KR101616496B1 - Panel for with Multi-Functional Warm Insulation Board for Construction - Google Patents

Abstract

The present invention provides a reflective heat-insulation material of a multi-layer structure to reflect and insulate radiant heat energy moving from the outside to the inside or from the inside to the outside of a construction. A humidity path inside a warm insulation material is formed to discharge residual water and humidity to the outside. Heat-insulation performance is maintained by preventing cold air of the outside from flowing into the inside of a construction through a moisture movement hole, thereby preventing mold and dew condensation. According to the present invention, a plurality of wall coupling grooves and a convex protruding hole are formed in a rear surface portion of the warm insulation material for adhesive power with an exterior material to be improved, and an opening portion which is a vacuum space is formed in the warm insulation material to have an heat-insulation effect and withstand vacuum pressure. Moreover, a buffering function of a panel and the ease of installation can be improved.

Description

[0001] The present invention relates to a multi-functional insulation panel for a building,

The present invention relates to a panel having a multifunctional heat insulating material of a building, and more particularly, to a panel having a multifunctional heat insulating material of a building, and more particularly, to a method of radiating heat radiated from outside or inside the building to heat insulation, Which is installed in the building to prevent moisture and dew condensation by discharging humid air from the inside to the outside while maintaining the heat insulating performance.

It is known that the conventional heat insulating panel is manufactured for the purpose of insulating and insulating buildings. As a means of increasing the room temperature, curtain wall type facade materials are used as a material of glass to utilize the solar heating method or the transmitted sunlight.

However, these methods have insufficient thermal insulation function, so that the passive house or the zero house for the purpose of coping with the energy ray can not satisfactorily satisfy the purpose of the thermal insulation function.

Insulation is used to block heat from the outside of the building or to prevent internal heat from being released. Insulation reduces surface heat condensation by reducing surface heat tempera- tures while reducing energy loss by reducing heat loss by reducing heat loss and heat gain, and reducing room temperature fluctuations when cooling or heating is unnecessary or impossible.

Background Art [0002] The prior art is an improvement of a heat reflecting insulator, and is a heat insulating material for preventing radiant heat conducted from the outside or internal heat from flowing out to the outside.

The prior art is intended to enhance the heat insulation effect by constituting a plurality of insulation layers having different materials. The first insulation layer is composed of a nonwoven fabric layer having a high thermal insulation property. The second insulation layer is formed of a foamed bridging material having a soundproofing insulation function , And a third insulating layer having many air cells.

In the prior art having such a constitution, a heat insulating function by the first insulating layer, the second insulating layer and the third insulating layer exerts a heat insulating function, so that a high heat insulating effect by vacuum can not be expected.

In addition, the prior art insulation has a problem in that the vacuum pressure is low due to the fact that the physical vacuum method is excluded and the heat insulating function is deteriorated. Since the durability is poor, it can not be used as the external heat insulation panel of the building.

Such a heat insulating material has a limitation in preventing the occurrence of fungi and condensation due to the remaining water in the outer wall body, the moisture, the condensation water between the outer wall body and the heat insulating material to the outside due to the remaining water in the outer wall body,

Registered Utility Model No. 20-0420049 (Registered Date: June 21, 2006), Name of invention: "Thermal Reflective Insulation Material"

In order to solve the problems and necessities of the related art, the present invention reflects radiant heat energy transferred from the outside or the inside to the outside of the building to insulate and maintain the insulation, and prevents the outside cold air from flowing into the inside The object of the present invention is to provide a panel with a multifunctional thermal insulation material, which is capable of effectively preventing humidity and condensation by discharging humid air present inside while maintaining insulation performance.

In order to achieve the above object, the present invention provides a panel having a multi-

A front surface portion 110 to which a finishing material or an exterior material is attached, a back surface portion 120 attached to or coupled to a housing wall, that is, an outer wall body of the building, and a cube or a rectangular parallelepiped structure including the side surface portion 130, The installation drawing is a thermal insulation material,

The heat insulating material includes a plurality of moisture permeable holes 111a having moisture passages 112 having a predetermined depth from the surface of the front surface 110 toward the back surface 120,

The moisture passage 112 has a tapered shape that is narrower toward the front portion 110 from the rear portion 120 and has a ventilation structure in which the rear portion 120 is not penetrated,

One or more concave wall coupling grooves 124 are formed at a predetermined interval so as to be closely contacted with the outer wall of the building 120. In order to enhance the coupling force between the outer walls of the building, Convex protrusions 122 are protruded in the space between the moisture passage 112 and the rear surface portion 120. The space between the moisture passage 112 and the rear surface portion 120 includes a multi-

The anti-reflective material of the multi-layered structure includes an aluminum foil 140 formed on one side of the anti-fogging film 141 to prevent condensation from being adhered to one side of the anti- A polyester film 144 having a function of keeping a warming action and formed of a polyester, a polyester film 144 formed on one surface of the nonwoven fabric 142 to prevent corrosion, A support member 145 made of a titanium dioxide coating layer 145b for forming a vacuum space 145a including a thermal insulation material having voids in a space between the titanium dioxide coating layers 145b at regular intervals, And a polyethylene foam 146 formed on one surface of the member 145 to prevent energy loss due to heat conduction.

According to the present invention having the above-described constitution, a moisture passage is formed inside the heat insulating material to discharge the remaining water and moisture to the outside, to prevent the external cold air from flowing into the inside of the building through the moisture permeable hole, Mold and condensation can be prevented.

According to the present invention, a plurality of wall joint grooves and protruding projections are formed on the back surface of the heat insulating material, thereby improving the adhesion with the exterior material.

According to the present invention, a void portion, which is a vacuum space, is formed in the heat insulating material to withstand the heat insulating effect and the vacuum pressure, and the buffering function and ease of installation of the panel are improved.

The present invention provides a moisture-proof film in the heat-insulating material to prevent internal condensation and prevent the deterioration of the heat-insulating performance due to moisture.

1 is a perspective view illustrating a panel with a multi-function thermal insulation material of a building according to an embodiment of the present invention.
2 is a side cross-sectional view showing a panel with a multi-function thermal insulation material of a building according to an embodiment of the present invention.
And
3 is a side view of a panel with a multifunctional thermal insulation material of a building according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

The panel with the conventional thermal insulation has a limitation in preventing the occurrence of mold and condensation due to the remaining water in the outer wall, moisture and dew condensation because the condensed water between the outer wall and the thermal insulation can not be discharged to the outside, It is not possible to expect a high thermal insulation effect due to the vacuum, and since it is poor in durability, there is a problem in using it as an external thermal insulation panel of a building.

The present invention provides a multi-layered reflection heat insulator for reflecting heat radiated from the outside or internal to the outside of a building to insulate and maintain the insulation, and a moisture passage is formed inside the heat insulation, The present invention provides a panel with a multifunctional thermal insulation material, which is capable of preventing mold and condensation while maintaining the heat insulation performance by blocking the inflow of cold air from outside into the interior of the building through the moisture permeable ball.

FIG. 1 is a perspective view showing a panel with a multifunctional thermal insulation material of a building according to an embodiment of the present invention, and FIG. 2 is a side sectional view showing a panel with a multifunctional thermal insulation material of a building according to an embodiment of the present invention.

The panel 100 to which the multifunctional heat insulating material of the building according to the embodiment of the present invention is attached is a structure to be adhered to or bonded to an outer wall of a building. The panel 100 is a structure in which the remaining water and moisture in the outer wall of the building, And a plurality of discharge grooves 111 are formed at predetermined intervals in order to prevent the external cold air from flowing between the structure and the outer wall body of the building, The water vapor permeation hole 111a is formed.

The panel 100 with the multifunctional heat insulating material of the building includes a front portion 110 to which a finishing material or a facade material is attached, a back portion 120 to be attached or coupled to a housing wall, And is fixed to the outer wall of various buildings depending on the place where the structure is formed as a cube or a rectangular parallelepiped.

A plurality of moisture permeable holes 111a are formed at a predetermined depth in the direction of the back surface 120 from the surface of the front surface 110. The panel 100 having the multi- Moisture or humid air existing in the space between the panel 100 and the outer wall body of the building is discharged to the outside.

The moisture permeable hole 111a is formed as a plurality of minute ventilating holes having a predetermined depth from the front surface 110 toward the back surface 120 so that the remaining water and humidity inside the outer wall of the building, And serves as a path for discharging the moisture present in the space between them.

The moisture permeable hole 111a is formed in the outer surface of the building so that the moisture remaining in the outer wall of the building and the moisture present in the space between the building outer heat insulating material 100 and the outer wall of the building, The construction panel 100 is not formed in the thickness direction so as to prevent the building panel 100 from being introduced into the space between the outer wall body of the building and the building panel 100 through the through holes 111a, Thereby forming the moisture passage 112 having a certain depth in the direction of the arrow.

The moisture passage 112 performs a function of allowing the moisture to escape through the tapered shape as the width of the moisture passage 112 decreases from the back surface 120 to the front surface 110. The back surface 120 is formed of a non- do.

Since the moisture permeable hole 111a has a ventilation structure in which the back side 120 is not penetrated but one side is clogged, external cold air is blocked from flowing into the moisture permeable hole 111a.

A plurality of concave wall coupling grooves 124 are formed at a predetermined distance on the backside 120 of the panel 100 to which the multifunctional heat insulating material of the building is attached.

Convex projecting protrusions 122 protrude from the space between the wall coupling grooves 124 to reinforce the coupling force between the outer wall bodies of the building.

3 is a side view of a panel with a multifunctional thermal insulation material of a building according to an embodiment of the present invention.

The panel 100 to which the multifunctional thermal insulating material of the building is attached includes a multi-layered reflective thermal insulator in the space between the moisture passage 112 and the backing part 120.

The multilayered reflective heat insulating material includes a supporting member 145 composed of an aluminum foil 140, an anti-fogging film 141, a nonwoven fabric 142, a moisture-proof film 143, a polyester film 144, a titanium dioxide coating layer 145b, And a polyethylene foam 146.

The aluminum foil 140 is formed in the form of a thin plate in which an anti-fogging film 141 for preventing condensation is adhered to one side of the both sides and the anti-fogging film 141 is adhered to reflect radiant heat energy, It is possible to prevent cracks and deformation of the building.

The anti-fogging film 141 is a film for preventing water condensation by increasing the tension at the critical point of the film by dispersing the water generated on the surface of the anti-fogging film 141 by the additive.

The aluminum foil 140 coated with the anti-fogging film 141 suppresses the condensation phenomenon caused by the difference in temperature and humidity by the anti-fogging film 141 having the Anti-Fog function to prevent deterioration of the insulation performance and damage to the building .

The surface of the aluminum foil 140 coated with the anti-fogging film 141 is prevented from coming into contact with air and moisture, thereby preventing deterioration of heat reflection efficiency of aluminum.

The anti-fogging film 141 is disposed between the outer surface of the wall and the marble or other exterior material so as to prevent radiant heat from being damped, do.

The nonwoven fabric 142 is formed on one side of the anti-fogging film 141, and has a sound absorbing and insulating effect. The nonwoven fabric 142 is made of polyester. Bi-axially oriented propylene (BOPP ) Moisture-proof film 143 is formed.

The nonwoven fabric 142 absorbs an external impact and becomes tangled with the tacapine when the wall of the building heat insulating material adheres to the nacelle 142, so that the nonwoven fabric 142 can be firmly fixed to the wall surface.

The moisture-proof film 143 is a general PE film or a PET film, which acts to prevent the moisture permeation of water vapor. The moisture-proof film 143 is laminated on one side of the nonwoven fabric 142 to prevent moisture and moisture.

The polyester film 144 is formed on one surface of the nonwoven fabric 142 to prevent corrosion.

The support member 145 is formed on one side of the polyester film 144 and is made of a titanium dioxide coating layer 145b. The titanium dioxide coating layer 145b prevents the adhesion of other materials caused by the static electricity of the synthetic resin, improves the heat insulation characteristic of the titanium dioxide, and cuts off the external temperature such as the heat of the sun or the cold.

The support member 145 is formed with vacuum spaces 145a filled with a heat insulating material at regular intervals in a space between the titanium dioxide coating layers 145b.

The polyethylene foam 146 is a polyolefin-based foam which is foamed, crosslinked and foamed to have spherical independent bubbles, and has a low moisture absorption rate.

When polyethylene (PE) is used, it is possible to effectively prevent energy loss due to heat conduction, thereby achieving significant energy saving effects.

In addition, the polyethylene foam 146 has excellent moldability, is excellent in heat insulation, shock absorbing property, heat resistance, durability and chemical resistance, and is widely used for civil engineering, construction and daily use. Especially, Therefore, it has excellent properties as industrial insulation material and heat-insulating refrigerant.

The embodiments of the present invention described above are not implemented only by the apparatus and / or method, but may be implemented through a program for realizing functions corresponding to the configuration of the embodiment of the present invention, a recording medium on which the program is recorded And such an embodiment can be easily implemented by those skilled in the art from the description of the embodiments described above.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

100: Panel 110 with thermal insulating material 110: Front panel
111: discharge groove 111a: breathable ball
112: a moisture passage 120:
122: convex protrusion 124: wall coupling groove
130: side portion 140: aluminum foil
141: anti-fogging film 142: nonwoven fabric
143: moisture-proof film 144: polyester film
145: Support member 145a: Vacuum space
145b: titanium dioxide coating layer 146: polyethylene foam

Claims (1)

A front surface portion 110 to which a finishing material or an exterior material is attached, a back surface portion 120 attached to or coupled to a housing wall, that is, an outer wall body of the building, and a cube or a rectangular parallelepiped structure including the side surface portion 130, The installation drawing is a thermal insulation material,
The heat insulating material includes a plurality of moisture permeable holes 111a having moisture passages 112 having a predetermined depth from the surface of the front surface 110 toward the back surface 120,
The moisture passage 112 has a tapered shape that is narrower toward the front portion 110 from the rear portion 120 and has a ventilation structure in which the rear portion 120 is not penetrated,
One or more concave wall coupling grooves 124 are formed at a predetermined interval so as to be closely contacted with the outer wall of the building 120. In order to enhance the coupling force between the outer walls of the building, Convex protrusions 122 are protruded in the space between the moisture passage 112 and the rear surface portion 120. The space between the moisture passage 112 and the rear surface portion 120 includes a multi-
The anti-reflective material of the multi-layered structure includes an aluminum foil 140 formed on one side of the anti-fogging film 141 to prevent condensation from being adhered to one side of the anti- A polyester film 144 having a function of keeping a warming action and formed of a polyester, a polyester film 144 formed on one surface of the nonwoven fabric 142 to prevent corrosion, A support member 145 made of a titanium dioxide coating layer 145b for forming a vacuum space 145a including a thermal insulation material having voids in a space between the titanium dioxide coating layers 145b at regular intervals, And a polyethylene foam (146) formed on one surface of the member (145) to prevent energy loss due to heat conduction.

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