KR101137505B1 - Mixed insulating material for construction - Google Patents

Abstract

The present invention relates to a composite heat insulating material for building, more specifically, to improve the heat insulating performance by increasing the reflectance, and to suppress the condensation due to the temperature difference through the internal air pocket, and structurally small deformation before and after construction of the heat insulating material It suppresses the increase in thermal conductivity due to the reduction of deformation of the air flow area, prevents deformation of the aluminum foil layer due to external pressure through a simple structure. It relates to a composite heat insulating material having.
The present invention, the first double-sided adhesive tape 40 for bonding the first aluminum foil layer 31, the polyester nonwoven fabric layer 32 and the second aluminum foil layer 33, spaced apart to block heat transfer Rectangular air pocket 38 and polymer foam layer 34 formed in the polymer foam layer 34 so that individual spaces have independent air flow spaces 37 formed through the horizontal and vertical supporters 36. And a second double-sided adhesive tape 42 for simultaneously bonding the third aluminum foil layer 35 and one surface of the third aluminum foil layer 35 to reinforce and support the strength of the polymer foam layer 34. A foamed resin 39, a third double-sided adhesive tape 43 and the fourth aluminum foil layer 45 for simultaneously bonding the foamed resin 39 and the third aluminum foil layer 35 is characterized in that it comprises a.

Description

Mixed insulating material for construction

The present invention relates to a composite heat insulating material for building, more specifically, to improve the heat insulating performance by increasing the reflectance, and to suppress the condensation due to the temperature difference through the internal air pocket, and structurally small deformation before and after construction of the heat insulating material It suppresses the increase in thermal conductivity due to the reduction of deformation of the air flow area, prevents deformation of the aluminum foil layer due to external pressure through a simple structure, makes it easy to manufacture air pockets in the production of insulation, and provides stable insulation performance and convenient construction characteristics. It relates to a composite heat insulating material having.

In general, the composite insulation used in buildings is used to prevent heat transfer by attaching to the wall of the building, and it is installed on the inner and outer walls of the building to block cold, heat, and radiant heat so that the internal temperature of the building can Functions to be less affected by.

Insulation materials used in buildings are designed to promote energy saving by preventing heat leakage and unnecessary heat inflow, and to ensure comfortable indoor temperature by preventing surface condensation or deflection distribution and distortion of room temperature.

Surface condensation occurs on buildings. Surface condensation is a type of water condensation in which moisture in the atmosphere, including moisture, drops below the dew point, causing moisture in the atmosphere to form droplets on the surface of the object. Condensation is more likely to occur at higher humidity levels, forming stains on the floors and walls of buildings, causing decay, and producing mold.

Building surface condensation occurs mainly in winter, but also in summer. In summer, it can occur mainly in places like building basements. In the summer, the walls of the building's ground are high in temperature due to external influences, but condensation occurs because the walls of the basement are hardly affected by the outside.

It is known that the effective use of heat insulators attached to the surface of building walls can slow the movement of the heat medium and at the same time effectively prevent condensation.

Insulation is to reduce the heat flow rate by increasing the heat resistance value of the object through which heat flows, and in the case of a building, to reduce the heat transmission rate.

Heat permeability refers to the flow of heat through the member from the high temperature to the low temperature when both surfaces of the member having a predetermined thickness are in contact with the fluid and there is a temperature difference between the two fluids. Can be.

In order to reduce the thermal permeability for insulation, it is necessary to increase the thickness of the material and to select a material having low thermal conductivity.However, since the cost and workability are considered first, a material having low thermal conductivity is selected and the construction is applied to the building wall. Purchase construction was generally used.

Conventionally, styrofoam, glass wool, and the like, which are plate volume insulating materials, have been widely used, but the use of plate insulating materials has been reduced with the development of new insulating materials.

Background Art Structures using aluminum foil as a reflective insulation in construction composite insulation have been known.

Aluminum foil is a material having a low emissivity to radiation, and reflects the radiant heat energy to insulate, and the reflectance and emissivity of the metal surface are shown in Table 1.

Material reflectivity
(reflectivity in%) Average emissivity
(average emittance ε) Aluminum foil 92-97 0.05 Aluminum sheet 80 to 95 0.12 Aluminum coated paper 75 to 84 0.20 Sheet galvanized 70-80 0.25 Aluminum paint 30 to 70 0.50

Reflective insulation is important for reflectivity and emissivity of reflective surfaces. That is, the value of the reflective insulation is most preferably 95 to 97% of the reflectance, and most preferably 0.03 to 0.05 of the emissivity. As shown in Table 1, it can be seen that the values of reflectance and emissivity of the aluminum foil are most preferable.

It is more effective to attach aluminum foil to both sides than to only one side of the air layer. Because both sides have high reflectivity, the heat energy reflected through the aluminum foil collides with the closed air, which reduces the heat energy and blocks the movement of heat. This can be maintained and can also serve as a moisture resistant resistor.

Diagram Thermal Conductivity (W / ㎡K) Heat permeation resistance (㎡K / W) Air layer 10T + AL Foil 0.03137 0.3192 AL Foil + Air Layer 10T + AL Foil 0.02181 0.4585 Air layer 10T + AL Foil + Air layer 10T
+ AL Foil 0.03310 0.6247 AL Foil + Air Layer 10T + AL Foil
+ Air layer 10T + AL Foil 0.02715 0.7540

Table 2 shows the results of measuring the configuration of the aluminum foil and the air layer using a thermal conductivity meter. The thermal performance can be determined by the number of aluminum foils between the air layers. That is, it can be seen that the thermal performance increases with the number of foils in which aluminum foil is in contact with the air layer of the same thickness.

According to the above results, it can be seen that the movement of heat energy trapped in the air layer formed between the aluminum foils is impossible to move due to the reflective action of the aluminum foil.

In general, reflective insulation using aluminum foil was prepared by bonding nonwoven fabric and polyethylene foam between aluminum foil.

Such a heat insulating material has a problem that the heat insulating performance is reduced by reflecting heat only between the air layer between the wall and the aluminum foil.

Many techniques related to reflective insulation are known.

The technology disclosed in Korean Patent Registration No. 0583381 relates to a 'composite function reflective thermal insulation material and a method for manufacturing the same', and a heat insulating material for thermally bonding polyethylene resin between a polyester film layer, an aluminum foil layer, a nonwoven fabric, and a polyethylene foam. It is about. However, the nonwoven fabric and the polyethylene foam are bonded to the aluminum foil using a resin to reflect heat only on one side of the aluminum foil, so that the performance of the heat insulating material is deteriorated and there is a problem in that indoor and outdoor condensation occurs due to the temperature difference.

The technology disclosed in the Republic of Korea Utility Model Registration No. 0397724 is a technology related to the 'insulation for construction of a composite structure', as shown in Figure 1, laminated on the aluminum thin layer 11 and the aluminum thin layer 11 A polyethylene layer 12 or polystyrene layer 13, and a polystyrene layer 13 or polyethylene layer 12 laminated on the polyethylene layer 12 or polystyrene layer 13, wherein the polyethylene layer 12 The thickness of about 3mm to 10mm, the thickness of the polystyrene layer 13 is about 2mm to 3mm, the laminated thickness of the entire heat insulating material 10 is about 5mm to 13mm, the heat insulating material 10 is a polystyrene layer 13 Or a protective layer 14 provided on the polyethylene layer 12 to protect the heat insulating material from the external environment. However, the above technique has a problem in that the heat is reflected through one side of the thin aluminum layer 11, whereby the performance of the insulating material is degraded and condensation is generated by the temperature difference.

Another technology of Korean Patent No. 0592052 is a technology related to a 'reflective heat insulating material having a multilayer structure using polyurethane foam', and has an aluminum foil layer 21 and 22 positioned to reflect and block heat on both sides of the outer surface. To form a polyurethane foam layer (23, 24) adhered to the inner surface of both aluminum foil layers (21), (22), polyester nonwoven fabric (25) on one side of the polyurethane foam layer (23) And an air bubble layer 26 is formed between the polyester nonwoven fabric 25 and the polyurethane foam layer 24 on the other side to form the heat insulating material 20.

The technique reflects heat from both sides using the aluminum foil layers 21 and 22 on both sides, and the polyurethane foam layers 23 and 24, the polyester nonwoven layer 25, and the air bubble layer 26 are applied. As a heat reflection type heat insulating material 20 to insulate, it is configured to improve the heat reflection performance through the aluminum foil layers 21, 22 and the air bubble layer 26 on both sides to improve the thermal insulation effect and reduce condensation. .

However, the technique reflects heat from both sides using the aluminum foil layers 21 and 22 on both sides, and the polyurethane foam layers 23 and 24, the polyester nonwoven layer 25, and the air bubble layer 26 are used. Although the heat reflection type heat insulating material to insulate the air bubble layer 26 is a dense through-hole shape, when the internal and external pressure is applied from the outside before and after construction, the space of the air bubble layer 26 is deformed and the air flow cross-sectional area is reduced. The thermal conductivity is sharply increased, the heat and cold air blocking effect is reduced, and thus there is a problem that the condensation phenomenon is not sufficiently controlled, the manufacturing is difficult, there is a problem that the construction is deteriorated due to deformation.

In addition, reflective insulation that forms numerous micro holes in aluminum foil is known to prevent condensation. However, these insulation materials require complicated manufacturing operations to form holes and structurally rigidity of aluminum foil is achieved by forming a plurality of holes. There was a problem of this degradation.

The present invention was created to solve the problems of the conventional reflective insulating material, by placing an aluminum foil layer on the inner and outer surfaces of the reflective insulating material to increase the reflectance to improve the insulation performance and to suppress condensation due to temperature differences. The purpose is to provide a composite composite insulation for the construction.

Another object of the present invention is to control the condensation phenomenon appearing on the surface of the heat insulating material by suppressing the increase in thermal conductivity due to the reduction of the deformation of the air flow area by structurally reducing the deformation of internal and external pressure applied from the outside before and after construction of the reflective heat insulating material To provide composite insulation for construction.

It is still another object of the present invention to provide a composite insulating material for construction to prevent the deformation of the aluminum foil layer due to external pressure by applying a simple structure and at the same time to make the air layer structurally simple in the production of heat insulating material.

Still another object of the present invention is to provide a composite insulating material for construction having excellent heat insulating performance and convenient workability.

Building composite heat insulating material according to the present invention for achieving this object,

A first aluminum foil layer for reflecting heat, a polyester nonwoven fabric layer bonded to one surface of the first aluminum foil layer, a second aluminum foil layer bonded to one surface of the polyester nonwoven layer and blocking heat, and the first And a polymer foam layer for blocking heat while supporting the second aluminum foil layer and the polyester nonwoven layer, and a third aluminum foil layer bonded to the rear surface of the polymer foam layer to block and reflect heat conduction. To

The first aluminum foil layer, the polyester nonwoven fabric layer, and the second aluminum foil layer are bonded together with an adhesive, and layered between the second aluminum foil layer and the polymer foam layer to bond them by laminating them to the polymer foam layer. A first double-sided adhesive tape laminated and coated on both sides with an adhesive;

The polymer foam layer positioned between the second aluminum foil layer and the third aluminum foil layer is continuously and repeatedly formed through horizontal and longitudinal supports spaced apart to block heat transfer, thereby allowing individual spaces to flow independently. A rectangular air pocket formed to have a space;

Adhesive is coated on both sides to simultaneously bond the polymer foam layer and the third aluminum foil layer, and is disposed between the polymer foam layer and the third aluminum foil layer to simultaneously bond the polymer foam layer and the third aluminum foil layer. A second double-sided adhesive tape to be used;

A foamed resin bonded to one surface of the third aluminum foil layer to reinforce and support the strength of the polymer foam layer;

An adhesive is coated on both sides to adhere the foamed resin to the third aluminum foil layer, and is disposed between the foamed resin and the third aluminum foil layer to simultaneously bond the foamed resin and the third aluminum foil layer. Adhesive tape;

And a fourth aluminum foil layer bonded to one surface of the foamed resin by an adhesive tape to reflect heat.

The first and second double-sided adhesive tapes are formed in a band shape, and the shape of the band is formed in a shape corresponding to a horizontal and vertical support except for a space of a rectangular air pocket formed in the polymer foam layer.

The third double-sided adhesive tape has a band shape to reduce wrinkles and deformation of the third aluminum foil layer, and the shape of the band corresponds to a horizontal and vertical support except for a space of a rectangular air pocket formed in the polymer foam layer. The shape is configured to bond the third aluminum foil layer and the foamed resin to each other.

The rectangular air pocket formed on the polymer foam layer is characterized in that formed by selecting any one of the shape of the rhombus, circle, star, honeycomb, triangle.

The present invention has an effect of increasing the reflectance by placing an aluminum foil layer on the inner and outer surfaces to improve the insulation performance and to suppress condensation due to the temperature difference through the air pocket.

In addition, there is an effect that can control the condensation phenomenon appearing on the surface of the insulating material by suppressing the increase in thermal conductivity due to the reduction of the deformation of the air flow area by structurally reducing the deformation to the internal and external pressure applied from the outside before and after construction of the insulating material.

In addition, it is possible to prevent deformation of the aluminum foil layer due to external pressure through a simple structure, and at the same time can be manufactured by structurally simplifying the air pocket inside the insulation in the insulation manufacturing, high reliability insulation having stable insulation performance and convenient construction There is an effect that can provide.

1 is a perspective view showing a conventional building insulation.
Figure 2 is a cross-sectional view showing an example of another conventional heat insulating material for building.
Figure 3 is a partially bonded perspective view for explaining the composite thermal insulation for building according to an embodiment of the present invention.
Figure 4 is a detailed exploded perspective view of a building composite heat insulating material according to an embodiment of the present invention.
Figure 5 is a cross-sectional view of the combined state of the building composite insulating material according to an embodiment of the present invention.
6 is a detailed view of the portion A of Figure 5 to explain the composite thermal insulation for building according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings.

Figure 3 is a partially bonded perspective view for explaining the composite thermal insulation for building according to an embodiment of the present invention. Figure 4 is a detailed exploded perspective view of a building composite heat insulating material according to an embodiment of the present invention. Figure 5 is a cross-sectional view of the combined state of the building composite insulating material according to an embodiment of the present invention. FIG. 6 is a detailed view of part A of FIG. 5 to explain a composite thermal insulation material according to an embodiment of the present invention.

Building composite insulation according to the present invention has a polyester-based non-woven fabric between a pair of aluminum foil in order to leave enough space to sufficiently reflect heat in the aluminum foil layer and a polymer foam layer and aluminum foil having a separate air pocket It has a layer so that it can sufficiently reflect heat in the front and rear direction to have excellent heat insulation performance and to suppress condensation.

For reference, in the thermal insulation construction of the wall surface of the building structure using the heat insulating material including the interior, exterior materials, the heat insulation performance, it can be seen that the performance difference depending on the thickness of the heat insulating material, the performance of the heat insulating material used. Almost all insulation materials have been newly developed and developed so that the characteristics of these insulation materials can be exhibited because it is desirable to have sufficient insulation performance with a small thickness as much as possible, harmless and low cost, and economical insulation materials without difficulty in handling. .

The composite insulation for building according to the present invention is characterized in that there is no significant increase in thickness and also excellent insulation performance using materials commonly used in the field of insulation materials in this field.

Building composite heat insulating material 30 according to the present invention for achieving this object is as shown in Figs.

The second aluminum foil layer 31 that reflects heat, the polyester nonwoven fabric layer 32 adhered to one surface of the first aluminum foil layer 31, and the second nonwoven fabric layer 32 which is bonded to one surface of the polyester nonwoven fabric layer 32 to block heat. The polymer foam layer 34 and the polymer foam layer 34 which block heat while supporting the aluminum foil layer 33, the first and second aluminum foil layers 31 and 33, and the polyester nonwoven fabric layer 32. It is composed of a composite composite heat insulating material 30 including a third aluminum foil layer 35 bonded to the back surface to block and reflect heat conduction.

The main part is the first aluminum foil layer 31, the polyester nonwoven layer 32 and the second aluminum foil layer 33 are adhered with a conventional adhesive and laminated them to the polymer foam layer 34 to be bonded In order to form a layered layer between the second aluminum foil layer 33 and the polymer foam layer 34, both sides are composed of a first double-sided adhesive tape 40 coated with an adhesive 41.

In addition, the polymer foam layer 34 positioned between the second aluminum foil layer 33 and the third aluminum foil layer 35 has horizontal and vertical supports 36 spaced apart from each other so as to block heat transfer. It is formed repeatedly through the rectangular air pocket 38 formed so that each space has an independent air flow space (37).

Here, the air pocket 38 may be injection molded at a time without a separate operation integrally with the polymer foam layer 34.

In order to simultaneously bond the polymer foam layer 34 and the third aluminum foil layer 35, an adhesive 41 is coated on both surfaces and between the polymer foam layer 34 and the third aluminum foil layer 35. The second double-sided adhesive tape 42 is formed to bond the polymer foam layer 34 and the third aluminum foil layer 35 simultaneously.

In addition, the foamed resin 39 is bonded to one surface of the third aluminum foil layer 35 to reinforce and support the strength of the polymer foam layer 34.

In order to bond the foamed resin 39 to the third aluminum foil layer 35, an adhesive 41 is coated on both sides of the foamed resin 39, and is disposed between the foamed resin 39 and the third aluminum foil layer 35 to foam. It consists of the 3rd double-sided adhesive tape 43 which adheres the resin 39 and the 3rd aluminum foil layer 35 simultaneously.

And, it is made of a configuration including a fourth aluminum foil layer 45 is bonded to one surface of the foamed resin 39 by the adhesive tape 44 to reflect the heat.

In addition, the building composite heat insulating material according to the present invention, the first and second double-sided adhesive tape 40, 42 is made of a band shape, the shape of the band is a rectangular air pocket (38) formed in the polymer foam layer 34. It is preferable to configure in a shape corresponding to the horizontal and vertical support 36 except for the space 37 of the).

In addition, the third double-sided adhesive tape 43 is formed in a band shape to reduce the wrinkles and deformation of the third aluminum foil layer 35, the shape of the band is a rectangular air pocket formed in the polymer foam layer 34 ( It is preferable that the third aluminum foil layer 35 and the foamed resin 39 are bonded to each other in a shape corresponding to the horizontal and vertical support 36 except for the space 37 in the space 38.

In addition, the rectangular air pocket 38 formed in the polymer foam layer 34 may be formed by selecting any one of a rhombus, a circle, a star, a honeycomb, and a triangle, although not specifically illustrated in the drawing. However, since the first to third double-sided adhesive tapes 40, 42 and 43 are bonded to other layered structures, the rectangular shape is advantageous in forming the support 36, and the air of the air pocket 38 is better. Also in the flow space design, the rectangular shape is more advantageous than the other shapes.

On the other hand, the polyester-based nonwoven fabric 32 disposed between the first aluminum foil layer 31 and the second aluminum foil layer 33 is applied to increase the reflective ability to improve the heat shielding ability, the polymer foaming agent The air pocket 38 formed on the layer 34 functions to minimize the condensation by blocking the transfer of the medium while ensuring the reflective space of the aluminum foil layer.

In addition, as a method of bonding the insulation materials constituting each layer, any method may be used during bond bonding, thermal bonding, resin bonding, and hot melt bonding.

However, the first and second double-sided adhesive tapes 40 and 42 are applied to both surfaces of the adhesive 41 to simultaneously bond other heat insulator materials adhered thereto, and the shape of the first and second double-sided adhesive tapes 40 and 42 is the polymer foam layer 34. It is formed in a shape corresponding to the air pocket 38 is formed in the one side of the belt portion is bonded along the support 36 to form an air pocket 38 independent of the polymer foam layer 34.

In addition, the third double-sided adhesive tape 43 is formed to correspond to the shape of the air pocket 38 to prevent wrinkles and deformation of the third aluminum foil layer 35 to be adhered in a solid state.

That is, the third aluminum foil layer 35 is interposed between the polymer foam layer 34 and the foamed resin 39 to be laminated in a layered structure. One surface of the third aluminum foil layer 35 has a second double-sided adhesive tape 42. Since it is adhered to the polymer foam layer 34 through), the other surface is to be bonded using a third double-sided adhesive tape 43 of the same shape as the second double-sided adhesive tape 42 to conform to the bonding position, By adhering the third aluminum foil layer 35 at the same bonding position, it maintains a stable bonding state without thermal deformation or wrinkle after bonding.

The foamed resin 39 adhered through the third aluminum foil layer 35 and the third double-sided adhesive tape 43 improves the overall bending and flexural strength while simultaneously slowing heat transfer and reducing deformation.

Conventional heat insulating material having an air pocket is relatively weak in strength and deformation is easily generated as the air pocket is formed, the peeling phenomenon between the aluminum foil layer and the structural members as a whole frequently appeared.

Insulation materials are applied to the structure to reduce the high-strength adhesion and deformation to withstand a certain degree of peeling phenomenon or deformation, but it is easily deformed when the external pressure and internal pressure. In particular, soft materials with low hardness and low density are mainly used, so they are vulnerable to shape maintenance. The foamed resin 39 is bonded to the third aluminum foil layer 35 which is one side of the polymer foam layer 34 to reinforce the polymer foam layer 34 and at the same time serve to maintain and maintain the overall shape and heat transfer. Has been applied to the general characteristics of the insulation to block the.

On one surface of the foamed resin 39, the fourth aluminum foil layer 45 is treated in a layered structure with an adhesive tape 44 to reflect and block heat.

According to the layered structure of the composite insulating material for building according to the present invention configured as described above, the heat transferred into and out of the heat insulating material is blocked by the surface and the inner laminated aluminum foil layer.

The rectangular air pocket 38 formed in the polymer foam layer 34 can be formed into various shapes such as honeycomb shape and round shape as other shapes, and the size is approximately 4 to 16 cm 2. If the size of the air pocket 38 is too small, the effect is reduced by reducing the reflection area of the aluminum foil layer. If the size of the air pocket 38 is too large, the strength may be weakened, which may cause problems during construction. However, the present invention is to reinforce the bending and bending strength through a separate foamed resin (39) can improve the strength problems caused by the air pocket (38) formation.

In order to find out the performance of the composite composite heat insulating material according to an embodiment of the present invention, the performance test was carried out by the following method, and the results are as follows.

≪ Example 1 >

First, an air pocket 38 was formed on a 170 g / m 2 polyester nonwoven fabric and a polymer foam layer 34 having a thickness of 10 mm, and then an aluminum foil layer was bonded to prepare a composite heat insulating material.

<Example 2>

In addition, the air pocket 38 was formed on a 170 g / m 2 polyester nonwoven fabric, a polymer foam layer 34 having a thickness of 4, 5, 7, 10, and 15 mm, and then an aluminum foil layer was bonded to prepare a composite heat insulating material.

<Example 3>

In addition, the air pocket 38 was formed on the 170 g / m 2 polyester nonwoven fabric and the polymer foam layer 34 having a thickness of 7 mm, and then the aluminum foil layer was bonded to prepare a composite heat insulating material.

In order to test the fabricated composite insulation in accordance with KS F2277; 2002 (Measurement of thermal insulation of building components—calibration method and protective heat box method), a polymer foam layer 34 having an air pocket 38 provided between the composite insulation materials and Gypsum board was attached and commissioned to the Korea Institute of Construction Test, which was accredited by KOLAS.

Experimental Example 1

The composite insulation prepared as described above was cured in a constant temperature and humidity room at room temperature 20 ± 1 ℃ and room relative humidity 50 ± 5% for more than 24 hours, and then measured three times, and the measured values are shown in Table 3. .

1 time Episode 2 3rd time Average Air temperature [℃]


Constant temperature room 20.00 20.00 20.00 20.00 Heating box 19.66 19.66 19.67 19.66 Low temperature -0.08 -0.09 -0.05 -0.07 Temperature tea 19.74 19.75 19,72 19.74 Calorie [W]

Total supply calories 22.07 22.31 22.22 22.20 Calibration calorie 11.55 11.55 11.55 11.55 Test tube
Superheat 10.52 10.76 10.67 10.65 Test body
Both surfaces
Heat transfer resistance
[(㎡K) / W]
Surface thermoelectric
Moon resistance 0.126 0.123 0.123 0.124 Correction value 0.038 0.041 0.041 0.040 Perfusion Resistance [(㎡K) / W] 1.91 1.88 1.89 1.89 Heat transmission rate [W / (㎡K)] 0.52 0.53 0.53 0.53

Experimental Example 2

On the other hand, it was measured by the thermal conductivity meter of the composite insulating material through <Example 2> and <Example 3>, the measurement conditions were measured three times at low temperature 0 ℃, high temperature 20 ℃, the average value is Table 4 (according to the air pocket thickness Changes in heat permeation resistance) and Table 5 (correlation between air pocket size and AL Foil number).

Construction layer thickness Thermal conductivity Heat permeation resistance AL Foil + Non-woven Fabric + AL Foil + Air Pocket 4mm
+ AL Foil 6 0.03418 0.1645 AL Foil + Non-woven Fabric + AL Foil + Air Pocket 5mm
+ AL Foil 7 0.03087 0.2147 AL Foil + Non-woven Fabric + AL Foil + Air Pocket 7mm
+ AL Foil 9 0.03246 0.2978 AL Foil + Non-woven Fabric + AL Foil + Air Pocket 10㎜
+ AL Foil 12 0.03276 0.3952 AL Foil + Non-woven Fabric + AL Foil + Air Pocket 15㎜
+ AL Foil 17 0.04168 0.4685

Construction layer thickness Thermal conductivity Heat permeation resistance AL Foil + Non-woven Fabric + AL Foil + Air Pocket 15㎜
+ AL Foil 17 0.03418 0.4685 AL Foil + Non-woven Fabric + AL Foil + Air Pocket 7mm
+ AL Foil + Air pocket 7㎜ + AL Foil 16 0.03087 0.5799

As shown in Table 4, it can be seen that as the thickness of the air pocket formed in the polymer foam layer increases, the heat permeation resistance increases. However, it was also confirmed that increasing the thickness of the air pocket did not proportionally increase the heat permeation resistance value.

In other words, the heat resistance value is greatly increased at the thickness of the air pocket of 7 ~ 10㎜ or less, the heat insulation performance is insufficient at the thickness of less than that, and the thickness of the air pocket is larger as shown in Table 5 above, It can be seen that the heat permeation resistance is higher than the thickness when the air foil is divided between the aluminum foil layers and the number of aluminum foil layers is increased to form multiple layers of reflective spaces.

However, structurally increasing the air pocket 38 to increase the thermal insulation performance causes a relatively low strength of the thermal insulation material to accelerate the deformation and distortion and the delamination of the layered structure.

The present invention is to form an air pocket 38 in one polymer foam layer 34 and to reinforce the weak strength through the foamed resin 39 having a thickness.

In the present invention, by placing an aluminum foil layer on the inner and outer surfaces to increase the reflectance, heat insulation performance can be improved, and condensation due to temperature difference can be suppressed through the air pocket 38.

In addition, the deformation of internal and external pressures applied from the outside before and after the construction of the insulation is structurally reduced to suppress the increase in thermal conductivity due to the reduction of the deformation of the air flow area, thereby effectively controlling condensation on the surface of the insulation.

In addition, it is possible to prevent the deformation of the aluminum foil layer due to external pressure by applying a simple structure and at the same time can be manufactured by structurally simplifying the air pocket in the production of heat insulating material, there is an advantage that has a stable heat insulating performance and convenient construction properties.

As described above, the present invention has been described with reference to the drawings and specification, with reference to an embodiment of the invention, but it is an example. Those skilled in the art can make various modifications and equivalent implementations.

30: Insulation
31: First aluminum foil layer
32: polyester nonwoven fabric
33: second aluminum foil layer
34: polymer foam layer
35: third aluminum foil layer
36: support
37: Space
38: Air pocket
39: foaming resin
40: First double sided adhesive tape
41: adhesive
42: Second double sided adhesive tape
43: third double-sided adhesive tape
44: adhesive tape
45: fourth aluminum foil layer

Claims (4)

The second aluminum foil layer 31 that reflects heat, the polyester nonwoven fabric layer 32 adhered to one surface of the first aluminum foil layer 31, and the second nonwoven fabric layer 32 which is bonded to one surface of the polyester nonwoven fabric layer 32 to block heat. The polymer foam layer 34 and the polymer foam layer 34 which block heat while supporting the aluminum foil layer 33, the first and second aluminum foil layers 31 and 33, and the polyester nonwoven fabric layer 32. In the building composite heat insulating material 30 comprising a third aluminum foil layer 35 bonded to the back surface to block and reflect heat conduction,
The first aluminum foil layer 31, the polyester nonwoven fabric layer 32, and the second aluminum foil layer 33 are bonded with an adhesive, and the second aluminum foil is laminated and adhered to the polymer foam layer 34 in a laminated manner. A first double-sided adhesive tape 40 laminated in layers between the layer 33 and the polymer foam layer 34 and coated on both sides with an adhesive 41;
The polymer foam layer 34 positioned between the second aluminum foil layer 33 and the third aluminum foil layer 35 is supported by horizontal and longitudinal supports 36 spaced apart to prevent heat transfer. A rectangular air pocket 38 that is formed repeatedly and repeatedly so that each space has an independent air flow space 37;
In order to simultaneously bond the polymer foam layer 34 and the third aluminum foil layer 35, an adhesive 41 is coated on both sides, and is disposed between the polymer foam layer 34 and the third aluminum foil layer 35. A second double-sided adhesive tape 42 for simultaneously bonding the polymer foam layer 34 and the third aluminum foil layer 35 to each other;
A foamed resin 39 adhered to one surface of the third aluminum foil layer 35 to reinforce and support the strength of the polymer foam layer 34;
In order to adhere the foamed resin 39 to the third aluminum foil layer 35, an adhesive 41 is coated on the amount, and the foamed resin 39 is disposed between the foamed resin 39 and the third aluminum foil layer 35. A third double-sided adhesive tape 43 for simultaneously adhering the 39 and the third aluminum foil layer 35 to each other;
Building composite heat insulating material further comprises a fourth aluminum foil layer (45) that is bonded to one surface of the foamed resin (39) by an adhesive tape (44) to reflect heat. The method of claim 1,
The first and second double-sided adhesive tapes 40 and 42 are formed in a band shape, and the shape of the band is horizontal and vertical except for a space 37 of a rectangular air pocket 38 formed in the polymer foam layer 34. The composite insulating material for building, characterized in that configured in the shape corresponding to the support (36). The method of claim 1,
The third double-sided adhesive tape 43 is formed in a band shape to reduce wrinkles and deformation of the third aluminum foil layer 35, and the shape of the band is a rectangular air pocket 38 formed in the polymer foam layer 34. Building composite heat insulating material, characterized in that the third aluminum foil layer 35 and the foamed resin (39) is configured in a shape corresponding to the horizontal and vertical support (36) excluding the space (37). The method of claim 1,
The air pocket (38) formed in the polymer foam layer 34 is formed by injection molding integrally to the polymer foam layer (34).

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