KR101617249B1 - Insulator - Google Patents

Abstract

The heat insulating material of the present invention includes a first heat insulating sheet for intercepting heat by radiation, a first heat insulating sheet for intercepting heat by conduction and convection combined with one surface of the first heat insulating sheet, A second reflector formed in a lattice shape of polygons and intercepting radiation due to radiation passing through the first reflector, a second reflector coupled to one surface of the second reflector, and heat generated by conduction and convection passing through the first heat- A third reflector for intercepting radiation caused by radiation passing through the second reflector in combination with one surface of the second heat insulating sheet, And a seam line for integrating the second reflector, the second heat insulating sheet and the third reflector.

Description

Insulator {Insulator}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a heat insulating material, and more particularly, to a heat insulating material capable of efficiently preventing heat transfer by conduction, convection and radiation at the same time.

The largest portion of the energy consumption of buildings is heat loss through the exterior walls of buildings. Therefore, in order to save energy in the building, it is necessary to design and construct properly to improve the insulation performance of the outer wall of the building.

In general, insulation materials such as styrofoam, urethane foam, glass surface, rock surface, and polyester foam are mainly used to improve the heat insulation performance of the outer wall of a building. These insulation materials are mainly used for a resistance insulation method in which heat transfer due to conduction and convection is minimized. In fact, if a plate-like heat insulating material such as ordinary styrofoam is used, a considerable degree of heat loss can be prevented.

However, the heat transferred from the building through the outer wall is transmitted by radiation as well as conduction and convection.

Heat transfer in buildings is different by season and by building area, but radiative heat transfer has the greatest effect.

Therefore, a member such as an aluminum foil is attached to the heat insulating material such as styrofoam described above to prevent heat transfer by radiation.

For example, Korean Patent Laid-Open Publication No. 10-2009-0097067 (entitled "Radiation-Shielding Type Insulation Material") discloses a radiation-blocking type insulation material in which an aluminum evaporated film is bonded to one side of a crosslinked expanded polyethylene sheet.

However, in the case of the heat insulating material to which the aluminum evaporated film is bonded, when the aluminum evaporated film is adhered to foreign matter such as dust, the reflection effect of the radiant heat due to the aluminum evaporated film is remarkably deteriorated.

Particularly, in the construction process of the building, many foreign substances such as dust are generated, and even after the building is completed, foreign matter such as dust may be generated at a place where the heat insulating material combined with the aluminum evaporated film is installed.

In addition, although the thermal conductivity of a crosslinked polyethylene sheet or the like is low, there is a limitation in completely blocking heat transfer by conduction.

SUMMARY OF THE INVENTION The present invention has been devised to solve the problems as described above, and it is an object of the present invention to provide a heat insulating material capable of simultaneously preventing heat transfer by conduction, convection and radiation.

According to one aspect of the present invention, there is provided a heat insulating material comprising: a first heat insulating material for shielding heat by radiation; a first heat insulating sheet for intercepting heat due to conduction and convection by engaging with one surface of the first heat insulating material; A second reflector coupled to one surface of the first reflector and formed in a lattice shape of polygonal shape to block heat generated by radiation passing through the first reflector, A third reflector for intercepting heat generated by radiation passing through the second reflector in combination with one surface of the second heat insulating sheet; A heat insulating sheet, a seam line for integrating the second reflector, the second heat insulating sheet and the third reflector.

Wherein the seam line is disposed at a rim of the first reflector and includes a first seam line, which is integrally formed with the first reflector, the first heat insulating sheet, the second reflector, the second heat insulating sheet, And a second reflector disposed on the surface of the first reflector and sequentially passing through the first reflector, the first heat insulating sheet, the second reflector, the second heat insulating sheet, and the third reflector, Two seams may be provided.

The second seam line may be provided with a plurality of grid-like shapes having a predetermined gap.

And a diaphragm that divides the second reflector so that the lattice of the polygon formed by the second reflector forms a cell.

The first reflector, the second reflector, and the third reflector may be an aluminum thin plate having an emissivity of 0.1 or less.

According to another aspect of the present invention, there is provided a heat insulating material comprising: a first heat-insulating sheet for shielding heat by radiation; a first heat-insulating sheet for intercepting heat by conduction and convection combined with one surface of the first heat- A second reflector coupled to one surface of the first reflector and formed in a lattice form of polygons to block heat generated by radiation passing through the first reflector and a second reflector combined with one surface of the second reflector to improve the tensile force of the second reflector A second heat insulating sheet joined to one surface of the glass fiber sheet and intercepting heat by conduction and convection through the first heat insulating sheet; And a seam line for integrating the first reflector, the first heat insulating sheet, the second reflector, the second heat insulating sheet and the third reflector .

Wherein the seam line is disposed at a rim of the first reflector and includes a first seam line, which is integrally formed with the first reflector, the first heat insulating sheet, the second reflector, the second heat insulating sheet, And a second reflector disposed on the surface of the first reflector and sequentially passing through the first reflector, the first heat insulating sheet, the second reflector, the second heat insulating sheet, and the third reflector, Two seams may be provided.

The second seam line may be provided with a plurality of grid-like shapes having a predetermined gap.

And a diaphragm that divides the second reflector so that the lattice of the polygon formed by the second reflector forms a cell.

The first reflector, the second reflector, and the third reflector may be an aluminum thin plate having an emissivity of 0.1 or less.

According to the heat insulating material according to the present invention, heat transfer due to conduction, convection and radiation can be effectively prevented at the same time, which can exert a great effect on energy saving of buildings.

1 is a perspective view of a heat insulating material according to an embodiment of the present invention;
2 is a sectional view of a portion A in Fig.
3 is a perspective view of a second reflector provided in a cell according to an embodiment of the present invention;
FIG. 4 is an enlarged perspective view of the portion B in FIG. 1; FIG.
5 is a cross-sectional view of a heat insulator according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a heat insulating material according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a heat insulating material according to an embodiment of the present invention, and FIG. 2 is a sectional view of a portion A of FIG.

Referring to FIGS. 1 and 2, a heat insulating material 10 according to an embodiment of the present invention includes a first reflector 100 for blocking heat by radiation, a first heat insulating sheet 100 for shielding heat by conduction and convection, A second reflector 300 for blocking heat due to radiation, a second heat insulating sheet 400 for blocking heat due to conduction and convection, a third reflector 500 for cutting off heat due to radiation, ).

The first heat insulating sheet 200 is installed outside the second insulation sheet 400 and blocks heat generated by conduction and convection that primarily enter the interior of the building.

Heat conduction and convection which are not blocked by the first heat insulating sheet 200 can be cut off once more by the second heat insulating sheet 400 provided inside the building than the first heat insulating sheet 200 .

As a result, heat due to conduction and convection can be blocked over a plurality of times, so that the effect of cutting off heat due to conduction and convection can be increased.

In the present invention, the heat insulating material 10 is formed of two heat insulating sheets 200 and 400, but is not limited thereto.

In addition, the heat insulating sheets 200 and 400 may be formed using a foamable resin. Expandable Polystyrene (EPS), Expanded Plypropylene (EPP), Ethylene Vinyl Acetate (EVA), and the like can be used as the expandable resin used in the heat insulating sheets 200 and 400. [ May be used.

Since the heat insulating sheets 200 and 400 are formed of a foamable resin, the heat insulating material 10 is light and flexible and can be deformed freely.

Accordingly, as shown in FIG. 1, the heat insulating material 10 can be easily rolled into a roll shape or transferred to a construction site easily.

In addition, due to the flexible nature of the heat insulating material 10, the shape of the roof may be difficult when the roof is insulated, or the heat insulating material 10 may be continuously and adhered to the roof in conformity with the shape of the roof have.

In addition, it is possible to continuously apply adhesion to a right corner or a curved region generated according to the connection or form of various members forming the skeleton of the roof.

As described above, since the heat insulating material 10 has a flexible characteristic, it is not necessary to process the heat insulating material 10 to match the shape of the roof, so that the workability of the heat insulating material 10 can be improved and the use of the heat insulating material 10 can be minimized It is possible to exert the effect of reducing the construction cost.

In the present embodiment, the heat insulating material 10 is installed on the roof. The heat insulating material 10 can be used in various positions including a roof.

The first reflector 100, the second reflector 300, and the third reflector 500 are sequentially disposed from the outside to the inside of the building.

The first reflector 100 is disposed at the outermost side of the building to block heat generated by radiation radiated into the building.

The heat generated by the radiation not blocked by the first reflector 100 may be cut off once more by the second reflector 300 provided inside the first reflector 100 than the first reflector 100. In addition, the third reflector 500 is provided to further cut off the heat due to radiation not blocked by the second reflector 300.

As a result, heat due to radiation can be blocked over a large number, so that the effect of cutting heat by radiation can be increased.

In the present invention, the heat insulator 10 has been shown to comprise three reflectors 100, 300 and 500, but is not limited thereto.

As the reflectors 100, 300, and 500, a metal thin plate having a small thickness and a high reflectance may be used. As an example of the metal thin plate, an aluminum thin plate may be used. Also, the reflectors 100, 300, and 500 may be formed with an emissivity of 0.1 or less. This is because the higher the emissivity, the more heat can be prevented from being radiated, but the reflectors 100, 300, and 500 absorb heat, which may be disadvantageous in preventing heat transfer due to conduction.

At this time, the aluminum thin plate which can be used as the thin metal plate may be any one capable of reflecting heat transmitted by radiation, such as an aluminum sheet, an aluminum foil, an aluminum deposited film, or the like.

Here, the second reflector 300 is provided after being folded to form a polygonal lattice. This is because the structural strength of the second reflector 300 can be improved by bending the second reflector 300 having a small thickness. Heat is also transferred by convection. By forming a lattice between each of the first and second heat insulating sheets 200 and 400, it is possible to reduce the space through which air can move, thereby reducing heat transfer due to convection. Lt; / RTI > In FIG. 2, although the shape of the grid is triangular, the grid may be formed as a polygonal shape such as a square or rhombus as well as a triangular shape.

Meanwhile, the multi-level grating formed by the second reflector 300 can form the cell 710. The cell 710 will now be described in more detail.

3 is a perspective view of a second reflector provided in a cell according to an embodiment of the present invention.

Referring to FIG. 3, a cell 710 is formed on the second reflector 300 in a polygonal lattice formed by the second reflector 300.

The second reflector 300 may further include a diaphragm 700 that separates the second reflector 300 to form the cell 710. By forming the cells 710 having a small volume through the diaphragm 700 as described above, the space through which the air can move can be further reduced, and the heat transfer due to the convection can be more effectively reduced.

Accordingly, the heat insulating material 10 may include the reflectors 100, 300, and 500 and the heat insulating sheets 200 and 400 to thereby block not only heat due to conduction and convection but also heat due to radiation.

Next, a description will be given of a sewing line 600 for integrating the reflectors 100, 300, 500 and the heat insulating sheets 200, 400.

4 is an enlarged perspective view of part B in Fig.

1 to 4, a heat insulating material 10 according to an embodiment of the present invention includes the first reflector 100, the first heat insulating sheet 200, the second reflector 300, And a seam line 600 for integrating the heat insulating sheet 400 and the third reflector 500 together.

The sewing line 600 includes a first sewing line 610 and a second sewing line 620.

The first seam line 610 is located at the rim of the first reflector 100 and includes the first reflector 100, the first heat insulating sheet 200, the second reflector 300, (400) and the third reflector (500).

Accordingly, the reflectors 100, 300, and 500 and the heat insulating sheets 200 and 400 may be integrated by a first seam line 610.

Since the reflectors 100, 300, and 500 and the heat insulating sheets 200 and 400 are not attached using a separate tape, the effect of the reflectors 100, 300, and 500 and the heat insulating sheets 200 and 400 .

When the reflectors 100, 300, and 500 are integrated with the heat insulating sheets 200 and 400 by using an adhesive, the weight of the hardened adhesive is greater than the weight of the adhesive before hardening, can do. As a result, the problem of lowering the workability can be caused.

On the other hand, since the heat insulating material 10 of the present invention integrates the reflectors 100, 300, 500 with the heat insulating sheets 200, 400 through the sewing, the weight of the heat insulating material 10 does not increase So that the problem of deterioration of the workability is not caused.

The second seam line 620 is positioned on the surface of the first reflector 100 and includes the first reflector 100, the first heat insulating sheet 200, the second reflector 300, The sheet 400 and the third reflector 500 sequentially.

A plurality of second seam lines 620 are provided to form a lattice shape, and a plurality of second seam lines 620 are provided while maintaining a constant spacing.

The reflectors 100, 300, 500 and the heat insulating sheets 200, 400 can be further firmly integrated by the second seam line 620.

In addition, when the heat insulating material 10 is cut and cut along the second seam line 620, the heat insulating material 10 can be more easily cut and used because the heat insulating material 10 is provided at regular intervals.

Since the reflectors 100, 300 and 500 and the heat insulating sheets 200 and 400 are integrated by the second seam line 620, even if the heat insulating material 10 is cut and used, the reflectors 100, 300, It is possible to prevent the heat insulating sheets 200 and 400 from being separated.

Hereinafter, the heat insulating material 10 according to another embodiment of the present invention will be described in detail. In the following description, only different parts from the above-described embodiment will be described in detail and the same or similar parts will not be described in detail.

5 is a cross-sectional view of a heat insulating material according to another embodiment of the present invention.

5, a heat insulating material 10 according to another embodiment of the present invention includes a first reflector 100 for blocking heat by radiation, a first heat insulating sheet 200 for blocking heat by conduction and convection, A second heat insulating sheet 400 for shielding heat by conduction and convection, a second heat insulating sheet 400 for cutting off heat by radiation, And a second reflector (500).

Since the heat insulating material 10 has the glass fiber sheet 800, it is possible to exert an effect of delaying fire and propagation due to excellent resistance to burning.

The tensile force of the glass fiber sheet 800 and the tensile force of the surface of the second reflector 300 are combined to strengthen the overall tensile force of the heat insulating material 10. [

The heat insulating material 10 in which the reflectors 100, 300, 500, the heat insulating sheets 200, 400 and the glass fiber sheet 800 are integrated can prevent the heat insulating material 10 from being bent during construction or transportation, It is possible to minimize the surface cracking phenomenon that occurs when bending or cutting the substrate.

As described above, according to the heat insulating material 10 according to the embodiment of the present invention, heat transfer due to conduction, convection and radiation can be effectively prevented at the same time, thereby saving energy of a building.

Although the heat insulating material according to one embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiments disclosed herein. Those skilled in the art, who understands the spirit of the present invention, can readily suggest other embodiments by adding, changing, deleting, adding, or the like of components within the scope of the same idea, something to do.

10: Insulation material 100: First reflector
200: first insulating sheet 300: second reflector
400: second insulating sheet 500: third reflector
600: seam 700: diaphragm
800: glass fiber sheet

Claims (10)

A first reflector for blocking heat by radiation,
A first heat insulating sheet joined to one surface of the first reflector to block heat generated by conduction and convection,
A second reflector coupled to one surface of the first heat insulating sheet and formed in a polygonal lattice pattern to block radiation due to radiation passing through the first reflector,
A second heat insulating sheet coupled to one surface of the second reflector to block heat generated by conduction and convection through the first heat insulating sheet,
A third reflector coupled to one surface of the second heat insulating sheet to block heat generated by radiation passing through the second reflector,
And a seam line for integrating the first reflector, the first heat insulating sheet, the second reflector, the second heat insulating sheet and the third reflector,
Wherein the seam line is disposed at a rim of the first reflector and includes a first seam line, a second seam line, and a second seam line, which are integrally formed to sequentially penetrate the first reflector, the first heat insulating sheet, the second reflector, And a second reflector disposed on the surface of the first reflector and sequentially passing through the first reflector, the first heat insulating sheet, the second reflector, the second heat insulating sheet, and the third reflector, Two seam lines,
Wherein the second seam lines are provided with a plurality of lattice-like shapes having a predetermined interval.
delete delete The method according to claim 1,
Further comprising a diaphragm that divides the reflector so that a grid of polygons formed by the second reflector forms a cell.
The method according to claim 1,
Wherein the first reflector, the second reflector, and the third reflector are aluminum thin plates having an emissivity of 0.1 or less.
A first reflector for blocking heat by radiation,
A first heat insulating sheet joined to one surface of the first reflector to block heat generated by conduction and convection,
A second reflector coupled to one surface of the first heat insulating sheet and formed in a polygonal lattice pattern to block radiation due to radiation passing through the first reflector,
A glass fiber sheet combined with one surface of the second reflector to improve tensile force of the second reflector,
A second heat insulating sheet joined to one surface of the glass fiber sheet to block heat generated by conduction and convection through the first heat insulating sheet,
A third reflector coupled to one surface of the second heat insulating sheet to block heat generated by radiation passing through the second reflector,
And a seam line for integrating the first reflector, the first heat insulating sheet, the second reflector, the second heat insulating sheet and the third reflector,
Wherein the seam line is disposed at a rim of the first reflector and includes a first seam line, a second seam line, and a second seam line, which are integrally formed to sequentially penetrate the first reflector, the first heat insulating sheet, the second reflector, And a second reflector disposed on the surface of the first reflector and sequentially passing through the first reflector, the first heat insulating sheet, the second reflector, the second heat insulating sheet, and the third reflector, Two seam lines,
Wherein the second seam lines are provided with a plurality of lattice-like shapes having a predetermined interval.
delete delete The method according to claim 6,
Further comprising a diaphragm that divides the reflector so that a grid of polygons formed by the second reflector forms a cell.
The method according to claim 6,
Wherein the first reflector, the second reflector, and the third reflector are aluminum thin plates having an emissivity of 0.1 or less.

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