KR20180000916U - Multi-functional insulation that combines flame retardant, moisture-proof and sound-absorbing function - Google Patents

Abstract

The present invention relates to a multifunctional insulation material for construction used for enhancing flame retardancy, sound absorption and moisture resistance by being attached between the inner wall or outer wall of a building and a finishing material. Especially, The present invention relates to a multifunctional heat insulating material having flame retardancy, sound absorption and moisture-proofing function in consideration of human life.
In order to achieve the above object, a composite functional insulation material 1 having a flame retardant, a sound absorption and a moisture-proofing function according to the present invention comprises a first and a second aluminum (Al) The first aluminum foil 21 on the rear surface is a finished surface and the upper surface of the second aluminum foil 22 on the front surface is provided with a first foamed polystyrene A third surface of the third aluminum foil 23 is fused to the other surface of the first foamed polystyrene mesh resin 31 and the third aluminum foil 23, A second foamed polystyrene mesh resin 32 having an air layer structure of a predetermined thickness is fused on the other face of the second foamed polystyrene mesh resin 32. The other face of the second foamed polystyrene mesh resin 32 is made of glass fiber, Semi-incombustible material cotton (50) formed by fusing fourth and fifth aluminum foil (24) (25) on both sides of the first aluminum foil (40) are fused and integrally formed as a whole.
According to the present invention constructed as described above, the thermal insulation design of a building must be designed to have a complex thermal insulation which has a flame retardancy, a blemish and a moisture-proofing function. Therefore, even when a fire occurs in a building, , It is possible to save lives by securing the evacuation time from the danger of toxic gas resulting from the fire. By securing the sound absorption of the material, it is possible to reduce the interlayer noise, which is common in the apartment house, And it is possible to effectively prevent the permeation phenomenon caused by the water vapor pressure difference on both sides of the wall of the building and the infiltration phenomenon penetrating from the bottom of the building by the efficient bonding of the moisture proof functional material, A multi-functional heat insulating material having a moisture-proof function is provided.

Description

[0001] The present invention relates to a multi-functional insulation that combines flame retardant, sound absorption,

The present invention relates to a multifunctional insulation material for construction used for enhancing flame retardancy, sound absorption and moisture resistance by being attached between the inner wall or outer wall of a building and a finishing material. Especially, The present invention relates to a multifunctional heat insulating material having flame retardancy, sound absorption and moisture-proofing function in consideration of human life.

It is not an exaggeration to say that the movement of heat from inside and outside of the building as a whole takes place, and the movement from the wall occupies half of the whole.

Air flows into and out of the building through the fine pores of the concrete or brick making up the wall, and unwanted heat movement occurs.

Therefore, thermal insulation of a building is the wisdom of human being to cool the summer warmly in winter by efficiently managing the cooling and heating energy of the building by preventing the movement of heat moving in and out of the building.

In other words, the main purpose of insulation is to reduce heat loss and heat absorption from unwanted buildings, thereby reducing the capacity of the heating and cooling system and saving the consumption of cooling and heating energy per year.

Another secondary purpose of insulation is to prevent condensation by warming the surface of the interior side structure.

Condensation phenomenon is a phenomenon in which the temperature difference between inside and outside of a building wall is deep and the inside of the wall is wetted, which is a main cause of mold formation on the wall.

As a method for preventing the above-mentioned condensation, it is the best solution to reduce the temperature difference between the room temperature and the wall surface. Therefore, it is very effective to use the heat insulating material having the condensation blocking film on the back side of the heat insulating material.

Also, it is known that the material with the highest insulation effect is still air, and the insulation effect is the best at 20 ° C at room temperature than any insulation material.

Therefore, materials such as still air cells using air or foamed polystyrene have become the basis of insulation materials

In addition, styrofoam and glass fiber can be cited as insulation materials that have been used conventionally.

Styrofoam insulation material (EPS), which is preferred in terms of low cost and easy construction, has a disadvantage that fire conduction is quick and toxic gas is generated and it is very dangerous from fire. There is a problem in the workability, and there is a problem that the living space is reduced due to the thick thickness.

In addition, in the case of glass fiber, it is possible to delay the flame spreading rapidly on the side of the fire-retardant insulation material. However, it is difficult to expect pressure resistance unless the other material is attached to the surface, There has been a disadvantage that dust can cause respiratory diseases of the human body.

In addition, the problem of inter-story noise, which is common in apartment houses, is a serious social problem because it hurts the mutual reconciliation of neighboring houses. Also, when there is a difference in steam pressure on both sides of a building wall, The moisture permeates through the wall toward the wall, and the inflow of water gradually flows from the bottom of the building, causing a serious problem that must be quickly overcome.

The present invention has been devised in order to solve the above problems, and the thermal insulation design of the building should be a complex thermal insulation design having flame retardancy, blemish, and moisture proofing functions. In addition, It is possible to save life time by securing evacuation time from the risk of toxic gas resulting from fire by securing the sound absorption of the material and reducing the interlayer noise which is common in the apartment house, It is possible to improve the life of the building by effectively joining with the material which can provide the moisture proof function, and there is the permeation phenomenon by the water vapor pressure difference on both sides of the wall of the building, ), Which is a combination of flame retardant, blemish and moisture-proof function Will for the ball.

In order to achieve the above object, a composite functional insulation material 1 having a flame retardant, a sound absorption and a moisture-proofing function according to the present invention comprises a first and a second aluminum (Al) The first aluminum foil 21 on the rear surface is a finished surface and the upper surface of the second aluminum foil 22 on the front surface is provided with a first foamed polystyrene A third surface of the third aluminum foil 23 is fused to the other surface of the first foamed polystyrene mesh resin 31 and the third aluminum foil 23, A second foamed polystyrene mesh resin 32 having an air layer structure of a predetermined thickness is fused on the other face of the second foamed polystyrene mesh resin 32. The other face of the second foamed polystyrene mesh resin 32 is made of glass fiber, Semi-incombustible material cotton (50) formed by fusing fourth and fifth aluminum foil (24) (25) on both sides of the first aluminum foil (40) are fused and integrally formed as a whole.

According to the present invention constructed as described above, the thermal insulation design of a building must be designed to have a complex thermal insulation which has a flame retardancy, a blemish and a moisture-proofing function. Therefore, even when a fire occurs in a building, , It is possible to save lives by securing the evacuation time from the risk of toxic gas resulting from the fire. By securing the sound absorption of the material, it is possible to reduce the interlayer noise, which is common in the apartment house, And it is possible to effectively prevent the permeation phenomenon caused by the water vapor pressure difference on both sides of the wall of the building and the infiltration phenomenon penetrating from the bottom of the building by the efficient bonding of the moisture proof functional material, A multi-functional heat insulating material having a moisture-proof function is provided.

Fig. 1 is a perspective view of a multi-functional heat insulating material having the flame retardant, sound absorption and moisture-proof function of the present invention.
Fig. 2 is an exploded perspective view of the multifunctional heat insulating material having the flame retarding function, the sound absorption function, and the moisture-proof function.
Fig. 3 is an explanatory view of the planar material of the composite functional insulation having the flame retardant, sound absorption and moisture-proof function of the present invention.
Fig. 4 is an explanatory view of a still air cell structure of the composite functional insulation having the flame retarding function, the sound absorption function and the moisture-proof function.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings, which is a composite functional insulation material having a flame retardant, sound absorption and moisture-proof function.

Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings, and the inventor may appropriately design the concept of the term appropriately to describe its own design in the best way possible. Therefore, it should be understood that the embodiments described in this specification are merely one preferred embodiment of the present invention, and that the technical idea of the present invention is not limited to the technical idea of the present invention It is to be understood that various equivalents and modifications may be substituted for those at the time of filing of the present invention. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, in adding reference numerals to the constituent elements, it should be noted that the same constituent elements are denoted by the same sign and the same name as possible even if they are shown in different drawings.

FIG. 1 is a perspective view of a multifunctional heat insulating material having a flame retardant, sound absorption and moisture proofing function according to the present invention, FIG. 2 is an exploded perspective view of a multifunctional heat insulating material having a flame retardant, Fig. 4 is an explanatory view of a still air cell structure of a composite functional insulation material having the flame retardant, sound absorption and moisture-proofing functions of the present invention, which is a composite material heat insulating material having flame retardancy, sound absorption and moisture- .

As shown in FIGS. 1 to 4, the multifunctional heat insulating material 1 having the flame retardant, sound absorbing and moisture-proofing functions of the present invention has a first layer on the front and rear surfaces of an extruded foamed polystyrene resin (XPS. The first aluminum foil 21 on the rear surface is a finished surface and the upper surface of the second aluminum foil 22 on the front surface is fused with the second aluminum foil 21 A first surface of the first expanded polystyrene mesh resin 31 is fused and a third surface of the third aluminum foil 23 is fused again to the other surface of the first expanded polystyrene network resin 31. The third aluminum foil 23, A second foamed polystyrene mesh resin 32 having an air layer structure of a predetermined thickness is fused on the other face of the second foamed polystyrene mesh resin 32. The other face of the second foamed polystyrene mesh resin 32 is made of glass fiber, The amount of semi-fire-proof material 40 And a planar member (50) in which fourth and fifth aluminum foils (24) and (25) are fused and fused to the surface of the base member.

I will explain in more detail below.

As shown in Figs. 1 and 2, in the present invention, extruded expanded polystyrene (XPS) 10 is a skeleton.

The extruded expanded polystyrene resin 10 is made by melting raw materials and continuously compressing and foaming them, and is not suitable for absorbing water, and is therefore well suited for construction of bases and basements of buildings.

Also, even if it is thinner than the styrofoam material of the same performance, it is preferred as an insulation material of a building because it has good thermal insulation performance because it does not occupy space and its thermal conductivity is low.

The multifunctional heat insulating material 1 having the flame retardant, sound absorbing and moisture proofing functions of the present invention is excellent in flame retardancy due to a synthetic resin foamed foam using extruded expanded polystyrene resin (XPS.10) Is a composite functional heat insulating material for construction that combines the flame-retarding property by the semi-fire-proof material surface (40) to maximize the effect of flame retardation and maximizes the effect of heat insulation

1, a first aluminum foil 21 is fused to the rear surface of the extruded foamed polystyrene resin (XPS. 10) having a predetermined thickness as described above, and a second aluminum foil 22 ) Are fused together, the heat insulating property and the hygroscopic property are further reinforced.

Since the extruded foamed polystyrene resin 10 itself has almost no property of absorbing water, the present invention dispenses with adhesion of the first aluminum foil 21 on the back surface of the extruded foamed polystyrene resin 10 Also,

However, since the first aluminum foil 21 is fused to the rear surface of the extruded foamed polystyrene resin 10, it is very effective in preventing radiant heat, thereby further reducing the difference between the indoor temperature and the wall surface temperature of the building, It becomes more effective in blocking.

Next, on the upper surface of the second aluminum foil 22 fused to the front surface of the extruded foamed polyethylene resin (XPS) 10, one surface of the first expanded polystyrene network resin 31 having an air layer structure and having a predetermined thickness is fused And one side of the third aluminum foil 23, which is a partition wall, is fused to the other side of the first foamed polystyrene mesh resin 31.

The first expanded polystyrene mesh resin 31 is foamed to have a still air structure of a hollow state by itself, so that the first expanded polystyrene mesh resin 31 has a high heat insulating effect.

The first expanded polystyrene mesh resin 31 is fused to the lower second aluminum foil 22 and the upper third aluminum foil 23 to form the first foamed polystyrene mesh resin 31, the second aluminum foil 22 and the third aluminum foil 23 which are bonded to the upper and lower portions serve as upper and lower barrier ribs respectively, , Each cell forming a respective still air cell.

Therefore, the still air is known to have the best adiabatic effect at a room temperature of 20 ° C than any other insulating material, thereby providing an excellent adiabatic effect.

For reference, the first foamed polystyrene mesh resin 31 may be used by adding and laminating multiple layers of expanded polystyrene network resin, if necessary, and the third aluminum foil 23, which is a partition wall, Folded, laminated, or laminated.

That is, one surface of the second expanded polystyrene network resin 32 having an air layer structure of a predetermined thickness is fusion-bonded to the other surface of the third aluminum foil 23, which is a partition, and the other surface of the second expanded polystyrene network resin 32 It is also possible that one side of the fourth aluminum foil (not shown) as a partition wall is fused again. In the same manner, the aluminum foil (above) and the foamed polystyrene mesh resin (above) They can be stacked and used. However, since the additive and the laminated layers proceed in the same manner, a detailed description of the additive and laminated layers will be omitted here to avoid duplication of description.

In this process, first, a roll-shaped unit sheet (not shown) formed by roll-to-roll fusing a rolled foamed polystyrene mesh resin bottom surface of an aluminum foil having a predetermined thickness in a roll form is formed first, It would be advantageous in the process to directly laminate a sheet (not shown) directly on the entire surface of the extruded foamed polyethylene resin (XPS) 10 so as to have a predetermined thickness.

That is, first aluminum foil 21 is fused to the rear surface of extruded foamed polystyrene resin (XPS. 10) having a predetermined thickness to form a finished surface.

Next, a first foamed polystyrene mesh resin 31 having an air layer structure with a predetermined thickness is fused on the upper surface of the second aluminum foil 22 to form a unit sheet (not shown).

Another surface of the third aluminum foil 23 is again fused with a second foamed polystyrene mesh resin 32 having an air layer structure of a predetermined thickness to form another unit sheet (not shown).

Each unit sheet (not shown) repeatedly formed as described above is directly laminated and formed on the entire surface of the extruded foamed polystyrene (XPS) 10 by a predetermined thickness.

Next, as shown in Fig. 3, on the other surface of the foamed polystyrene network resin of the uppermost unit sheet (not shown), on both surfaces of the semi-fire-proof material surface 40 made of any one of glass fiber, silica gel or airgel, 5 aluminum foil 24 (25) are fusion-bonded to each other to form a single body.

Of course, conversely, the first aluminum foil 21 is fused to the back surface of the extruded foamed polystyrene resin (XPS. 10) having a predetermined thickness to become a finished surface, and a glass fiber, It is needless to say that the planar member 50 formed by fusing aluminum foil may be directly fused to both surfaces of the semi-fire-resistant surface 40 made of any one of the airgel and the airgel.

Hereinafter, the present invention will be described again.

On the other surface of the third aluminum foil 23 as the partition, another surface of the second expanded polystyrene network resin 32 having an air layer structure of a predetermined thickness is fused, and on the other surface of the second expanded polystyrene network resin 32, And the planar member 50 is fused and integrally formed as a whole.

3, fourth and fifth aluminum foils 24 and 25 are formed on both surfaces of a semi-fire-proof material surface 40 made of any one of glass fiber, silica gel or airgel, And are integrally formed by fusion bonding.

As the semi-fire-proof surface 40, glass fiber, which is a fireproof insulation material, can be used to delay the rapid diffusion of the flame during a fire. In addition, It is advantageous to use silica gel which can absorb moisture and absorb moisture again so that moisture absorption ability can be improved and reusable silica gel can be used and a shock buffer which is strong against heat, And for the soundproofing purpose it is suitable to use an airgel.

In the case of glass fiber, it was possible to delay the flame spreading rapidly in case of fire on the side of the fire-proof heat insulating material. However, it was difficult to expect pressure resistance unless other substances were attached to the surface, The present invention overcomes this problem by forming a planar member 50 by fusing fourth and fifth aluminum foils 24 and 25 on both sides of the glass fiber in the present invention .

In order to evacuate when a fire occurs, it is necessary to consider three factors of flame, smoke, and toxic gas generated in the fire. According to the present invention constructed as described above, the composite heat insulation having flame retardancy, As a designable insulation material, even if a fire occurs in a building, it is possible to delay the conduction of fire due to the flame retardancy of the insulation material, thereby saving life time by securing sufficient evacuation time from the risk of toxic gas resulting from fire, This can reduce the inter-floor noise that is common in apartment houses, thereby enabling the neighboring houses to live together in harmony. By effectively joining moisture-proof materials, the moisture permeability due to the difference in water vapor pressure on both sides of the building wall (Infiltration) from the bottom of the building. It is possible to provide a composite functional insulating material having flame retardancy, blemish and moisture-proof function that can be formed.

Although the present invention has been described in detail with respect to a preferred embodiment thereof with reference to the composite functional heat insulating material having the flame retardant, sound absorption and moisture proof functions, the present invention is not limited to the contents described in the above embodiment, It is to be understood that the invention may be embodied otherwise without departing from the spirit and scope of the invention as defined by the appended claims.

1 Multifunctional insulation with flame retardant, sound absorption and moisture-proof function
10 extruded expanded polystyrene resin
20 aluminum foil
21 1st aluminum foil 22 2nd aluminum foil 23 3rd aluminum foil
24 fourth aluminum foil 25 fifth aluminum foil
30 Foamed polystyrene mesh
31 1st expanded polystyrene mesh resin 32 2nd expanded polystyrene mesh resin
40 Semi-nonflammable material with either glass fiber, silica gel or airgel
50 surface material
60 Still air cell structure

Claims (4)

First and second aluminum foils 21 and 22 are fused to the front and back surfaces of an extruded foamed polystyrene resin (XPS. 10) having a predetermined thickness, the first aluminum foil 21 on the rear surface is a finished surface, A first foamed polystyrene mesh resin 31 having an air layer structure of a predetermined thickness is fused on the upper surface of the second aluminum foil 22 of the first foamed polystyrene mesh resin 31. On the other face of the first foamed polystyrene mesh resin 31, One surface of the third aluminum foil 23 is fused and another surface of the second foamed polystyrene mesh resin 32 having an air layer structure of a predetermined thickness is fused to the other surface of the third aluminum foil 23 as the partition, On the other surface of the second expanded polystyrene network resin 32, fourth and fifth aluminum foils 24 and 25 are fusion-bonded to both surfaces of the semi-fire-retardant material surface 40 made of any one of glass fiber, silica gel or airgel The one face material (50) is fused to form a whole It is a multi-functional insulation material that combines fire-retardant, sound-absorbing and moisture-proofing features. The composite heat insulating material according to claim 1, wherein the foamed polystyrene mesh resin (31) and the third aluminum foil (23) as the partition are capable of being laminated as required. A first aluminum foil 21 is welded to the back surface of the extruded foamed polystyrene resin (XPS. 10) having a predetermined thickness to form a finished surface, and a semi-fireproof surface 40 made of glass fiber, silica gel, And a face material (50) formed by fusing an aluminum foil on both sides of the aluminum foil (50) is fused and integrally formed as a whole. The multifunctional heat insulator having a flame retardant, sound absorption and moisture proof function. The composite heat insulating material according to any one of claims 1 to 3, characterized in that the adhesion of the first aluminum foil (231) on the rear surface of the extruded foamed polystyrene resin (10) is omitted. .

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