KR20180071908A - Insulation sheet for building and the Insulation sheet manufacturing device - Google Patents

Abstract

The present invention relates to a heat insulation sheet for interior and exterior materials for construction, and a manufacturing apparatus thereof. More specifically, an aluminum foil layer, a glass fiber layer woven with glass fiber yarn as a mesh, a polyester (PET) film layer, and a non-woven fabric layer are bonded in a multi-layer structure, wherein punching holes through which air passes the inside and the outside of the sheet and preventing moisture penetration are formed so as to be attached to various kinds of panels for construction. Thus, the heat insulation sheet has improved incombustibility, sound-absorption property, ventilation property, desiccating property, anti-crease property, crack-prevention property, tensile force, and the like. In addition, a heating and insulating property of the panel is remarkably improved. Since the heat insulation sheet can be simply manufactured by an automatic process, a manufacturing process and operation can be simplified and improved.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat insulating sheet for building interior and exterior,

More particularly, the present invention relates to a thermal insulation sheet for building interior and exterior, and more particularly, to a heat insulation sheet for building interior and exterior, A heat insulating sheet for building interior and exterior, and a manufacturing apparatus therefor, which are formed by joining layers in a multi-layered structure, wherein air is permeated to the inside and outside of the sheet, and pores for preventing moisture permeation are formed.

In general, insulation materials are installed on the inner and outer walls of buildings to minimize heat loss and heat input.

Such a heat insulating material uses a material having a low thermal conductivity, and conventionally, styrofoam or glass fiber, which is cheap in price, is mainly used.

However, the above-mentioned styrofoam is manufactured in a panel form and requires a large cost for logistics. In order to achieve proper heat insulation performance, the styrofoam has to be made thick and difficult to install so as to be exposed to the outside air. Therefore, there were a lot of limitations in use.

In addition, the glass fiber is harmful to the human body and the environment, and thus it has been difficult to use and its use is limited.

In order to solve the problem of the conventional heat insulating material, a plurality of heat insulating sheets have been disclosed in the form of an aluminum film layer for reflecting radiant heat, a protective layer formed of polyethylene or the like, a foamed heat insulating layer and a nonwoven fabric layer, It is easy to transport and install the product, and the insulation effect is superior to the conventional insulation.

However, the above-mentioned conventional heat-insulating sheet is improved in the heat insulation effect, but other characteristics required for construction inside and outside the building such as sound-absorbing property, ventilation property and moisture-proofing property are weak and are provided in roll form, There is a problem that it is difficult to handle due to high risk of tearing or tearing. Therefore, there has been a desperate need for a heat-insulating sheet in which the heat-insulating and heat-insulating performance is greatly improved as a heat-insulating sheet.

Patent Document 1: Registration No. 10-1005542 Patent Document 2: Registered Utility Model No. 20-0218992

Disclosure of Invention Technical Problem [8] The present invention has been made to solve all the problems of the prior art described above, and it is an object of the present invention to provide a multilayer structure in which an aluminum foil layer, a glass fiber layer in which a glass fiber yarn is woven in a network, The air holes are formed on the inner and outer sides of the sheet to prevent water permeation and are used for various construction panels. Therefore, the flame retardancy, sound absorption, breathability, moisture resistance, anti- And the improvement of the heat insulation performance and the commerciality of the product.

The object of the present invention is to provide a heat insulating sheet easily manufactured by an automatic process, thereby providing excellent productivity as well as productivity.

The present invention relates to a laminate film comprising an aluminum foil layer, a PET (polyester) film layer adhered to the lower surface of the aluminum foil layer with an adhesive, a nonwoven fabric layer adhered to the lower surface of the PET film layer with an adhesive, A glass fiber layer formed by weaving a glass fiber yarn in a mesh form between the layers is formed into a multi-layer structure, and air holes are penetrated into the inside and outside of the sheet to prevent water permeation, It is characterized by providing a sheet.

The punched hole according to the present invention is characterized by having a size of 10 to 100 탆.

The glass fiber layer according to the present invention is characterized in that a glass fiber yarn is woven in at least one of a diamond shape, a lattice shape, and a line shape.

The nonwoven fabric layer according to the present invention is characterized in that the nonwoven fabric layer is formed by coating a fire retardant or a flame retardant.

The nonwoven fabric layer according to the present invention is characterized in that it is formed by directly spraying a foamed phenol resin foam to form a panel.

A first adhesive applying unit for applying an adhesive to one surface of the PET film while feeding and feeding the PET film; and a second adhesive applying unit for applying an adhesive to one surface of the PET film, A first drying section for drying the applied adhesive; a glass fiber weaving section for woven glass fiber yarn in a network structure; and a glass fiber weaving fabric woven in a network structure between the PET film and the aluminum foil A primary bonding means composed of a first bonding portion pressed by a press roll and a cooling roll rotating while opposing to each other while feeding and feeding and a first winding roll for winding a bonding material bonded by the first bonding portion;

A nonwoven fabric supply roll on which the nonwoven fabric is wound, a second adhesive for applying an adhesive supplied from the nozzle of the tie die to the other surface of the PET film while feeding and feeding the adhesive paper, A second bonding portion for pressing and bonding the PET film and the nonwoven fabric of the bonding paper to each other by a press roll and a cooling roll which rotate while opposing each other while vertically feeding and feeding the PET film and the nonwoven fabric of the bonding paper; And a second winding means for winding the sheet so as to continuously form perforations along the longitudinal direction of the sheet by rotating a fin roll formed by projecting the perforation pin to an equiangular position on the circumference while supplying the sheet There is provided an apparatus for manufacturing a heat insulating sheet for interior and exterior use.

The present invention relates to a multilayer structure comprising an aluminum foil layer, a glass fiber layer woven with a glass fiber yarn in a net shape, a PET (polyester) film layer and a nonwoven fabric layer in a multilayer structure, It is possible to improve the insulation and insulation performance of the panel as well as to improve the fireproof property, the sound absorption property, the breathability, the moisture proof property, the anti-rust prevention property, the rupture prevention property and the tensile strength, It has an effect of greatly improving the merchantability.

In addition, since the heat insulating sheet can be simply bonded by a two-step automatic process using the first and second sheathing means, it has an excellent productivity as well as an excellent workability.

1 is a perspective view showing a sheet of the present invention;
Fig. 2 is an exploded perspective view of Fig. 1; Fig.
3 is a partial side cross-sectional view of Fig.
4 is a plan view showing an embodiment of the glass fiber layer of the present invention.
5 is a plan view showing another embodiment of the glass fiber layer of the present invention.
6 is a schematic view showing a primary bonding means of an apparatus for manufacturing the present invention;
7 is a configuration diagram showing a secondary bonding means of the manufacturing apparatus of the present invention.
8 is a schematic view showing a second adhering portion of an apparatus for manufacturing the present invention;
9 to 12 are a side view and a plan view showing a glass fiber weaving portion of an apparatus for manufacturing the present invention.
FIG. 13 is a perspective view showing another example of the apparatus for manufacturing the present invention. FIG.
14 is a perspective view showing a width cutting portion of the manufacturing apparatus of the present invention.

First, a thermal insulating sheet for construction and exterior of the present invention will be described.

1 to 4, the heat insulating sheet 10 of the present invention comprises an aluminum foil layer 11, a PET (polyester) film layer 12 adhered to the lower surface of the aluminum foil layer with an adhesive, And a non-woven fabric layer (13) adhered to the lower surface of the PET film layer with an adhesive, wherein a glass fiber yarn is formed between the aluminum foil layer (11) and the PET film layer And a woven glass fiber layer 14 is further formed.

In addition, the heat-insulating sheet 10 is formed with a plurality of perforations 15 for permeating air into the sheet and outside thereof, while preventing moisture permeation and reducing the occurrence of sound-absorbing properties, ventilation, mold and the like, and having antimicrobial properties.

The perforations 15 are formed in a size of 10 to 100 mu m.

Here, the aluminum foil layer 11 is configured to have a thermal reflection characteristic for reflecting radiant heat and a nonflammable characteristic.

The glass fiber layer 14 is formed by forming a glass fiber yarn in a net shape to improve the tensile force of the sheet and improve the appearance of the glass fiber yarn by a pattern of a mesh. Can be woven in a diamond shape, a lattice shape, or a woven fabric in a line, and they are also configured to be woven in various forms mixed with these shapes.

The PET (polyester) film layer 12 is configured to improve moisture resistance, anti-creasing, and rupture strength to prevent moisture penetration of the sheet.

The nonwoven fabric layer 13 may be applied to the nonwoven fabric layer 13 so as to have adhesion or flame retardancy by coating the nonwoven fabric layer 13 with fire-retardant or flame retardant material. Of course.

The adhesive for bonding the aluminum foil layer 11 and the PET film layer 12 is used as a polyurethane adhesive and the adhesive for bonding the PET film layer 12 and the nonwoven fabric layer 13 has a low density It is preferably used as a polyethylene (LDPE) resin adhesive.

The heat insulating sheet 10 of the present invention can be obtained by applying the nonwoven fabric layer 13 to a glass wool, a urethane foam, a building interior / exterior panel foam or the like, or spraying a phenolic resin foam directly onto the nonwoven fabric layer 13, It goes without saying that it may be manufactured and used. At this time, since the foaming of the phenolic resin foam forms an air layer of micropores of 0.2 to 100 탆, the insulating property of the sheet is further improved.

6 to 14, the manufacturing apparatus for manufacturing the heat insulating sheet 10 of the present invention includes an aluminum foil layer 11, a glass fiber layer 14, and a PET (polyester) film layer And a secondary bonding means 200 for bonding the nonwoven fabric 6 to the PET (polyester) film layer 12 again.

The primary bonding means 100 comprises a PET film supply roll 110 on which the PET film 2 is wound, an aluminum foil supply roll 120 on which the aluminum foil 3 is wound, A first drying unit 140 for drying the adhesive applied to the PET film 2, a glass fiber yarn 140 for drying the adhesive applied to the PET film 2, A glass fiber weaving part 150 for woven fabric in a network structure between the PET film 2 and the aluminum foil 3 while feeding and feeding glass fiber woven in a network structure in a laminated manner, And a first wind-up roll 170 for winding the joining paper 5 joined by the first joining portion. The first joining portion 160 is formed by the first joining portion 160 and the first joining portion 160.

9 to 12, the glass fiber weaving unit 150 is formed by continuously moving the engaging concave and convex 151a, which is moved in the form of an endless track on the lower side of the aluminum foil 3, and the glass fiber yarn 9 is caught on both sides A conveying belt 151 and a guide frame 152 in which a number of guide holes 153 for guiding and feeding the glass fiber yarn 9 are formed.

9 and 10, the guide frame 152 may be formed in a ring shape to form a guide hole 153 at an equi-angular position on the circumference thereof, The guide holes 153 may be formed in a line or may be formed in various forms according to the weave shape of the glass fiber yarn.

The secondary bonding means 200 includes a bonding paper feed roll 210 on which the bonding paper 5 bonded by the primary bonding means is wound, a nonwoven fabric supply roll 220 on which the nonwoven fabric 6 is wound, A second adhesive applying unit 230 for applying an adhesive supplied from the nozzles 232 of the tie die 231 to the other surface of the PET film 2 while feeding and feeding the PET film 2 A second bonding portion 240 which is pressed by the press roll 241 and the cooling roll 242 which rotate while opposing each other while feeding and feeding the nonwoven fabric 6 up and down; (250) for continuously forming perforations along the longitudinal direction of the sheet by rotating a fin roll (251) formed by projecting the perforated fin (252) to an equiangular position on the circumference while feeding and feeding the sheet, And a second take-up roll 260 to be taken.

At this time, between the tread 250 and the second take-up roll 260, a width cutting portion 270 for cutting the width of the sheet is further provided, and the width cutting portion 270 is installed below the heat insulating sheet A guide bar 272 provided above the sheet in the width direction of the sheet and a cutter 273 for cutting and operating the sheet while moving along the guide bar to adjust the cutting position of the sheet ).

The guide roll 271a is configured to continuously form the guide groove 271 along the longitudinal direction so that the cutter 273 can be guided to a predetermined cutting position.

The tie die 231 is formed by melt-extruding the LDPE resin chips supplied to the hopper 235 in the extruder 236 and supplying the LDPE resin chips to the inside of the tie die 231, And the adhesive is supplied through the adhesive layer 232 to the surface of the PET film.

Reference numerals denoted by reference numerals 142 denote drying ducts, and 180 and 280 denote guide rolls.

Hereinafter, a manufacturing process and effect of the heat insulating sheet 10 by the manufacturing apparatus of the present invention will be described.

First, the PET film 2 is fed and fed from the PET film feed roll 110 of the primary bonding means 100, and an adhesive (polyurethane adhesive) is applied to one surface of the PET film in the first adhesive application portion 130 Lt; / RTI >

Then, the adhesive is dried in the drying duct 142 of the first drying unit 140.

In this state, the aluminum foil 3 supplied from the PET film 2 and the aluminum foil supply roll 120 is vertically fed to the first bonding portion 160.

At this time, a glass fiber yarn (9) is woven in a network structure between the PET film (2) and the aluminum foil (3) in a glass fiber weave portion (150).

This is because at least one glass fiber yarn 9 wound around the failure is guided to pass through the guide hole 153 of the guide frame 152 so as to form a delicate image on the conveyance belt 151 moving in an endless track form, It is woven in structure.

9 and 10, the glass fiber yarn 9 passing through the guide hole 153 of the ring-shaped guide frame 152 is engaged with the engaging concavities 151a on both sides of the conveyor belt 151, The glass fiber yarn is woven in a rhombic shape by the conveyance of the conveyance belt 151 and the rotation of the guide frame 152.

At this time, the glass fiber yarn located below the conveyance belt 151 is cut after weaving, and is dropped downward, and the glass fiber yarn 9 positioned on the conveyance belt is transferred between the PET film 2 and the aluminum foil 3 Is supplied.

11 and 12, the glass fiber yarns 9 passing through the guide holes 153 of the flat guide frame 152 are transferred in a line on the conveyor belt 151, And the glass fiber yarn 9 woven in the rhomboidal shape of FIG. 10, so that it is possible to provide a woven structure as shown in FIG. 4 and also to provide various woven structures such as a lattice form as shown in FIG. 5 will be.

The PET film 2, the glass fiber yarn 9 of the mesh structure, and the aluminum foil 3 are stacked between the press rolls 161 and the cooling rolls 162, which are opposed to each other in the first adhesive portion 160, And they are bonded to each other by an adhesive while being transferred.

As described above, the bonding papers 5 joined at the first bonding portion are wound by the first winding roll 170.

The joint paper 5 of the first wind-up roll is dried in a drying chamber (not shown) until the adhesive is completely dried.

After the drying process, the secondary bonding process is performed by the secondary bonding device 200 again.

That is, an adhesive (a low density polyethylene (LDPE) resin adhesive agent) supplied from the nozzle 232 of the tie die 231 to the upper surface of the PET film 2 of the bonding paper 5 fed and fed from the bonding paper feed roll 210 ).

The nonwoven fabric 6 fed and fed from the bonding papers 5 and the nonwoven fabric supplying rolls 220 is pressed and pressed between the pressing roll 241 and the cooling roll 242 which are rotated opposite to each other of the second bonding portion 240 So that the heat-insulating sheet 10 can be manufactured.

The heat insulating sheet 10 according to the present invention thus produced is continuously fed and supplied while the pin roll 251 of the tread 250 rotates to form a perforation pin 252 protruding to an equiangular position on the circumference of the fin roll The perforations 15 are formed at regular intervals along the longitudinal direction.

After the punching up of the sheet is completed, the width cut portion 270 cuts the width size according to the sheet application.

This is because the heat insulating sheet 10 to be guided to the upper portion of the guide roll 271 is cut by the upper guide bar 272 by a cutter 273 which is positioned in the width direction of the sheet and cut to a proper width size .

The sheet thus cut is wound around the second wind-up roll 260 and the heat-insulating sheet 10 is completed.

1 and 2, the heat-insulating sheet 10 of the present invention manufactured as described above can be used as an aluminum foil layer, a glass fiber layer in which a glass fiber yarn is woven into a network, a PET (polyester) film layer, The nonwoven fabric layer is bonded to the various construction panels by forming pores for joining the nonwoven fabric layer in a multilayer structure to prevent air permeation and moisture permeation to the inside and outside of the sheet. As well as the heat insulation and heat insulation performance of the panel are greatly improved.

10: thermal insulation sheet 11: aluminum foil layer
12: PET (Polyester) film layer 13: Nonwoven fabric layer
14: glass fiber layer 15: perforation
100: primary bonding means 110: PET film supply roll
120: aluminum foil supply roll 130,230: first and second adhesive application parts
140: first drying section 142: drying duct
150; Glass fiber weaving part 160,240: First and second adhesive parts
161, 241: push roll 162, 242:
170, 260: first and second winding rolls 200; Secondary bonding means
210: Feedstock Feed Roll 220: Nonwoven Feed Roll
231: Tee dies 232: Nozzles
250: tread 252: perforated pin

Claims (8)

A polyester film layer 12 adhered to the lower surface of the aluminum foil layer with an adhesive; a nonwoven fabric layer 13 adhered to the lower surface of the PET film layer with an adhesive; A glass fiber layer 14 in which a glass fiber yarn is woven in a mesh form is formed between the foil layer 11 and the PET film layer 12 in a multilayer structure,
Wherein the pores (15) are formed so as to transmit air through the sheet and prevent moisture from permeating through the sheet.
The method according to claim 1,
Wherein the perforations (15) are formed in a size of 10 to 100 mu m.
The method according to claim 1,
Wherein the glass fiber layer (14) is formed by weaving a glass fiber yarn in at least one pattern of a diamond shape, a lattice shape, or a line shape.
The method according to claim 1,
Wherein the nonwoven fabric layer (13) is formed by coating a fireproof or flame retardant material.
The method according to claim 1,
Wherein the nonwoven fabric layer (13) is formed by spraying a foamed phenol resin directly to form a panel.
A first adhesive applying unit 130 for applying an adhesive to one surface of the PET film while feeding and feeding the PET film, a PET film supply roll 110 for winding the PET film, A first drying unit 140 for drying the adhesive applied to the PET film 2, a glass fiber weaving unit 150 for woven glass fiber yarn into a network structure, A first bonding portion (first bonding portion) which is pressed by the pressing rolls 161 and the cooling rolls 162, which are opposed to each other while feeding and feeding the glass fiber yarns woven in a network structure between the first bonding portion 2 and the aluminum foil 3, (160), and a first winding roll (170) for winding the joining paper (5) joined by the first joining portion;
A nonwoven fabric supply roll 220 on which the nonwoven fabric is wound, and a non-woven fabric supply roll 220 which is provided on the other surface of the PET film while feeding the bonding paper, A second adhesive applying unit 230 for applying an adhesive supplied from a nozzle 232 and a press roll 241 and a cooling roll 242 which are rotated counter to each other while vertically feeding and feeding the PET film and the nonwoven fabric of the bond paper And a pin roll 251 formed by projecting the perforated pin 252 to an equiangular position on the circumference while feeding and feeding the sheet bonded by the second adhering portion is rotated And a secondary winding means (200) composed of a tread (250) for continuously forming perforations along the longitudinal direction of the sheet and a second winding roll (260) for winding the sheet. A device for manufacturing a sheet.
The method according to claim 6,
The glass fiber weaving unit 150 includes a conveyance belt 151 for continuously forming the engaging concave and convex 151a on both sides of the aluminum foil 3 in the form of an endless track at the bottom of the aluminum foil 3, And a guide frame (152) formed with a plurality of guide holes (153) for supplying the guide holes (153).
The method according to claim 6,
The secondary bonding means 200 further includes a width cutout portion 270 for cutting the length of the sheet between the tread 250 and the second takeup roll 260, A guide bar 272 installed at a lower portion of the sheet and guiding the sheet to convey the sheet, a guide bar 272 provided in the width direction of the sheet at the upper portion of the sheet, And a cutter (273) for cutting operation.

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