KR20140001183A - The insulator and the same method - Google Patents

Abstract

Provided is an insulation body (1150) capable of fundamentally preventing a heat reflection film from being contaminated due to external air and including excellent insulation properties by being formed with a plurality of spherical insulation unit bodies (250). The insulation unit body (250) is formed in an assembly of the insulation unit body including a spherical film member (110) including a sealed space unit inside and a partial heat reflection film (120) formed in a dome shape at a part of the inner surface of the film member. Argon gas is injected into the inner space of the insulation unit body.

Description

Insulator and its manufacturing method {The insulator and the same method}

The present invention relates to a heat insulator, and more particularly, to provide a heat insulator composed of a plurality of heat insulators, which is excellent in heat insulation properties and does not fundamentally cause contamination of the heat reflection film by outside air.

In the field of construction, various studies have been made to increase the insulation efficiency. As an example, the publication of Patent Publication No. 10-2013-110123 (published on Oct. 8, 2013), which was developed and filed by the applicant of the present invention, includes a concrete coating material 10 having a space therein and the entire inner peripheral surface of the space. The heat insulator 150 is formed by wrapping the heat insulation unit 50 made of the heat reflection film 20 coated on the outer skin 16.17.

When the heat ray 39 is incident and transmitted from the outside, the heat insulation unit 50 of the spherical shape constituting the conventional heat insulator 150 is diffusely reflected in the spherical internal space by the heat reflection film 20 to obtain the heat ray. Since the heat trap 39 is trapped in the internal space of the body shape and is trapped, it is difficult to radiate heat through the heat insulating unit.

Because of the above reasons, the thermal insulation effect is improved on the boundary between the thermal insulation units 50, and even though a long time passes, the internal space of the thermal insulation unit is blocked from being exposed to polluted outside air, thereby preventing the reflection efficiency from decreasing. .

Applicant of the present invention is to produce a sample in a variety of forms including the insulating unit 50 of the conventional structure in the process of testing the insulating unit is a heat insulating unit structure more excellent than the heat insulating film coated structure on the inner front surface of the heat insulating unit. Newly developed.

Domestic Patent Publication No. 10-2013-110123

The present invention has been made in view of the prior art by forming a partial heat reflection film in a hemispherical shape in the interior space of the heat insulation unit, and by arranging a plurality of heat insulation units so that the partial heat reflection film is arranged in the same direction, it is possible to improve the heat insulation effect It is an object to provide an insulator.

Another object of the present invention is to partially coat the heat reflection film on a portion of the inner peripheral surface of the heat insulating unit made of a spherical or hemispherical shape so that the heating wire incident on the heat insulating unit is irregularly reflected in one direction in the inner space of the spherical or hemispherical shape. By induction, some heat is trapped in the sphere space, and some heat is intended to provide an insulator that can maximize the heat insulation and heat insulation effect by allowing the heat wire to be efficiently discharged to the incident side.

It is also an object of the present invention to provide an insulator that can be used interchangeably in various places such as home appliances such as clothes, automobiles, refrigerators, industrial plants, and construction fields, and is easy to install and apply.

Moreover, an object of the present invention is to provide a heat insulator in which the efficiency of heat reflection and heat insulation does not decrease even after long-term use.

In addition, it is an object to provide a heat insulator that does not need to install a separate vent in the heat insulating body by allowing the space between the space of the heat insulating units to act as a vent of the outside air.

In order to achieve the above object, the heat insulator of the present invention comprises an aggregate of heat insulating units having a spherical or hemispherical coating material having an enclosed space therein and a partial heat reflection film formed in a portion of an inner surface of the coating material in a dome shape. It is characterized by.

The partial heat reflection film may be arranged in the same direction.

The partial heat reflection film may be formed in a hemispherical shape.

In addition, at least one surface of the outer surface of the aggregate of the heat insulating unit is characterized in that the outer shell is configured.

Insulating method of the present invention comprises the steps of preparing a first sheet formed with a plurality of dome structure having a hemispherical recess,

Forming a heat reflection film inside the recess of the first sheet;

Preparing a second sheet on which a heat reflection film is not formed on a side facing the recess of the first sheet,

Bonding the first sheet and the second sheet so that at least the recess of the first sheet forms an enclosed interior space.

Further, the second sheet has a dome structure having a plurality of hemispherical recesses, and the dome structure of the first sheet on which the heat reflection film is formed and the dome structure of the second sheet correspond to each other to form a spherical sealed inner space. Characterized in that configured to form.

The first sheet and the second sheet are made of vinyl, and the partial heat reflection film is made of an aluminum film.

The heat insulating units constituting the heat insulator of the present invention form a partial heat reflecting film formed in a domed shape on a part of the inner surface of the spherical or hemispherical coating material having a closed space portion, thereby insulating the heat insulating film in the entire inner circumferential surface thereof. And an excellent heat insulating property can be obtained.

Partial coating of the heat-reflective film induces heat rays incident to the adiabatic unit to be constrained irregularly in one direction in the spherical or hemispherical inner space part, so that some heat is trapped in the spherical space and some heat Efficient discharge to the side can be obtained to further improve the limit of heat conduction and movement to one side based on each insulation unit.

Even after long-term use after installation, the thermal insulation efficiency does not decrease, and even if some of the plurality of thermal insulation units are damaged, the thermal insulation function of the thermal insulator may not be significantly reduced.

1 is a cross-sectional view of a conventional heat insulator,
2 is a cross-sectional view of a conventional insulating unit
3 is a three-dimensional view showing an example of the heat insulator of the present invention,
4 is a partial cross-sectional view along the line AA of FIG.
5 is a three-dimensional view showing another example of the heat insulator of the present invention,
6 is a partial cross-sectional view along the line BB of FIG. 5,
7 is a schematic diagram of a test chamber for testing a conventional thermal insulation unit,
8 is a simulated three-dimensional view showing the movement of heat in a conventional singular insulation unit;
9 is a graph showing the movement of heat in a conventional singular insulation unit,
10 is a simulation three-dimensional view showing the movement of heat in a plurality of heat insulating units of the prior art,
11 is a schematic diagram of a test chamber for testing an insulating unit of the present invention,
12 is a simulation three-dimensional view showing the movement of heat in the singular insulation unit of the present invention,
Figure 13 is a graph showing the heat transfer in the singular insulation unit of the present invention,
14 is a simulation three-dimensional view showing the movement of heat in the plurality of thermal insulation units of the present invention,
15 is a cross-sectional view showing another example of the insulator of the invention,
It is sectional drawing which shows the other example of the heat insulating body of this invention.

Hereinafter, the technical configuration and operation of the heat insulator of the present invention will be described in detail with reference to FIGS. 3 to 16.

3 and 4, the heat insulator 1150 of the present invention is composed of a set of heat insulating units 250 coated with a partial heat reflection film 120 in a sealed space.

The thermal insulation unit 250 may be formed as an integral type of an independent sphere by forming a coating material 110 of the same material and a domed partial heat reflection film 120 formed in a hemispherical shape by coating or the like in the inner space of the coating material. have. The diameter of the heat insulation unit 500 is preferably configured to be 2 ~ 35mm but is not limited to this size can be used by appropriately changing the size according to the use conditions.

The spherical thermal insulation unit 250 forms a partial heat reflection film 120 on the inner circumferential surface of the spherical coating material 110 made of a synthetic resin, such as transparent plastic, or a transparent vinyl material. The thickness of the coating material 110 is 0.1 ~ 0.2mm, the partial heat reflection film 120 may be configured by coating an aluminum film 0.005 ~ 0.01mm thickness, the coating material using a well-known transparent flame retardant material that does not burn well Or it may be composed of a material mixed with a transparent flame retardant material.

After the divided heat reflection film 120 is formed, or in the forming process, the inner space of the spherical shape is sealed to completely block the outside air. The sealed spherical inner space may be formed to fill the atmosphere at a predetermined pressure, or may be sealed by injecting argon gas having a lower thermal permeability than the general atmosphere.

When the heat ray 39 is incident and transmitted from the outside of the heat insulation unit into the heat insulation unit, the heat insulation unit 250 configured as described above is diffusely reflected by the partial heat reflection film 120 in the spherical inner space to enter the heat ray. Partly trapped and trapped in the internal space of the body shape, and part of the heat is transmitted through the portion where the partial heat reflection film is not formed to radiate toward the incident side. Therefore, the thermal insulation property is improved while maintaining the thermal insulation unit 250 at the boundary.

Since the thermal insulation unit 250 of the present invention prevents the internal space of the thermal insulation unit from being exposed to contaminated outside air even after a long time passes after installation, the reflection efficiency of heat does not decrease permanently in the internal space of the spherical shape. There is.

Each of the insulation units 250 may be manufactured in an independent complete spherical shape, but in consideration of manufacturing costs, the insulation unit 250 may be configured of an insulation unit 1150 formed of a set of insulation units 250 as shown in FIG. 3.

In the method of manufacturing the heat insulator 1150 of FIG. 3, the method includes preparing an upper coating material 110 made of 0.1 mm thick transparent vinyl having a dome structure having a hemispherical recess.

Subsequently, forming a partial heat reflection film 120 by coating a 0.006 mm thick aluminum in a hemispherical shape inside the recess of the upper coating material 110,

Subsequently, preparing a lower coating material 110 of 0.1 mm thick transparent vinyl having a dome structure having a hemispherical recess,

Subsequently, the upper coating material 110 on which the partial heat reflection film is formed and the dome structure of the lower coating material 110 correspond to each other to form a spherical sealed inner space.

The heat insulator of the present invention is not limited to the structure of FIGS. 3 and 4, and the heat insulation unit 350 and the heat insulator 2150 may be configured in the same structure as in FIGS. 5 and 6.

6 and 6, the insulating unit 350 is formed in a hemispherical shape using the transparent vinyl coating material 210, and a partial heat reflection film 220 made of aluminum is formed on the inner surface of the hemispherical shape by coating or the like. Thereafter, the flat coating material 310 made of transparent vinyl is bonded to each other. The heat reflection film is not formed on the side where the coating material 210 and the flat coating material 310 are bonded to each other.

The heat insulator of the present invention is omitted, but may be formed in a structure of mixing the spherical heat insulation unit 250 or the hemispherical heat insulation unit 350, or may be configured by mixing the diameters in various ways. In the case of a structure in which the spherical heat insulation unit 250 and the hemispherical heat insulation unit 350 are mixed or have a structure having various diameters, the pattern of the partial heat reflection film is preferably configured to be disposed in the same direction.

The heat insulator 1150 is formed in a single layer as shown in FIG. 15 and is wrapped and supported by the outer shells 16 and 17, or as shown in FIG. It can be configured as.

In Figs. 15 and 16, the sheaths 16 and 17 can be supported on only one side, and the sheaths 16 and 17 are made of sheet material such as styrofoam, wood plywood, nonwoven fabric, woven synthetic fiber, fabric made of natural fiber, and the like. Can be used.

Insulation of the present invention has the advantage that the space between the sphere or hemispherical insulation unit can act as a vent to the outside air, greatly improving the efficiency of the installation work of the insulation structure, bend freely or It can be folded for compatibility with curved wall spaces.

In addition, even if a part of the thermal insulation unit is damaged, most other thermal insulation units do not have any effect on the function, and thus do not need to be repaired separately, and do not greatly affect the thermal insulation efficiency.

(Comparison of Insulation Characteristics of Insulation Units of Conventional Structures and Insulation Units of the Present Invention)

Hereinafter, the characteristics of the thermal insulation unit of the conventional structure and the thermal insulation unit of the present invention are compared with reference to FIGS. 7 to 14.

First, a sample of the heat insulating unit 50 having a conventional structure as shown in FIG. 7 was prepared and set in the test chamber 500.

The heat insulating unit 50 of the conventional structure is composed of a coating material 10 made of 0.1 mm thick transparent vinyl in a spherical shape, and coated with an aluminum film having a thickness of 0.006 mm on the entire inner space of the spherical shape to form a heat reflection film 20. Formed. The outer diameter of the thermal insulation unit 50 was formed to 30mm.

The test chamber 500 is composed of a cube having an internal space of about 30 mm × 30 mm × 30 mm in volume, and the remaining four surfaces except for the first surface 501 located in the direction of entry of the heating wire, and the second surface 502 facing the first surface. Silver is composed of shielding films 503 through which the hot wire is not transmitted or emitted. The first surface 501 and the second surface 502 were composed of a polyester double board having a thickness of 3 mm and a conductivity of λ = 0.027 W / mk.

The conventional insulation unit 50 is set in the chamber between the first surface 501 and the second surface 502 of the test chamber 500 configured as described above, and the first surface 501 is 20 ° C., The side 2 of the side 502 was shielded from outside and set to maintain 0 ° C., and then the temperature change was measured for 1 day at the points ①, ②, ③, and ④ using a comsol multiphysics simulation program.

Subsequently, the thermal insulation unit 250 of the present invention is manufactured by the same method, the same conditions, and the same size in order to compare the characteristics with the thermal insulation unit of the conventional structure, and then the test chamber 500 of the same condition as shown in FIG. The thermal insulation unit 250 was set, and the temperature change was measured for about 1 day at the ①, ②, ③ and ④ points. However, the heat insulation unit 250 of the present invention is disposed such that the partial heat reflection film 120 is located on the second surface side facing the first surface 501.

The spherical inner space of the heat insulation unit 50 and the heat insulation unit 250 of the present invention were manufactured to have the same pressure at room temperature at atmospheric pressure.

As a result of measuring the temperature change under the above conditions, the thermal insulation unit 50 of the conventional structure is heated to the inner space of the thermal insulation unit 50 for 8000 seconds (about 2 hours) as can be seen in the simulation stereoscopic diagram of FIG. 8. It can be seen that the diffusion movement is relatively active and the heat dissipation toward the second surface 502 based on the adiabatic unit 50 does not occur relatively large.

On the other hand, as can be seen in the simulation three-dimensional view of FIG. 12, the heat insulation unit 250 according to the present invention has a significant heat diffusion movement compared to FIG. 8 in the internal space of the heat insulation unit 50 for 8000 seconds (about 2 hours). It can be seen that the heat dissipation toward the second surface 502 based on the thermal insulation unit 250 hardly occurs.

 In FIG. 8 and FIG. 12, the darkest red portion represents the region approaching 20 ° C., and the temperature region becomes lower toward the darkest blue portion.

That is, it can be seen that the heat insulating unit 250 of the present invention is significantly superior in heat insulating properties compared to the heat insulating unit 50 of the conventional structure.

In addition, when comparing the graph showing the heat movement in the conventional heat insulation unit 50 of FIG. 9 with the graph showing the heat movement in the heat insulation unit 250 of the present invention of FIG. For 10,000 seconds (about 3 hours), the temperature change with respect to time rises to about 14 ° C. in FIG. 9, and shows a pattern that rises to 16 ° C. in FIG. 12, because in FIG. 12, in the thermal insulation unit 250. This is because part of the reflected heat is released toward the first surface 501 through the coating material without the heat reflection film.

However, it can be seen that the temperature change is markedly different at the ②, ③ and ④ points of both graphs.

At points ② and ③ of both graphs, FIG. 9 shows that the temperature rises to 10 ° C. for 10,000 seconds (about 3 hours), and to 6 ° C. at point ④ and afterwards for 80,000 seconds (about 1 day). It can be seen that the temperature remains constant without change, and FIG. 12 shows that the temperature rises to 7 ° C. for 10,000 seconds (about 3 hours), and the temperature rises only to 2 ° C. at the point ④ thereafter, after about 1 day without any further temperature change. It can be seen that while being kept constant.

As can be seen from the graphs of FIGS. 9 and 12, at the points ②, ③, and ④, the graph of FIG. 12 has a lower peak temperature than the graph of FIG. 9 and maintains a relatively low temperature for about one day. You can check it.

In addition to the above experiments, it was confirmed that the thermal insulation units of the prior art and the present invention were placed in double, respectively, in the test chambers 500 having different sizes as shown in FIGS. .

As can be seen from the above experimental results, it was confirmed that the heat insulating unit 250 of the present invention, in which the heat reflection film was partially formed in the hemispherical shape, was better than the structure in which the heat reflection film was formed on the inner front surface.

The cause is that the heat rays incident to the adiabatic unit by the dome-type partial heat reflection film are induced to be constrained to be diffusely reflected in one direction from the inner space of the spherical shape so that some heat is retained in the spherical space. This is because it is reflected and emitted to the side where the hot wire is incident, that is, to the side where the heat reflection film is not formed.

When the thermal insulation unit of the present invention is configured in a spherical form, even if the coating area of the partial heat reflection film 120 is coated by about 60-70% over the hemispherical region, or only about 40% without over the hemispherical region It is believed that the same result will be obtained.

The present invention is not limited to the above description and illustrated, and may be variously modified within the scope of the claims and the invention.

10,110,210,310-Encapsulant
16,17-sheath
20,120,220-heat reflecting film
39-heating wire
50,250,350-insulation unit
150,1150,2150-insulation structure

Claims (7)

A heat insulating body comprising an aggregate of a heat insulating unit having a spherical or hemispherical coating material having a sealed space therein and a partial heat reflection film formed in a portion of an inner surface of the coating material in a dome shape. The method of claim 1,
The partial heat reflection film 120 is insulated, characterized in that arranged in the same direction. The method of claim 1,
And the partial heat reflection film is formed in a hemispherical shape. 4. The method according to any one of claims 1 to 3,
At least one surface of the outer surface of the aggregate of the heat insulating unit 250 is characterized in that the outer shell is configured. Preparing a first sheet having a plurality of dome structures having hemispherical recesses,
Forming a heat reflection film inside the recess of the first sheet;
Preparing a second sheet on which a heat reflection film is not formed on a side facing the recess of the first sheet,
Bonding the first sheet and the second sheet to form at least a recessed inner space of the first sheet. The method of claim 5,
The second sheet has a plurality of dome structures having hemispherical recesses, and the dome structure of the first sheet on which the heat reflection film is formed and the dome structure of the second sheet correspond to each other to form a spherical sealed inner space. Insulator manufacturing method, characterized in that configured to. The method according to claim 5 or 6,
And the first sheet and the second sheet are made of vinyl, and the partial heat reflecting film is made of aluminum film.

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