formed on the top and bottom surfaces of the intermediate panel 360, respectively. The first groove pattern and the second groove pattern respectively include first grooves 361 and second grooves 362 in a checkerboard arrangement. For the structure and operation of the first groove pattern and the second groove pattern, refer to the above-described embodiments.

The first radiation insulation sheet 371 is inserted between the upper surface of the intermediate panel 360 and the insulation panel 350. The second radiation insulation sheet 371 is inserted between the lower surface of the intermediate panel 360 and the insulation panel 350.

The building thermal insulation material 300 may be modified and used according to various requirements requiring various thicknesses and thermal insulation performance. That is, the insulation panel 350, the intermediate panel 360, and the first and second radiation heat reflecting sheets 371 and 372 are manufactured according to a specific standard. Then, when these are laminated reflecting the lamination structure shown in FIG. 5 according to the required conditions, building insulation having various thicknesses can be produced. Therefore, while maintaining the shape of the intermediate panel 360 to reduce the manufacturing cost, such as mold cost, because the building insulation is manufactured by adjusting only the number of laminated, the design conditions such as strength, insulation performance, thickness of the building insulation Since it can be variously modified, manufacturing cost is reduced and usability is improved.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100, 200, 300: building insulation
110, 210: first insulation panel 120. 220: second insulation panel
130, 230: middle panel 131, 231: first groove
132, 232: second groove 141, 241: first radiation heat reflecting sheet
142 and 242: second radiation heat reflecting sheet 350: heat insulation panel
360: middle panel

Claims (12)

A first insulating panel formed of a rigid material;
A second insulation panel disposed to be spaced apart to face the first insulation panel and formed of a rigid material to form a skeleton together with the first insulation panel;
A first groove pattern and a second interposed between the first insulation panel and the second insulation panel and forming an air layer on first and second surfaces facing the first insulation panel and the second insulation panel, respectively; An intermediate panel in which groove patterns are formed; And
A radiant heat reflecting sheet inserted between the first surface and the first insulation panel or between the second surface and the second insulation panel,
Holes are formed in the radiant heat reflecting sheet so as to correspond to the first groove pattern or the second groove pattern.
The intermediate panel such that the first groove pattern or the second groove pattern is inserted into the holes of the radiant heat reflecting sheet such that the first insulating panel and the second insulating panel are in direct contact with the intermediate panel to be heat-sealed. Coupled to,
The first insulation panel, the second insulation panel and the intermediate panel are each formed of expanded polystyrene (EPS), expanded polyurethane or expanded polypropylene (EPP),
The radiant heat reflecting sheet is a building insulation material is a sheet of a thin film formed of aluminum. The method according to claim 1,
The first groove pattern and the second groove pattern respectively include first grooves and second grooves formed in a checkerboard arrangement.
And the first grooves are arranged to be staggered with the second grooves. The method according to claim 1,
The first groove pattern and the second groove pattern may include first grooves and second grooves, respectively.
And the first grooves and the second grooves are arranged to be staggered so that at least a portion thereof does not overlap. The method according to claim 1,
The radiant heat reflecting sheet is inserted between the first surface and the first insulation panel and between the second surface and the second insulation panel, respectively. delete Attaching a first radiation heat reflecting sheet and a second radiation heat reflecting sheet to one surface of the first heat insulation panel and the second heat insulation panel formed of a rigid material, respectively;
Preparing an intermediate panel having a first groove pattern and a second groove pattern, each of which forms an air layer on an upper surface and a lower surface, and formed of a rigid material; And
The intermediate panel is heat-sealed between the first insulation panel and the second insulation panel while the first radiation heat reflection sheet and the second radiation heat reflection sheet face the first groove pattern and the second groove pattern, respectively. Including the steps of
Holes are formed in the first radiation-heat reflection sheet and the second radiation-heat reflection sheet to correspond to the first groove pattern and the second groove pattern.
The holes and the holes of the first radiant heat reflecting sheet of the first radiant heat reflecting sheet and the second radiant heat reflecting sheet such that the first heat insulating panel and the second heat insulating panel are in direct contact with the intermediate panel to be heat-sealed. It is coupled to the intermediate panel such that the first groove pattern and the second groove pattern are inserted into the holes of the second radiation row reflecting sheet,
The first insulation panel, the second insulation panel and the intermediate panel are each formed of expanded polystyrene (EPS), expanded polyurethane or expanded polypropylene (EPP),
The radiant heat reflecting sheet is a manufacturing method of a heat insulating material for building which is a sheet of a thin film formed of aluminum. The method of claim 6,
The first groove pattern and the second groove pattern respectively include first grooves and second grooves formed in a checkerboard arrangement.
And the first grooves are arranged to be staggered with the second grooves. delete delete delete delete delete

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