KR101290455B1 - Insulating material for building wall and its manufacturing method - Google Patents

Abstract

PURPOSE: An internal and external insulator for buildings and its manufacturing method is provided to improve thermal efficiency by improving the insulation performance of a building using an air layer and a reflective film. CONSTITUTION: An internal and external insulator for buildings comprises a first foamed sheet (10), a second foamed sheet (20), and a cover sheet (40). The first foamed sheet comprises a plurality of hemispherical protrusion (11) columns and a V-shaped bent part (12). The second foamed sheet adheres to the bottom surface of the first foamed sheet. The second foamed sheet comprises a plurality of hemispherical protrusion (21) columns and a V-shaped bent part (22). The cover sheet adheres to the top surface of the first foamed sheet. The cover sheet sticks a nonwoven fabric to a reflective sheet. The cross-sectional thicknesses of the hemispherical protrusion and the V-shaped bent part are same as the cross-sectional thicknesses of neighboring flat parts.

Description

Insulating Material for Building Wall and Its Manufacturing Method

The present invention relates to an interior and exterior insulation for buildings and a method for manufacturing the same, and more particularly, the interior and exterior insulation for buildings to be installed on the ceiling or the interior and exterior walls of the building to improve the thermal insulation performance of the building to improve the efficiency of thermal energy utilization. And to a method for producing the same.

Insulation is installed between the ceiling or the inner and outer walls or walls of the building to prevent heat loss due to the temperature difference between the inside and outside of the building, as a heat insulating material of the styrofoam is usually used.

Styrofoam insulation is light weight and has excellent insulation performance compared to other materials, so it is widely used as interior and exterior insulation for buildings, but it is not easy to handle due to its weak strength and can not be bent or folded. If the wall surface is not flat or made of a curved surface because the carry-in is inconvenient and the deformation is low, it is difficult to install the heat insulating material in close contact with the wall surface according to the shape of the wall surface.

Therefore, in recent years, the interior and exterior insulation for buildings that are excellent in insulation performance and easy to handle are being developed. As one example thereof, the building insulation disclosed in Korean Utility Model Registration No. 432661 may be mentioned.

Building insulation disclosed in the document is, as shown in Figure 1, the aluminum insulation layer 110 of aluminum material attached to the front and rear surfaces of the foamed polystyrene foam 100 and insulated by heat reflection; A flame retardant nonwoven fabric 120 attached to an outer surface of each aluminum heat insulation layer 110 and made of a flame retardant material; An aluminum finishing layer 130 attached to an outer surface of each of the flame retardant nonwoven fabric 120 and insulated by heat reflection; The aluminum insulating layer 110 and the flame retardant nonwoven fabric 120 is attached to the air layer is a structure consisting of a sheet 140 is formed.

However, the heat insulating material for buildings having the structure as described above, although the aluminum heat insulating layer 110 and the aluminum finish layer 130 are located on the front and rear and outer front and rear surfaces of the foamed polystyrene foam 100, the air insulation is formed in the middle part of the heat insulating material. Since the reflective sheet is not attached to the inner surface of the air layer sheet, the heat transfer prevention performance of the air layer may not be further improved.

In addition, the heat insulating material of the patent document is still difficult to bend or fold because the foamed polystyrene foam is located in the middle portion of the heat insulating material, and the flame-retardant nonwoven fabric is located on both the upper and lower outer surfaces, and thus the sheet is cut in a predetermined width and length unit. It has to be a problem with the conventional styrofoam insulation material that is difficult to transport and handle.

As another example of the heat insulating material, there may be mentioned the interior and exterior insulation for buildings disclosed in Patent Publication No. 2009-132093, the heat insulating material disclosed in this patent document is a foamed synthetic resin molded sheet 200, as shown in FIG. A foamed synthetic resin thin plate 210 adhered to one side of the foamed resin molded sheet 200; It is made of a foamed plastic molding sheet 200 and an aluminum sheet 220 bonded to one side or both sides of the foamed plastic sheet 210, a plurality of convex protrusions are formed on one side of the foamed plastic sheet 200 The air passage is formed, and the air layer is formed by forming a plurality of concave grooves on the other side.

However, the heat insulating material having the structure as described above, although the aluminum thin plate 220 is positioned on the front and rear surfaces of the foamed resin molded sheet 200, the reflective sheet is not attached to the inner surface of the air layer sheet forming the air layer, and the molded sheet 200 is also provided. Since there is only one layer, there is a problem in that the thermal insulation performance is low overall.

Moreover, the heat insulating material of the patent document has a non-uniform thickness of the portions connecting the convex protrusions and the concave grooves formed on the upper and lower portions, and the thicknesses of the portions forming the convex protrusions and the concave grooves, so that the thermal insulation performance is not uniform, and the foamed resin molded sheet By adhering to the front and rear surfaces of the flat sheet 200, the foamed synthetic resin sheet 210 is still difficult to bend or fold, which is difficult to transport and handle.

The present invention has been made to solve the problems of the conventional building insulation as described above, the object is to provide a building interior and exterior insulation and excellent manufacturing method and easy to transport and installation and its manufacturing method. have.

An object of the present invention as described above is the first foam sheet and the interior and exterior insulation for buildings, the hemispherical projection is repeatedly molded in a plurality of rows; A second foam sheet adhered to the bottom of the first foam sheet, and the hemispherical protrusions are repeatedly molded in a plurality of rows by pressure molding; The cover sheet is bonded to the upper surface of the first foam sheet and the non-woven fabric and the reflective paper are bonded to each other, and the first and second foam sheets extend in the width direction and the inverted " V " shaped bent portions are spaced at regular intervals. A plurality of pieces are formed, and the thicknesses of the hemispherical protrusions and the reverse faces of the inverted " V " -shaped bent portions are achieved by having the same thickness as the cross-sectional thickness of the peripheral planar portion.

At this time, it is preferable that the reflective film of the CPP material is adhered to the bottom of each of the first and second foam sheets.

In addition, the cross-sectional height of the first and second foam sheets is 15 to 25mm, respectively, including the height of the protrusions, and the height of the entire cross-section including the first and second foam sheets and the cover sheet is more preferably 35 to 50mm.

And a third foam sheet having a CPP reflective film attached to the bottom of the first and second foam sheets, wherein the third foam sheet and the reflective film are the first and second foam sheets and the reflective film, respectively. It is preferable to have the same shape and the same cross-sectional height.

In addition, an object of the present invention is to provide a method for manufacturing the interior and exterior insulation for buildings, the method of manufacturing the insulation, foamed polyethylene resin to produce a foam sheet, and then attach a reflective sheet of CPP material to the bottom of the prepared foam sheet, A foam sheet manufacturing and molding step of press-molding the hemispherical protrusion and the inverted " V " -shaped bent portion, respectively; A cover sheet manufacturing step of applying a molten resin to an upper surface of the nonwoven fabric and then supplying a reflective paper to the upper surface of the nonwoven fabric to which the resin is applied to press the roller with a roller; After applying the adhesive to the bottom of the cover sheet manufactured by the cover sheet manufacturing step, and then supplying the foam sheet prepared by the foam sheet manufacturing and molding step to the bottom of the cover sheet a plurality of times two or three Attaching the foam sheet of the layer to form a foam sheet; It is achieved by configuring the insulation sheet winding step of winding the insulation sheet produced by the foam sheet attaching step to the bobbin to facilitate transport and storage.

In this case, the resin used to bond the cover sheet and the nonwoven fabric is preferably polyethylene resin.

The heat insulating material of the present invention is formed by a plurality of foam sheets having a plurality of air layers are laminated by the hemispherical protrusions formed on the surface, and because the reflective film is provided for each air layer, heat transfer is effectively blocked, so that the heat insulating performance is greatly improved. .

In addition, the present invention is provided with a bent portion of the reverse "V" shape at regular intervals in the width direction of the heat insulating material, the heat insulating material can be easily bent along this bent, as a result, the transfer and handling of the heat insulating material is much easier.

In addition, in the present invention, since the thickness of the cross section of the projection and the bent portion has the same thickness as the cross-sectional thickness of the surrounding flat portion, heat transfer does not occur in any part of the heat insulating material, and there is a portion having weak strength due to the uniform thickness. In this case, even when an external pressure is applied to the foam sheet, it is prevented from being partially damaged or broken.

1 and 2 is a perspective view showing an example of a conventional heat insulating material for buildings,
Figure 3 is a perspective view showing an example of the interior and exterior insulation for buildings according to the present invention,
Fig. 4 is an exploded perspective view of Fig. 3,
5 (a) is a cross-sectional view of FIG.
5 (b) is a use state diagram showing an example in which the internal and external insulation of Figure 5 (a) is wound,
6 is a cross-sectional view showing an example attached to the third foam sheet according to the present invention;
7 is a flow chart showing a manufacturing method of the interior and exterior insulation for buildings according to the present invention,
8 is a process chart showing the manufacturing process of the interior and exterior insulation for buildings according to the present invention.

Hereinafter, the configuration of the present invention through the accompanying drawings showing a preferred embodiment will be described in more detail.

The present invention relates to a building interior and exterior insulation for reducing heat loss by blocking the heat transfer is installed on the ceiling or the inner wall or outer wall of the building, the heat insulating material of the present invention as shown in Figure 3 the first foam sheet ( 10), the second foam sheet 20 and the cover sheet 40.

The first foam sheet 10 and the second foam sheet 20 stacked on top of the first foam sheet 10 are each made of polyethylene resin having good processability and moldability and excellent thermal insulation performance. In this case, the first foam sheet 10 and the second foam sheet 20 have the same shape, and therefore, the first and second foam sheets 10 and 20 are manufactured by the same manufacturing process.

Each of the first and second foam sheets 10 and 20 has a hemispherical protrusion 11 and 21 that protrudes upward by pressure molding and has the same thickness as the surrounding flat portion, as shown in FIGS. 3 and 4. Are formed in a plurality of rows at regular intervals, thereby forming hemispherical grooves 11A and 21A inside the protrusions 11 and 21.

As shown in FIG. 5 (a, b), the first and second foam sheets 10 and 20 are stacked up and down by the protrusions 11 and 21 as described above, or a cover sheet 40 to be described later is disposed on the upper portion thereof. Even if they are located, spaced gaps are formed between them, and as a result, a space in which air stays between foam sheets and a cover sheet, that is, an air layer, is formed. Blocking and consequently the loss of thermal energy.

In addition, as shown in FIG. 6, the third foam sheet 30 may be further stacked on the lower portions of the first and second foam sheets 10 and 20, whereby the thermal insulation performance of the insulation is further improved.

At this time, the first, second, third foam sheets (10, 20, 30) are made of a foamed polyethylene resin, thereby having a light weight and excellent thermal insulation performance, and can be easily bent or bent.

Meanwhile, the thicknesses of the first and second foam sheets 10 and 20 and the third foam sheet 30 have cross-sectional heights in the range of 15 to 25 mm, including the heights of the protrusions 11, 21, and 31, respectively. When manufacturing the first and second foam sheets (10, 20) and / or the third foam sheet (30) having such a height in turn laminated, and a cover having a relatively thin height relative to these foam sheets on top By stacking the sheet 40 is prepared so that the cross section of the entire insulation material has a height range of 33 ~ 50 mm.

However, as described above, although the first, second, and third foam sheets 10, 20, and 30 can be easily bent or bent by manufacturing the foamed polyethylene resin, in the case of laminating them in two or three layers, a heat insulating material is used. It may be difficult to bend or bend easily, and therefore, in order to solve this problem, the present invention has an inverted “V” shape having a length in the width direction at regular intervals between the hemispherical protrusions 11, 21, and 31. The bent portions 12, 22, and 32 are formed, whereby the first, second, and third foam sheets 10, 20, and 30 are more easily bent based on the bent portions 12, 22, and 32 to roll by bobbins or the like. It can be wound in the form, and therefore, not only will it be easier to transfer or carry it into the work site, but also the construction will be much easier because it can be installed while unwinding a certain length from the roll form during construction. At this time, the thicknesses of the bent portions 12, 22, 32 are molded to have the same thickness as the surrounding planar portions, similar to the hemispherical protrusions 11, 21, 31.

On the bottom surfaces of the first, second and third foam sheets 10, 20 and 30 in which the hemispherical protrusions 11, 21 and 31 and the inverted " V " -shaped bent portions 12, 22 and 32 are formed. Reflective films 13, 23, 33 are attached, and the reflective films 13, 23, 33 block the movement of air particles that retain thermal energy to the outside, and at the same time reflect the air particles, thereby allowing the inside of the air layer to be reflected. The heat insulating performance of the heat insulator is further improved by staying in the heat insulator, and the reflective films 13, 23, and 33 are bent portions 12 having the inverse "V" shape and the hemispherical protrusions 11, 21, and 31 as described below. , 22, 32 are molded in accordance with the shape and adhered to the whole of the bottom of the flat surface and adheres, for this purpose, the material of the reflective film 13, 23, 33 is not stretched polypropylene (CPP) , Casting Polypropylene) film is used.

The cover sheet 40 positioned on the upper surface of the first foam sheet 10 has a structure in which the reflective paper 42 is adhered to the upper surface of the nonwoven fabric 41 made of long fibers, thereby further preventing heat from moving. The cover sheet 40 is prevented from being easily torn or damaged by the nonwoven fabric 41 constituting the sheet 40, and when the heat insulating material is fixed to the wall with a concrete nail, etc., the head of the nail does not fall out and is robust. Can be fixed.

In addition, when the cover sheet 40 is attached to the first foam sheet 10, the projection 11 and the bent portion 12 of the first foam sheet 10, as shown in Figure 5 (a, b) and 6 It is attached while partially in contact with the upper portion of the cover, thus forming an air layer between the cover sheet 40 and the first foam sheet 10, thereby preventing heat transfer. At this time, the height of the cover sheet 40 preferably has a height of 3 to 5 mm so that the heat insulating material can be easily wound on the bobbin or the like.

On the other hand, in the present invention, the thickness of the cross section of the hemispherical protrusions 11, 21, 31 and the inverted " V " -shaped bent portions 12, 22, 32 is equal to the cross-sectional thickness of the surrounding planar portion. Since it has the same thickness, even if a slight degree of heat transfer is made through the heat insulating material, heat transfer is not generated by concentrating on any part of the heat insulating material, which is advantageous for the heat insulating performance, and due to the uniform thickness, there is no weak strength part and thus foaming Even when an external pressure is applied to the sheet, it is prevented from being partially damaged or broken.

Hereinafter, the method of manufacturing the interior and exterior insulation for buildings of the present invention having the structure as described above will be described.

Building interior and exterior insulation material manufacturing method according to the present invention is as shown in Figures 7 and 8 foam sheet manufacturing and molding step (S100), cover sheet manufacturing step (S200), foam sheet attaching step (S300) and the insulation winding Step S400 is made.

(1) foam sheet manufacturing and molding step (S100)

This step is a step of forming a foam sheet by foaming polyethylene resin, and then attaching a reflective sheet to the bottom of the prepared foam sheet, and then forming a hemispherical protrusion and an inverted “V” shaped bend, respectively. When a foam sheet having a uniform thickness is prepared by foaming polyethylene resin, as shown in FIG. 8, an adhesive is applied to the bottom surface of the foam sheet by a roller, and then a CPP material separately supplied to the surface to which the adhesive is applied. Attach the reflective sheet of.

After the reflective sheet is attached to the bottom of the foam sheet as described above, the foam sheet with the reflective sheet is attached to the hemispherical protrusions (11, 21, 31) and the inverted " V " 22 and 32 are supplied to the forming roller 2 'having a shape corresponding to the shape thereof, and press-molded so that the protrusions and the bent portions having the same cross-sectional thickness are simultaneously formed.

By forming the projections and bent portions on the surface by the above-described process, after the foam sheet with a reflective sheet is manufactured on the bottom, the foam sheet is wound on a plurality of rolls (bobbins), respectively, in the subsequent insulation manufacturing step Ensure a smooth supply.

(2) cover sheet manufacturing step (S200)

This step is to prepare a cover sheet 40 to be attached to the upper portion of the first foam sheet 10, for this purpose, the resin stored in the hopper (1) in the molten state as shown in FIG. After applying to the upper surface of the non-woven fabric 41 of the, and then supplying the reflective paper 42 to the upper surface of the non-woven fabric 41 is coated with this resin to press them with a roller to produce a cover sheet 40.

At this time, the molten resin stored in the hopper 1 and used to bond the cover sheet and the nonwoven fabric is made of polyethylene so that a firm bonding can be made between the long fiber nonwoven fabric 41 and the first foam sheet 10 made of polyethylene. Resin is used.

(3) foam sheet attachment step (S300)

After the cover sheet 40 is manufactured by the cover sheet manufacturing step (S200), the adhesive sheet is applied to the bottom of the cover sheet 40 manufactured by using the adhesive coating unit 3, and then the foam sheet Manufacturing and reflecting film attaching step (S100) by supplying and attaching the foam sheet prepared in the bottom surface of the cover sheet 40 to prepare a heat insulating material sheet, such foam sheet attaching step (S300) is the number of layers of foam sheet to be laminated As many times, that is, repeated twice or three times, thereby laminating and attaching two or three layers of foam sheets.

(4) insulation winding step (S400)

After the cover sheet 40 and the insulating sheet consisting of the first and second foam sheets (10, 20) or the first, second and third foam sheets (10, 20, 30) are manufactured, the manufacturing process After drying with hot air or the like so that the resin and the adhesive applied therein can be completely dried, the dried heat insulating material is wound on a bobbin 4 having a diameter and width of a predetermined size for easy transportation and storage.

As described above, the heat insulating material of the present invention has a structure in which a hemispherical protrusion and a reverse V-shaped bent portion are respectively formed on the surface thereof, and a plurality of foam sheets with a reflective film are laminated on the bottom thereof. Therefore, a heat insulating material having excellent heat insulating performance but easy to transport and handle can be provided.

1: hopper 2: roller
2 ': forming roller 3: adhesive coating
4: bobbin 5: cutting machine
10: first foam sheet 11: projection
11A: Groove 12: Bend
13: reflective film 20: second foam sheet
21: Turning 21A: Home
22: bend portion 23: reflective film
30: third foam sheet 31: projection
31A: Groove 32: Bend
33: reflective film 40: cover sheet
41: nonwoven fabric 42: reflective paper

Claims (6)

In the heat insulating material for buildings installed on the inner wall or outer wall of the building to block heat transfer,
A first foam sheet 10 in which the hemispherical protrusions 11 are repeatedly molded in a plurality of rows;
A second foam sheet 20 adhered to the bottom surface of the first foam sheet 10 and the hemispherical protrusions 21 are repeatedly molded in a plurality of rows by pressure molding;
It is composed of a cover sheet 40 is bonded to the upper surface of the first foam sheet 10, the nonwoven fabric 41 and the reflecting paper 42 are bonded to each other,
The first and second foam sheets 10 and 20 extend in the width direction, and a plurality of inverted “V” shaped bent portions 12 and 22 are formed at regular intervals.
The thickness of the cross section of the hemispherical protrusions 11 and 21 and the inverted " V " -shaped bent portions 12 and 22 has the same thickness as that of the surrounding flat portion. insulator.
The method according to claim 1,
The interior and exterior insulation for buildings, characterized in that the first and second foam sheets (10, 20), the bottom surface of each of the CPP reflective film (13, 23) is attached in close contact.
The method according to claim 1 or 2,
The cross-sectional heights of the first and second foam sheets 10 and 20 are 15 to 25 mm including the heights of the protrusions 11 and 21, respectively.
Height of the entire cross section including the first and second foam sheets (10, 20) and the cover sheet 40 is 35 ~ 50mm interior and exterior insulation for buildings.
The method according to claim 3,
A third foam sheet 30 having a CPP reflective film 33 attached to the bottom of the first and second foam sheets 10 and 20 is disposed, and the third foam sheet 30 and the reflection The film 33 has the same shape and the same cross-sectional height as the first and second foam sheets 10 and 20 and the reflective films 13 and 23, respectively.
In the manufacturing method of the insulating material for buildings installed on the inner wall or outer wall of the building to block heat transfer,
After foaming polyethylene resin to prepare a foam sheet, the foam sheet is manufactured by attaching a CPP reflective sheet to the bottom of the foam sheet, and pressing and molding the hemispherical protrusion and the inverted “V” shaped bending portion, respectively. And forming step (S100);
A cover sheet manufacturing step (S200) of applying a molten resin to an upper surface of the nonwoven fabric and then supplying a reflective paper to the upper surface of the nonwoven fabric to which the resin is applied to press the roller with a roller;
After applying the adhesive to the bottom surface of the cover sheet manufactured by the cover sheet manufacturing step (S200), the foam sheet manufactured by the foam sheet manufacturing and molding step (S100) a plurality of times on the bottom surface of the cover sheet Attaching a foam sheet of two layers or three layers to supply the foam sheet attaching step (S300);
Method of manufacturing interior and exterior insulation for buildings, characterized in that consisting of the insulation winding step (S400) for winding the bobbin to facilitate the transport and storage of the insulation sheet prepared by the foam sheet attachment step (S300).
The method according to claim 5,
Resin used for bonding the cover sheet and the nonwoven fabric is a manufacturing method of the interior and exterior insulation for buildings, characterized in that the polyethylene resin.

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