KR200419677Y1 - Heat protecting material coated aluminium and scratched - Google Patents

Abstract

The present invention relates to an aluminum coating insulation material having a power cut function to reduce safety accidents such as fire and electric shock due to a short circuit through an aluminum coating insulation material applied to increase heating efficiency when heating a building. In the aluminum coating heat insulating material having a heat reflection coating layer of aluminum material for heat reflection on the upper surface of the foamed heat insulating material layer, the heat reflection coating layer is coated with an aluminum diluent in which a powdered aluminum dilution is applied to one side of the thin film The coating layer is formed, but the aluminum coating layer is characterized in that the scratching process is performed to break the bonding relationship between the aluminum particles located on both sides of the scratch line.

Aluminum Coating Insulation, Heat Reflective Coating, Scratch

Description

Heat protecting material coated aluminum and scratched}

1 is a view for explaining a heating system to which a heating cable is applied.

2 is a view for explaining a heating system to which a film heater is applied.

Figure 3 is a view for explaining the aluminum coating insulation according to the prior art.

Figure 4 is a perspective view of the aluminum coating insulation formed by the present invention.

5 is a view for explaining a process of manufacturing a heat reflection coating layer of the present invention.

6 is a perspective view of an aluminum coating heat insulating material according to another embodiment of the present invention.

7 is a view for explaining the manufacturing process of the aluminum coating insulation of the present invention.

8 is a view showing an electric heating system to which the aluminum coating insulation according to the present invention is applied.

 ※ Explanation of code for main part of drawing

10: foundation concrete layer 12: finishing materials

14: heat source 30, 40: aluminum coating insulation

31,41: insulation layer 42: pressure line

43: embossing 44: air layer

50: heat reflection coating layer 51: thin film

52: aluminum coating layer 53: scratch line

The present invention relates to an aluminum coating insulation material having a power cut function, and more particularly, to reduce safety accidents such as fire and electric shock due to a short circuit through an aluminum coating insulation material applied to increase heating efficiency when heating a building. It relates to an aluminum coating insulation having a power cut function for.

The heating system applied to a general building includes a boiler heating system for circulating a heated fluid through a pipe, and an electrical heating system for converting electrical energy into thermal energy by applying a current to a heating cable or a film heater.

In particular, the electric heating system is a situation that the application is gradually increasing because the construction process is simpler and thinner than the boiler heating system, as well as the maintenance cost and maintenance costs are lower in the operation process.

1 is a view illustrating a heating system to which a heating cable is applied. Insulating the upper surface of the foundation concrete layer 10 in the process of constructing the heating system by the heating cable 14a on the upper side of the foundation concrete layer 10 is performed. Aluminum coating insulation for 20 is laid. In addition, the mesh body 18 is constructed in a shearing system for wiring the heating cable 14a on the upper portion of the aluminum coating insulation 20. On the upper side of the mesh body 18, the plaster finishing layer 16 is constructed in the state in which the heating cable 14a was wired in the zigzag direction, and heating construction is completed. On the other hand, on the upper side of the plaster finish layer 16 by using a finishing material 12, such as mono- nium, reinforced floor, tiles, deco tiles and the like to create an atmosphere suitable for the place.

FIG. 2 is a view for explaining a heating system to which a film heater is applied, and an aluminum coating insulation 20 is laid on the upper surface of the foundation concrete layer 10 before constructing the film heater 14b. The upper surface of the film heater 14b placed on the heat insulating material 20 is covered with a protective film 17 made of vinyl. And the upper side of the protective film 17 by using a finish 12, such as mononium, reinforced floor, tiles, deco tiles and the like to create an atmosphere suitable for the place.

FIG. 3 is a view showing an aluminum coating heat insulating material 20 which is being constructed in a conventional electric heating system, in which a synthetic resin raw material (sponge, soft urethane, styrofoam, etc.) is foamed to a predetermined thickness (about 5 mm). On the upper surface of 21, a heat reflection coating layer 22 is formed so that the heat radiated from the heating cable and the film heater, which are heat sources, is reflected to the upper side. As the heat reflection coating layer 22, a thin plate made of aluminum is mainly used, and a thin plate-shaped aluminum prepared in advance is pressed onto the heat insulating material layer 21 to form an aluminum coating heat insulating material 20.

However, when the aluminum coating insulation manufactured according to the prior art is applied to the construction of the electric heating system, the heat reflectance is excellent and the heating efficiency is greatly increased. However, when the short circuit occurs in the heating cable or the film heater, the aluminum material is used. Due to the current through the heat-reflective coating layer made there was a disadvantage that may cause a fire or electric shock.

Therefore, the present invention has been devised to supplement the disadvantages of the aluminum coating insulation according to the prior art as described above, due to the short circuit through the aluminum coating insulation applied for the increase of the heating efficiency during the heating construction of buildings, fire, electric shock It is an object of the present invention to provide an aluminum coating insulation having a power cut function to reduce safety accidents such as accidents.

The object of the present invention described above, in the aluminum coating heat insulating material formed of a heat reflection coating layer of aluminum material for heat reflection on the upper surface of the heat insulating material layer foamed to a predetermined thickness, the heat reflection coating layer is powder on one side of the thin film The aluminum dilution solution of which aluminum is diluted is applied to form an aluminum coating layer, and the aluminum coating layer is scratched to break the bonding relationship between the aluminum particles located at both sides of the scratch line. It is achieved by providing an aluminum coating insulation having a power cut function.

According to a preferred feature of the present invention, the thin film is formed of one of polyethylene terephthalate (PET) deposited film, OPP deposited film and CPP deposited film.

According to a more preferable feature of the present invention, a lattice-type pressing line is formed in the process of fusing the heat reflection coating layer to the heat insulating material layer so that a plurality of embossing is formed on the aluminum coating layer.

According to a more preferable feature of the present invention, the scratch lines formed on the aluminum coating layer are formed in the transverse direction and the longitudinal direction, respectively.

Hereinafter, with reference to the accompanying drawings, preferred embodiments according to the configuration and operation of the aluminum coating insulation according to the present invention will be described in detail.

Figure 4 is a perspective view of an aluminum coating heat insulating material formed by one embodiment of the present invention, Figure 5 is a view for explaining the process of manufacturing the heat reflection coating layer according to the present invention, Figure 6 is another embodiment of the present invention Figure 7 is a perspective view of the aluminum coating insulation formed by, Figure 7 is a view for explaining the manufacturing process of the aluminum coating insulation according to the present invention, Figure 8 is a view showing the electric heating system applied aluminum coating insulation according to the present invention.

Reference numeral 30 shown in the drawing indicates an aluminum coating insulation formed by one embodiment of the present invention, 40 indicates an aluminum coating insulation formed by another embodiment of the present invention.

The aluminum coating insulation 30 is interposed between the heat source 14, such as heating cable or film heat and the base concrete layer in the process of constructing the heating system of the building and the heat insulating function between the upper and lower sides of the aluminum coating insulation 30 In addition, the function of radiating the heat transferred from the heat source 14 to the heat reflection coating layer 50 to be directed back to the heat source side is the same as in the aluminum coating insulation according to the prior art. By the way, the aluminum coating heat insulating material 30 according to the present invention is formed so that the current through the heat reflection coating layer 50 coated with aluminum is blocked.

That is, even if a current leakage through the heat source 14 is somewhat generated, the heat reflection coating layer 50 in order to be able to suppress the occurrence of electric shock accident or fire through the aluminum-coated insulating material 30 widely laid on the foundation concrete layer 10 Although formed of aluminum, which is a metallic material, current is formed so as not to be conducted.

In order to form the heat reflection coating layer 50 having a short-circuit function to block the flow of current, the thin film 51 is coated with a diluting solution in which fine aluminum powder particles are diluted.

The thin film 51 may be formed of a polyethylene terephthalate (PET) deposition film, an OPP deposition film uniaxially or biaxially stretched polypropylene (PP), or a CPP (casting polypropylene) deposition film not stretched polypropylene (PP). have.

In this way, the aluminum coating layer 52 applied to the thin film 51 is subjected to a scratching process using a separately formed scratcher. The scratch line 53 formed by the scratching process by the scraper breaks the bonding relationship between the particles of the aluminum coating layer 52 located on both sides of the scratch line 53 as shown in the partially enlarged view of FIG. 4. do. Therefore, the flow of current is blocked between the aluminum coating layers on both sides based on the scratch line 53, so that the overall heat reflection coating layer 50 has an effect of becoming an insulator.

The distance between the scratch lines 53 formed by the scraper does not have to be constant, and may be formed only in the horizontal direction or the vertical direction, and may be formed in both the horizontal direction and the vertical direction. The scraper may be a roller type or a cutter type.

As shown in the figure, in order to break the aluminum particles on both sides when the scraper line 53 is formed, the bonding relationship between the aluminum particles is broken, but the thin film 51 has to be applied with a shearing force such that the shear force is not cut. Skill is needed.

On the other hand, the heat reflection coating layer 50 produced by the process as described above is heat-sealed on one side of a separate heat insulating material layer formed (foaming, synthetic resin raw material (sponge, soft urethane, styrofoam, etc.)).

In the process of thermally fusion bonding the heat reflection coating layer 50 to the heat insulating material layer 31, the same heat and pressure are applied to the entire surface of the heat reflection coating layer 50 formed through the above-described process, and the bonding portion thereof is shown in FIG. It can be made in the form of a smooth surface. On the other hand, in the process of thermally bonding the heat reflection coating layer 50 and the heat insulating material layer 41, when a relatively strong heat and pressure is applied to a section forming a lattice shape at a predetermined interval, the joining portion is changed in strength and pressurized line 42 is formed to obtain an aluminum coating heat insulating material 40 having a structure in which the embossing 43 is formed on the heat reflection coating layer 50 as shown in FIG. 6. In addition, the embossed structure may be applied to the bottom surfaces of the heat insulation layers 31 and 41.

The reason for the embossing to be formed on the surfaces of the aluminum coating insulation (30, 40) is to improve the thermal insulation performance by forming an air layer between the members located on the upper and lower sides during the construction of the heating system.

The operation of the aluminum coating insulation according to the present invention will be described below by taking the case where the aluminum coating insulation configured as described above is applied at the time of construction of the electric heating system.

In the process of constructing an electric heating system of a building, an aluminum coating insulation material 30 and 40 formed by the present invention is interposed between a heating cable or a film heater, which becomes the base concrete layer 10 and the heat source 14. When the film heater is applied as the heat source 14, the film heater is interviewed on the upper surfaces of the aluminum coating insulation (30, 40), when the heating cable is applied, the mesh body between the heating cable and the aluminum coating insulation (30, 40) 18 may be located.

However, in the electric heating system constructed as described above, a phenomenon may occur in which an electric current flows due to residual electricity or an electric leakage. In this way, the electric current flowing from the heat source is widely spread in the basic concrete layer 10. 40).

However, since numerous scratch lines 53 are formed in the aluminum coating insulation materials 30 and 40 formed according to the present invention, the bonding relationship between the aluminum particles located at both sides of the scratch line 53 is increased. It is disconnected and the flow of current is not allowed.

Therefore, the electric leakage through the heat reflection coating layer of the aluminum coating insulation according to the prior art is to be expanded to give a safety accident such as a fire or an electric shock.

In addition, by the formation of the air layer 44 by the pressure line 42 provided in the heat reflection coating layer 50, the heat insulating performance of the aluminum coating heat insulating material 40 can be improved. In particular, in the case of the electric heating system to which the film heater is applied, the heat insulating material and the film heater are in a state of being interviewed with each other, and the air layer also functions to prevent a phenomenon such that both members stick to each other.

According to the aluminum-coated heat insulator constructed by the present invention as described above, a plurality of scratch lines are formed on the heat reflection layer coated with aluminum on one side of the heat insulator, the current caused by the leakage current in the heating cable or film heater of the electric heating system Even though it is flowing, there is a big advantage that can reduce the safety accidents such as the occurrence of fire or electric shock through the aluminum-coated insulation spread over the entire surface of the foundation concrete layer.

Claims (4)

In the aluminum coating heat insulating material formed with a heat reflection coating layer of aluminum material for heat reflection on the upper surface of the heat insulating material layer foamed to a predetermined thickness, The heat reflection coating layer is coated with an aluminum diluent in which powdered aluminum is diluted on one side of the thin film to form an aluminum coating layer, and the aluminum coating layer breaks the bonding relationship between the aluminum particles located on both sides of the scratch line. An aluminum coating insulation material having a power cut function, characterized in that the scratching process is carried out to ensure the power cut. The method of claim 1, The thin film is an aluminum coating heat insulating material having a power failure function, characterized in that formed of one of the PET deposition film, OPP deposition film and CPP deposition film. The method according to claim 1 or 2, An aluminum coating heat insulating material having a power dissipation function, characterized in that the lattice pressure line is formed in the process of fusing the heat reflection coating layer to the heat insulating material layer so that a plurality of embossing is formed on the upper side of the aluminum coating layer. The method of claim 3, wherein Scratch lines formed on the aluminum coating layer is an aluminum coating heat insulating material having a power failure function, characterized in that each formed in a horizontal direction and a vertical direction.

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