KR20110006748A - Complex insulator for construction having plural reflecting layers - Google Patents

Abstract

PURPOSE: An architecture-purpose composite insulator with a plurality of reflective layers is provided to ensure insulating, sound absorbing and shock absorbing effects and to prevent dew condensation. CONSTITUTION: An architecture-purpose composite insulator(1) with a plurality of reflective layers comprises a plurality of reflective layers(10) and an insulating layer(20). The reflective layer is formed from aluminum foil so that heat is reflected. The insulating layer is located between neighboring reflective layers and forms a reflective space between reflective layers simultaneously with insulating. The insulating layer comprises a non-woven fabric layer(21) and an air layer(22).

Description

COMPLEX INSULATOR FOR CONSTRUCTION HAVING PLURAL REFLECTING LAYERS}

The present invention relates to a composite composite heat insulating material having a plurality of reflective layers, and more particularly, by providing a reflective layer made of aluminum foil that reflects heat not only in the outermost layer but also in the middle layer thereof, to increase heat insulation efficiency, and between the reflective layers. By providing an insulating space layer to ensure a reflective space it is possible to lower the emissivity of the reflective layer to maximize the thermal insulation efficiency and at the same time by providing a non-woven layer and an air layer as the insulating space layer, heat insulation as well as sound absorption, The present invention relates to a composite insulating material provided with a plurality of reflective layers that can prevent shock absorption and condensation.

In general, more than 40% of the energy heat loss of the building is generated through the outer wall, because the air flows into or out of the building through the fine pores of the concrete or brick of the building.

In a building that is not sufficiently insulated, the outdoor heat is easily introduced into the indoor cooling room during summer, and the indoor heat is easily released to the outdoor during the winter season. In other words, this means that energy consumption is considerable in order to maintain a comfortable indoor thermal environment.

In addition, in a building that is not sufficiently insulated, when the room is heated indoors in the cold winter, the wall surface temperature is lowered because the wall is affected by the cold outside, and condensation is likely to occur on the wall surface. .

In order to insulate the building, the thermal transmittance should be reduced. For this, a method of increasing the thickness of the material or selecting a material having a low thermal conductivity may be considered.

However, the method of increasing the thickness of the material is a method of selecting a material having a low thermal conductivity, that is, a method of inserting a heat insulating material into the building wall because of problems such as construction cost and construction.

Insulation is being used to improve the problems of such buildings and to save energy.

Insulation generally refers to a single material or a combination of materials that can greatly reduce the flow of heat by conduction, convection, and radiation. The range of use of these insulations is very broad.

Insulators reduce heat loss or heat gain by significantly reducing heat flow, conserving energy, preventing surface condensation due to surface temperature drop, and reducing fluctuations in room temperature when heating or cooling is not needed or impossible.

Insulation should also be able to prevent infiltration and moisture permeation. In addition to the basic properties of thermal insulation, the selection criteria of the thermal insulation material should consider various performances such as stiffness, sound insulation, anti-invasiveness, flame retardancy, heat resistance, economy, degree of human hazard, and stability.

In Korea, a porous or fibrous resistance type heat insulating material composed of numerous bubbles is generally used. Such resistance type heat insulating material is made to insulate by lowering thermal conductivity by stopping air.

A typical example of such a resistance type insulation is foamed polystyrene, but foamed polystyrene has the advantage of easy construction and light weight because air is composed of more than 98% of the volume. In the event of a fire, harmful gases such as carbon monoxide (CO), methane (CH ₄ ), and ethylene (C ₂ H ₄ ) are generated. There was a disadvantage of dissolving.

On the other hand, inorganic insulating materials such as glass wool and rock wool are resistant to heat and have excellent workability at joints, but have high hygroscopicity and are not excellent in mechanical properties in the molded state, making them difficult to install on the wall and weighing a lot. There was a disadvantage that can cause dust respiratory diseases of the human body.

Although a reflective heat insulating material is proposed to replace the resistive heat insulating material having the above-described problems in the prior art, the reflective heat insulating material according to the prior art has an advantage of easy construction, but the reflective layer made of aluminum foil or the like is a single layer. It is made of only or is disposed only in the outermost layer, the heat reflectivity is lowered, and since the simple bubble paper is laminated to the reflective layer, there is a disadvantage that the heat insulating performance is lower than the conventional heat insulating material.

For reference, reflective insulation is a material that has a low emissivity against thermal radiation, which reflects heat radiation to insulate radiant heat energy, and insulates heat between walls and tiles or between walls and interior panels to prevent heat emission. Refers to insulation.

The present invention has been made to solve the problems of the prior art as described above, the object of the present invention is to provide a reflective insulating material to replace the conventional resistance-type insulating material, the outermost layer of a reflective layer made of aluminum foil reflecting heat In addition, by providing a layer in the middle layer to increase the thermal insulation efficiency, by providing an insulating space layer between the reflective layers to ensure a reflective space can lower the emissivity of the reflective layer to maximize the thermal insulation efficiency and at the same time the thermal insulation space By providing a nonwoven fabric layer and an air layer as a layer, it is to provide a composite composite insulating material having a plurality of reflective layers that can prevent heat insulation, as well as sound absorption, shock absorption and condensation.

Building composite heat insulating material provided with a plurality of reflective layers according to the present invention to achieve the above object, the plurality of reflective layers made of aluminum foil so that heat is reflected, and the neighboring space so as to ensure the reflective space between the reflective layers at the same time with heat insulation It is configured to include a heat insulating space layer positioned between the reflective layer, wherein the reflective layer is provided with at least three, wherein the heat insulating space layer is provided with an air layer made of a polyester-based non-woven fabric layer and a porous synthetic resin It features.

Building composite heat insulating material with a plurality of reflective layers according to the present invention by the above configuration is provided with a plurality of reflective layers to block the movement of heat on the inner and outer surfaces of the building through a continuous reduction effect, and excellent heat reflection ability as a reflective layer By using aluminum foil having a low moisture permeability, there is an effect of preventing condensation.

In addition, the composite composite heat insulating material having a plurality of reflective layers according to the present invention is provided with a heat insulating space layer so as to secure a reflective space between neighboring reflective layers to lower the emissivity of the reflective layer to increase the heat insulating efficiency to the maximum. It is effective, and by having a non-woven fabric layer and an air layer having excellent heat insulating performance and sound absorption effect as the heat insulating space layer, there is an effect that can prevent sound absorption, shock absorption and condensation as well as heat insulation in a thin thickness.

In addition, the composite composite insulation provided with a plurality of reflective layers according to the present invention can reduce the thermal stress of the concrete caused by the change in the outside temperature can not only help to maintain the performance of the concrete, but also a plurality of reflective and insulating space layer Since the layer is laminated in multiple layers to keep warm inside, condensation inside the surface is also prevented.

Hereinafter, with reference to the embodiment shown in the drawings will be described in more detail the building composite insulation provided with a plurality of reflective layers according to the present invention.

1 is a cross-sectional view of a building composite heat insulating material according to an embodiment of the present invention, Figure 2 is a state diagram used in the composite building heat insulating material according to an embodiment of the present invention.

Referring to the drawings, the composite composite heat insulating material 1 is provided with a plurality of reflective layers according to an embodiment of the present invention is a heat insulating space layer 20 located between the plurality of reflective layers 10 and the adjacent reflective layer (10) It is configured to include.

The reflective layer 10 serves to prevent the condensation due to moisture and heat condensation by reflecting the radiant heat to block the cracks and deformation of the building, and has excellent heat reflecting ability and the ability to block air and moisture. It consists of a foil and is provided with at least three or more.

In one embodiment of the present invention, the reflective layer 10 is provided with three reflective layers 10 of the first reflective layer 11, the second reflective layer 12, and the third reflective layer 13. The first reflective layer 11 and the third reflective layer 13 are positioned at the outermost layer, and the second reflective layer 12 is positioned at the intermediate layer.

The aluminum foil used as the reflective layer 10 is formed in a thin plate shape so as not to be wrinkled when wound in a roll shape. On the other hand, even when the aluminum foil is formed in a thin plate shape, there is no problem in blocking the communication between air and moisture due to the characteristics of aluminum.

The insulating space layer 20 serves to ensure the reflective space between the reflective layer 10 and the heat insulating at the same time to be located between the adjacent reflective layer 10, the nonwoven fabric layer 21 and the air layer 22 It is provided.

The nonwoven fabric layer 21 is polyester-based and is located between the first reflective layer 11 and the second reflective layer 12.

That is, the non-woven fabric layer 21 is a polyester-based fiber is arranged in a parallel or inverse direction (non-defining direction) without going through a woven process, and made of a felt shape by combining a synthetic resin adhesive, excellent thermal stability, mechanical properties It has high wear resistance, adhesive strength, and has excellent thermal barrier ability.

On the other hand, the non-woven fabric layer 21 itself has a heat insulating effect, thermal insulation effect, shock absorbing effect and soundproofing effect, and tangled with takapin when the wall surface of the building composite heat insulating material according to an embodiment of the present invention, nail It will be hooked up, allowing it to be firmly fixed to the wall.

In addition, the nonwoven fabric layer 21 may provide a reflection space between the first reflection layer 11 and the second reflection layer 12 so as to provide emissivity of the first reflection layer 11 and the second reflection layer 12. By lowering it, it is possible to increase the thermal insulation efficiency of the first reflection layer 11 and the second reflection layer 12 to the maximum.

The air layer 22 is made of porous synthetic resin composed of a myriad of bubbles and is positioned between the second reflective layer 12 and the third reflective layer 13.

That is, the air layer 22 is formed between the second reflection layer 12 and the third reflection layer 13 by a warm temperature having a very low thermal conductivity, thereby having an effect of blocking the heat or cold air with a sudden temperature difference And the second reflective layer 12 and the second reflective layer 12 and the third reflective layer 13 so as to prevent condensation and to ensure a reflection space between the second reflective layer 12 and the third reflective layer 13, similarly to the nonwoven fabric layer 21. The emissivity of the third reflective layer 13 is lowered to maximize the heat insulation efficiency of the second reflective layer 12 and the third reflective layer 13.

Figure 2 illustrates the use state, but the composite composite heat insulating material 1 according to an embodiment of the present invention is the first reflective layer 11, the nonwoven fabric layer 21, the second reflective layer 12 from the outer wall (2) of the building The air layer 22 and the third reflecting layer 13 are sequentially stacked, and a predetermined space portion 4 is formed between the building composite heat insulating material 1 and the finishing material 3 of the outer wall.

Therefore, the heat emitted from the interior of the building to the outside through the outer wall (2) is primarily blocked by the first reflective layer 11, the air and moisture introduced through the finishing material 3 of the outer wall is the third The reflective layer 13 is primarily blocked.

Movement of heat, air, or moisture that is not blocked in the first reflection layer 11 or the third reflection layer 13 is continuously blocked by the heat insulating space layer 20 and the second reflection layer 12. Through the reduction effect, it is possible to completely block the movement of heat, air or moisture on the inside and outside surfaces of the building.

In particular, the third reflection layer 13 has the effect of keeping the temperature of the space portion 4 between the building composite heat insulating material 1 and the finishing material 3 by reflecting the incoming heat and air.

In addition, the first reflective layer 11, the nonwoven fabric layer 21, the second reflective layer 12, the air layer 22, the third reflective layer 13 is sequentially stacked so that the heat retention inside the building composite heat insulating material (1) As a result, surface condensation can be prevented as well as condensation therein.

Building composite insulation provided with a plurality of reflective layers described above and shown in the drawings is only one embodiment for carrying out the present invention, it should not be construed as limiting the technical idea of the present invention. The scope of protection of the present invention is defined only by the matters set forth in the claims below, and the embodiments which have been improved and changed without departing from the gist of the present invention are obvious to those skilled in the art. It will be said to belong to the protection scope of the present invention.

1 is a cross-sectional view of a building composite heat insulating material according to an embodiment of the present invention

Figure 2 is a state of use of the composite composite insulation for building according to an embodiment of the present invention

<Short description of the major reference symbols>

1 Composite building insulation

     10 reflective layer

           11 first reflection layer

           12 Second Reflective Layer

           13 Third Reflection Layer

     20 insulation space layer

           21 nonwoven layer

           22 air layer

Claims (1)

Comprising a plurality of reflective layers made of aluminum foil so that the heat is reflected, and a heat insulating space layer located between the adjacent reflective layers to ensure a reflective space between the reflective layers at the same time as the heat insulation, At least three reflection layers are provided, The heat insulating space layer is a composite heat insulating material having a plurality of reflective layers, characterized in that the air layer consisting of a polyester-based non-woven fabric layer and a porous synthetic resin.

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