KR20210119365A - Insulation with radiation shielding method and insulation invoked radiation shielding - Google Patents

Abstract

The present invention relates to a method for blocking radiation of an insulation material and an insulation material manufactured using the same, designed to improve thermal insulation performance by preventing radiation loss occurring in a high-temperature area. The method for blocking radiation of an insulation material comprises steps of: setting an overall thickness of the insulation material; evenly dividing the thickness of the insulation material to make a plurality of divided insulation materials; setting a reflector for radiation shielding according to the temperature of use of the insulation material; and preventing radiation loss by arranging the set reflector at a predetermined position of the plurality of divided insulation materials, thereby improving the thermal insulation performance.

Description

Radiation shielding method of an insulating material and an insulating material manufactured using the same

The present invention relates to a method for blocking radiation of an insulator, and to a heat insulating material manufactured using the same, to a method for blocking radiation of an insulator to prevent radiation loss occurring in a high temperature region to improve thermal insulation performance, and to an insulating material manufactured using the same will be.

Wool-type insulators such as Cerakwool, a commonly known insulator, have a wool-like shape, so a method is used to insulate by simply enclosing an object for insulation.

Compared to the low-temperature region, the high-temperature region has a larger amount of heat transfer due to radiant heat compared to room temperature among the heat transfer methods of conduction, convection, and radiation.

Insulation made of a single material, such as ceracule, cannot prevent radiation loss at high temperatures, so a method of further increasing the thickness of the insulating material is used to maintain the insulating effect.

However, it is difficult to increase the thickness of the insulating material indefinitely in order to maintain the insulating effect at high temperature, and when the thickness of the insulating material is thick, the installation space is relatively limited, and the installation cost is also high.

A conventional technique for a single material insulation material such as ceracule was disclosed in Korean Patent Registration No. 10-1981004. The disclosed prior art secures a space for baking pizza by forming a dome part with refractory bricks on a volcanic stone, and then attaching volcanic stone tiles and Cerakwool in turn, so that the inside of the pizza baking space is at a high temperature. It not only maintains it, but also blocks heat transfer to the outside of the pizza oven to make pizza safely. Since ordinary sand is laid under the volcanic stone and chemical cement is poured under the ordinary sand, heat transfer under the volcanic stone can be prevented.

However, since this prior art also uses a single material (cerakwool) insulating material, there is a disadvantage in that a thicker insulating material must be used as the operating temperature of the furnace increases.

Republic of Korea Patent Registration 10-1981004 (Registered on May 15, 2019) (Pizza Oven)

Therefore, the present invention has been proposed to solve the problems occurring in the general single-material heat insulator and the prior art as described above. An object of the present invention is to provide an insulating material to which a method and a radiation shielding method are applied.

A method for blocking radiation of an insulating material according to the present invention for achieving the above objects, (a) setting the overall thickness of the insulating material; (b) equally dividing the insulating material having a set thickness into a plurality of divided insulating materials; (c) setting a reflector (reflector) for radiation shielding according to the use temperature of the insulating material; (d) arranging a set reflector at predetermined positions of the plurality of divided heat insulating materials to prevent radiation loss.

In the above step (c), the reflector sets the insulation reference temperature to prevent the material for radiation blocking from rotating, and when the insulation material is used in an area lower than the insulation reference temperature, Aluminum Foil is set as the reflector And, when the insulating material is used in a region higher than the thermal insulation reference temperature, a stainless foil is set as a reflector.

In the above step (c) the reflector is a spacer (spacer) for forming a space between the divided insulating material; It is characterized in that it is made of a radiation shielding material that is coupled to the spacer to block radiation.

In addition, the heat insulator to which the radiation blocking method according to the present invention is applied is characterized in that it is a heat insulator manufactured using the radiation blocking method of the heat insulator.

The heat insulating material to which the radiation blocking is applied is characterized in that it is created by equally dividing the heat insulator to be used to make a divided heat insulating material, and arranging a reflector for blocking the radiation between the divided heat insulating materials.

According to the present invention, by equally dividing the insulating material of a single material and arranging a reflector, which is a radiation shielding material, between the divided divided insulating materials to generate the insulating material, it is possible to prevent radiation loss occurring in the high temperature region and improve the thermal insulation performance. there is an effect

1 is a process diagram of a method for blocking radiation of an insulating material according to the present invention;
2A and 2B are structural diagrams of an insulating material to which a radiation blocking method is applied;
3 is a table showing the difference in emissivity of metal foil, sheet, and oxidized metal.

Hereinafter, a method for blocking radiation of an insulator according to a preferred embodiment of the present invention and a heat insulating material manufactured using the same will be described in detail with reference to the accompanying drawings.

The terms or words used in the present invention described below should not be construed as being limited to conventional or dictionary meanings, and the inventor may appropriately define the concept of terms in order to best describe his invention. It should be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle that it can be

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only preferred embodiments of the present invention, and do not represent all of the technical spirit of the present invention, so various equivalents and It should be understood that there may be variations.

1 is a process diagram of a method for blocking radiation of an insulator according to the present invention, (a) setting the overall thickness of the insulator (S10), (b) dividing the heat insulator having the set thickness into a plurality of divided heat insulators ( S20), (c) setting a reflector for radiation shielding according to the temperature of use of the insulating material (S30) and (d) placing the set reflector at a predetermined position of the plurality of divided insulating materials to prevent radiation loss (S40).

2 is a cross-sectional view of an insulator manufactured by the method of blocking radiation of the insulator as described above.

In the method of blocking radiation of the insulator according to the present invention configured as described above, first, the total thickness of the insulator 100 to be installed is set as in step S10. The insulation to be installed here is a single-material insulation material such as Cerakwool.

Next, in step S20, the insulating material to be installed is equally divided into a predetermined thickness to make a plurality of divided insulating materials 101 - 104.

In general, a single thickness of a single material is used when implementing a heat insulator. Insulation performance is superior to using a stack of insulation materials rather than insulation using a single thickness insulation material. The reason is that although the material is made of the same material, the contact resistance generated as the materials are laminated increases, preventing heat transfer.

Therefore, in the present invention, the insulating material of a single thickness is equally divided to the same thickness to make the divided insulating materials 101 - 104, and the insulating performance is improved by laminating them. Here, when equally dividing a single-thickness insulator into the same thickness, too much division causes a problem in the manufacturing process and causes a disadvantage in that it takes a lot of time to manufacture the insulator.

In order to improve this disadvantage, in the present invention, it is assumed that the insulating material of a single thickness is divided into four divided insulating materials having the same thickness. In an embodiment, it is described as equally dividing the insulating material into four, but the present invention is not limited thereto, and it is obvious to those of ordinary skill in the art that it can be used by dividing it into a larger number or a smaller number. will be.

For example, in the case of an insulating material having a thickness of 50 mm, it is divided equally into four to make a divided insulating material having a thickness of 12.5 mm.

Next, set reflectors (reflectors) (111 - 113) for radiation shielding according to the use temperature of the insulator. Here, the reflector, which is a radiation shielding material, effectively blocks heat received from high temperatures.

In order to increase the effect of blocking radiation, it is important to arrange a high-temperature heat source, insulating material, and reflector for blocking radiation. In the present invention, the reflector for blocking radiation is preferably disposed between the divided heat insulating materials to increase the effect for blocking radiation.

In order to further improve the insulation effect by blocking radiation, it is necessary to consider the ratio of radiation loss in the temperature region.

Figure 3 shows the difference in emissivity of metal foil and sheet, and oxidized metal.

In the case of Aluminum Foil, the emissivity is very good at 0.04, but when used in a high temperature environment, the surface is oxidized and the emissivity increases to 0.2 - 0.31. Therefore, at high temperature, it is helpful to improve overall performance to use stainless, which is not oxidized in a high temperature environment.

Therefore, the reflector sets the insulation reference temperature (for example, 300° C.), and when an insulation material is used in an area lower than the insulation reference temperature, aluminum foil is set as the reflector, and in the area higher than the insulation reference temperature When using insulation material, set stainless foil as a reflector.

The reflector 111 is implemented as a set of a spacer 111a and a radiation shielding material 111b. The spacer 111a forms a space between insulators having a general thermal insulation performance, thereby allowing the radiation shielding material 111b to function properly. The spacer can use a mesh (60-75% open area level).

Hereinafter, the functions of the spacer and the reflector will be described in detail.

First, heat from the high temperature side is irradiated to the reflector through the open area of the spacer. It is a form of heat transfer in the form of radiation. The reflector that receives heat radiates heat to the low temperature side as much as the emissivity, which is its inherent property. At this time, the remaining heat that cannot be emitted stays near the reflector, and the high temperature side with respect to the reflector achieves temperature equilibrium.

Although the reflector is in contact with the insulator, since the surface shape of the insulator is like cotton, even if the reflector and the insulator are in contact with each other, they make a large number of line contact instead of surface contact, which limits the heat transferred from the reflector to the insulator.

Next, the reflector set as described above is disposed at predetermined positions of the plurality of divided heat insulating materials to prevent radiation loss. The arrangement position of the reflector may be between the divided insulating material and the divided insulating material. That is, the reflector is disposed in the same form as (high temperature side) insulation material + reflector + heat insulating material (low temperature side) or (low temperature side) insulation material + reflector + heat insulating material (low temperature side).

FIG. 2A is a view for explaining that the reflectors 111 to 113 are placed between the divided divided insulating materials 101 to 104, and FIG. 2B is a cross-sectional view of the completed insulating material by combining the divided insulating materials with the reflectors.

Therefore, when a reflector set is inserted between the insulator and the insulator, the amount of heat transferred is drastically reduced.

By using this principle, an insulating material having better thermal insulation performance than using only the existing resistance type insulating material is realized.

Although the invention made by the present inventor has been described in detail according to the above embodiments, the present invention is not limited to the above embodiments and various modifications are possible without departing from the gist of the present invention. Anyone who has it will say it's self-evident.

100: insulation
101 - 104: split insulation
111 - 113: reflector
111a, 112a, 113a: spacers
111b, 112b, 113b: radiation shielding material

Claims (3)

As a method for blocking radiation of the insulating material,
(a) setting the overall thickness of the insulation;
(b) making a plurality of divided insulating materials by equally dividing the insulating material having the set thickness in order to prevent heat transfer through an increase in contact resistance;
(c) setting a reflector (reflector) for radiation shielding according to the use temperature of the insulating material; and
(d) arranging the set reflector between the divided insulating material and the divided insulating material made in step (b) to prevent radiation loss,
In the reflector of step (c), the insulation reference temperature is set to 300°C, and when an insulation material is used in a region lower than the insulation reference temperature, an aluminum foil having an emissivity of 0.04 is set as a reflector, and the insulation reference temperature When using insulation in a higher area, stainless foil that does not oxidize even at high temperatures is set as a reflector,
The reflector of step (c) includes a spacer (spacer) for forming a space between the divided insulation; It is made of a radiation shielding material that is combined with the spacer to block radiation,
The spacer uses a mesh having an open area of 60 to 75%,
The reflector and the insulator limit the heat transferred from the reflector to the insulator through line contact.
A heat insulating material manufactured using the method of blocking radiation of the heat insulating material according to claim 1 .
The method according to claim 2, wherein the insulator manufactured using the radiation blocking method is manufactured by equally dividing the insulator to be used to make a split insulator, and arranging a reflector for blocking radiation between the split insulators. Insulation material manufactured using

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