KR20230060031A - Insulation wall with high-temperature climate-responsive heat reflective insulation - Google Patents

Abstract

Insulation wall to which the high-temperature climate-responsive heat reflective insulation material is applied according to the present invention is an adhesive layer attached to one side of a building, a core material for blocking outside air transmitted from the building, and heat transmitted by radiation provided on both sides of the core material A heat reflective heat insulating material having a reflective aluminum sheet; a rectangular member provided outside the heat reflective heat insulating material to fix the heat reflective heat insulating material to one surface of the building; and a finishing material provided on the outer side of the rectangular material to finish one side of the building and to form an air layer in the heat reflective heat insulating material.

Description

Insulation wall with high-temperature climate-responsive heat reflective insulation}

The present invention relates to a heat-insulating wall to which a heat reflective insulator corresponding to a high temperature climate is applied, and more particularly, a coating layer corresponding to a high temperature climate is formed on one surface of the heat reflective insulator, and condensation water generated on one surface of the heat reflective insulator is reduced. It relates to a heat insulating wall to which a heat reflective heat insulating material corresponding to a high temperature climate is applied, which can increase the radiant heat blocking effect of the heat reflective heat insulating material by being discharged to the ground.

Heat loss through the outer walls of a building accounts for the largest portion of the energy consumption of a building. Therefore, in order to save energy in a building, it is necessary to design and construct appropriately to increase the insulation performance of the outer wall of the building.

In general, in order to increase the insulation performance of the outer wall of a building, a heat insulating material such as styrofoam, urethane foam, glass wool, rock wool, or polyester foam is mainly used. These insulating materials are mainly used in resistance-type insulation methods that minimize heat transfer by conduction and convection. In fact, a significant degree of heat loss can be prevented by using a plate-shaped insulator such as ordinary Styrofoam.

However, heat transferred through exterior walls in buildings is carried not only by conduction and convection, but also by radiation. Heat transfer in buildings varies by season and by part of the building, but heat transfer by radiation has the greatest effect.

Therefore, in order to prevent heat transfer by radiation, a member such as a thin aluminum plate capable of reflecting heat moving by radiation is attached to an insulator such as the above-described Styrofoam.

However, in the case of an aluminum sheet exposed to a high-temperature climate, problems such as peeling, corrosion, and discoloration occur due to corrosion or oxidation prevention caused by environmental contamination.

In addition, in the case of an insulator in which an aluminum thin plate is combined, condensation occurs on the aluminum deposited film, and when foreign substances such as dust are attached due to the condensed water, the effect of reflecting radiant heat by the aluminum thin plate is significantly reduced.

Korean Registered Patent Publication No. 10-1355045 (2014.01.17.)

An object of the present invention is to provide a heat-insulating wall to which a high-temperature climate-compatible heat-reflective heat-reflecting heat-reflective heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat-reflecting heat insulating material can be provided with anti-oxidation, weather resistance, and corrosion resistance.

Another object of the present invention is to provide a heat-insulating wall to which a heat-reflecting heat-reflecting heat-insulating material for high-temperature climate is applied, capable of discharging condensation water generated on a thin aluminum plate formed on the heat-reflective heat-reflecting heat insulating material.

In order to achieve the above object, a heat insulating wall to which a heat reflective insulating material corresponding to a high temperature climate is applied according to an aspect of the present invention includes an adhesive layer attached to one side of a building, a core material for blocking outside air transmitted from the building, and the core material. A heat reflective insulator having thin aluminum plates provided on both sides to reflect heat transmitted by radiation; a rectangular member provided outside the heat reflective heat insulating material to fix the heat reflective heat insulating material to one surface of the building; and a finishing material provided on the outer side of the rectangular material to finish one side of the building and to form an air layer in the heat reflective heat insulating material.

The aluminum thin plate is produced by applying any one of glass fiber, non-woven fabric, plastic thin film, or tarpaulin material, and oxidation prevention, weather resistance, and corrosion resistance can be formed on one surface exposed to the outside of the aluminum thin plate.

The multi-purpose coating layer is an antioxidant coating for applying an antioxidant coating solution to prevent an oxidation reaction due to an alkaline component occurring in the building, and a weather resistance by reducing peeling, corrosion, and discoloration of the aluminum sheet due to direct long-term exposure to high-temperature solar radiation. It may be provided with a high-deposition coating having a high-deposition vacuum coating method for increasing the UV coating and the emissivity of the aluminum thin plate.

The core material may be formed of any one of perforated PE foam, non-perforated PE foam, air cap, or nonwoven fabric to increase insulation performance.

The adhesive layer can be easily attached to one surface of the building in the field by applying an oil-based or water-based adhesive to one surface of the core material and attaching a release paper.

The heat reflective heat insulator may maximize heat insulation performance by providing another heat reflective heat insulator on one surface according to the environment of the building.

The heat reflection insulating material may be fixed to the building, and a condensation water discharge unit may be further provided to discharge the condensed water generated on one surface of the aluminum thin plate to the ground.

The condensation water discharge unit is coupled to the fixing pin so that the condensation water generated on one surface of the aluminum thin plate flows to the ground, and the fixing pin fixing the heat reflective insulation to the building is provided with a condensed water discharge table for discharging condensed water can do.

The condensation water discharge stand has a discharge channel for flowing condensation water and one surface of the aluminum thin plate, a coupling ring formed at both ends of the discharge channel and forming a groove so as to be coupled to the fixing pin, and on one side of the discharge channel It may be provided with a discharge passage that is perforated and extends toward the ground and discharges the condensed water flowing from the discharge waterway to the ground.

The discharge waterway has a first waterway surface in which one side faces the aluminum thin plate, a second waterway surface whose outer surface is formed as an inclined surface to discharge condensed water generated in the aluminum thin plate, and the discharge waterway is coupled to the fixing pin. And it may be provided with a butting means in which a part is bent in an oblique direction so that the first waterway surface faces the aluminum thin plate.

According to the insulating wall to which the heat reflective heat insulating material for high temperature climate is applied according to the present invention, oxidation prevention, weather resistance, and corrosion resistance of the heat reflective heat insulating material can be provided by oxidation prevention coating, UV coating, and high deposition coating formed on an aluminum thin plate. .

In addition, it is possible to discharge the condensation water generated in the aluminum thin plate to the ground by fixing the heat reflective insulation to the building and facing the surface of the condensation water discharge unit.

1 is a cross-sectional view showing the overall appearance of a heat-insulating wall to which a high-temperature climate-responsive heat-reflecting heat insulating material according to the present invention is applied.
Figure 2 is a cross-sectional view showing the state of the double heat reflection insulator of the insulation wall to which the high-temperature climate response type heat reflection insulation material in FIG. 1 is applied.
Figure 3 is a perspective view showing the overall appearance provided with a condensed water discharge unit to the heat insulating wall to which the high-temperature weather response type heat reflective heat insulating material according to the present invention is applied.
Figure 4 is a perspective view showing the appearance of the condensed water discharge portion of the heat insulating wall to which the high-temperature climate-responsive heat reflective heat insulating material is applied in FIG.
Figure 5 is an enlarged view showing a detailed appearance of the condensation water discharge portion of the heat-insulating wall to which the high-temperature climate-responsive thermal insulation material is applied in FIG.
Figure 6 is a perspective view showing a state in which condensation water is generated and discharged on one side of a heat-insulating wall to which a high-temperature climate-responsive heat reflective heat insulating material is applied in FIG.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. However, it goes without saying that the present invention is not limited to these embodiments and can be modified in various forms.

In the drawings, in order to clearly and concisely describe the present invention, parts not related to the description are omitted, and the same reference numerals are used for the same or extremely similar parts throughout the specification. In addition, in the drawings, the thickness, width, etc. are enlarged or reduced in order to make the description more clear, and the thickness, width, etc. of the present invention are not limited to those shown in the drawings.

And when a part in the entire specification is said to "include" another part, it does not exclude other parts unless otherwise stated, and may further include other parts.

1 is a cross-sectional view showing the overall appearance of a heat-insulating wall to which a heat-reflective insulating material for high-temperature climate is applied according to the present invention, and FIG. cross section shown.

As shown in FIGS. 1 and 2, the heat-insulating wall to which the high-temperature climate-responsive heat reflective insulating material according to the present invention is applied includes an adhesive layer 110 attached to one surface of the building 10 and outside air transmitted from the building 10 A heat reflective insulator 100 having a core material 120 for blocking and a thin aluminum plate 130 provided on both sides of the core material 120 to reflect heat transmitted by radiation; A rectangular member 500 provided on the outside of the heat reflective insulator 100 to fix the heat reflective insulator 100 to one side of the building 10; and a finishing material 300 provided on the outside of the rectangular material 20 to finish one side of the building 10 and to form an air layer in the heat reflective heat insulating material 100.

Here, the heat reflective insulator 100 is provided on one surface and the roof of the building 10 to efficiently prevent heat transfer by conduction, convection and radiation, thereby exerting a great effect on energy saving of the building 10.

The heat reflective insulator 100 may include a core material 120 and an aluminum thin plate 130 and may form an adhesive layer 110 to be attached to one surface of the building 10. In addition, a coating layer may be additionally applied to increase the lifespan of the aluminum thin plate 130 .

The adhesive layer 110 can be easily attached to one surface of the building 10 in the field by applying oil-based and water-based adhesives to one surface of the core material 120 and attaching a release paper.

Since the adhesive layer 110 may peel off when exposed to a high temperature for a long period of time depending on the field environment (climate, etc.), it is possible to prevent the peeling phenomenon by using an oil-based and water-based adhesive in combination.

The core material 120 may be formed of any one of perforated PE foam, non-perforated PE foam, air cap, and non-woven fabric to increase insulation performance. Foamed polyethylene is easy to mold, has a low melting point, and has a high adhesion level when grafted with various materials, and can produce a core material 120 with enhanced combustion performance according to the mixing ratio.

The air cap is foamed with LDPE and has high insulation performance according to the formation of an air layer, and has the same melting point as expanded polyethylene, so it can be heat-sealed with various film and fabric materials.

The aluminum thin plate 130 may be produced by applying any one of glass fiber, non-woven fabric, plastic thin film, or tarpaulin material.

The thin aluminum plate 130 may have a multi-purpose coating layer 131 forming oxidation prevention, weather resistance, and corrosion resistance on one surface exposed to the outside. The multipurpose coating layer 131 may be applied as a response to corrosion and oxidation prevention phenomena caused by environmental contamination of the material when the aluminum thin plate 130 is exposed to the outside for a long period of time.

The angle member 500 may be spaced apart so as to form a space between the heat reflective insulator 100 and the finishing material 300 so that the aluminum thin plate 130 faces the air layer to evaporate or circulate the condensed water to some extent.

The angle member 500 fixes the heat reflective insulator 100 to one surface of the building 10, and the finishing material 300 is fixed to the outer surface of the angle member 500 to form a beautiful appearance of the building 10. .

In the heat reflective insulator 100, aluminum thin plates 130 are thermally fused on both sides of the core material 120, and then a multi-purpose coating layer 131 is applied to increase the performance and extend the lifespan of the aluminum thin plate 130. An adhesive layer 110 equipped with a release paper may be attached to one surface of the building 10 later.

Here, the multi-purpose coating layer 131 is composed of an antioxidant coating for applying an antioxidant coating liquid to prevent an oxidation reaction due to an alkaline component generated in the concrete of the building 10 and direct long-term exposure to high-temperature solar radiation transmitted from the outside. It may be provided with a UV coating that reduces peeling, corrosion, and discoloration of the aluminum thin plate due to high weather resistance, and a high-deposition coating having a high-deposition vacuum coating method for increasing the emissivity of the aluminum thin plate 130.

The multi-purpose coating layer 131 is applied only to one side of the aluminum thin plate 130, and after the aluminum thin plate 130 is thermally fused with the core 120 to form the heat reflective insulator 100, one side facing the external air layer and the building It can be formed on one side facing the concrete of (10).

The aluminum thin plate 130 has excellent weather resistance and corrosion resistance of the heat reflective insulator 100 due to the coating technology, and can maintain the performance of the heat reflective insulator 100 even when exposed to high-temperature sunlight for a long time.

According to the environment of the building 10, the heat reflective insulator 100 may further provide the same heat reflective insulator 100 on one surface to maximize the heat insulation performance. At this time, the environment of the building 10 may be a wall, a roof, or a ceiling.

The double heat reflective insulator 100' is integrally formed by forming the adhesive layer 110 without forming the multipurpose coating layer 131 on the thin aluminum plate 130 provided between the heat reflective insulator 100 and the heat reflective insulator 100. can be formed

The double heat reflective insulator 100' is formed in one piece and applies the multi-purpose coating layer 131 only to the aluminum thin plate 130 formed on the outside to increase the lifespan of the surface facing the concrete and the surface of the building 10 facing the air layer. can make it

Next, the condensation water discharge unit of the heat insulating wall to which the heat reflective heat insulating material corresponding to the high temperature climate according to the present invention is applied will be described in more detail.

Figure 3 is a perspective view showing the overall appearance provided with a condensation water discharge unit to the insulating wall to which the heat reflective insulating material corresponding to the high temperature climate according to the present invention is applied, Figure 4 is a heat insulating wall to which the heat reflective insulating material corresponding to the high temperature climate is applied in FIG. It is a perspective view showing the appearance of the condensation water discharge unit, and FIG. 5 is an enlarged view showing a detailed appearance of the condensation water discharge unit of the heat insulating wall to which the high-temperature climate responsive heat reflective insulation material is applied in FIG.

The condensation water discharge unit 500 is generated from the aluminum thin plate 130 coupled to a fixing pin 510 formed to fix the heat reflective insulator 100 to one surface of the building 10 and a part of the fixing pin 510 The condensed water discharged to the ground may be provided with a condensed water discharge stand 520 for maintaining the efficiency of the heat reflective insulator 100.

Here, the fixing pin 510 includes a fixing body 511, a fixing bolt 512 extending from one surface of the fixing body 511 and fixed to one surface of the building 10, and protruding from the other surface of the fixing body 511. It may be provided with a coupling protrusion 513 coupled to the condensed water discharge table 520.

The condensation water discharge table 520 is formed on both ends of the discharge waterway 521 for flowing condensed water and one side facing the aluminum thin plate 130, and the discharge waterway 521, and has grooves so as to be coupled to the fixing pin 510 It may be provided with a coupling ring 522 formed, and a discharge passage 523 that is perforated on one surface of the discharge waterway 521 and extends in the direction of the ground and discharges the condensed water flowing from the discharge waterway 521 to the ground.

The discharge conduit 521 includes a first conduit surface 5211 having one side facing the aluminum thin plate 130 and a second conduit surface 5212 having an inclined outer surface to discharge condensed water generated in the aluminum thin plate 130. ), and a butting means 5213 in which a part of the discharge waterway 521 is coupled to the fixing pin 510 and a part of the waterway surface 5211 is bent in an oblique direction so that the first waterway surface 5211 faces the aluminum thin plate 130. Can be provided there is.

One surface of the first waterway surface 5211 is formed as a flat surface so that the aluminum thin plate 130 and the condensation water do not flow between the aluminum thin plate 130 and the second waterway surface. (5212) can be guided to be discharged.

The second waterway surface 5212 is formed as an inclined surface from the first waterway surface 5211, so that the condensed water can be collected in one place so that the water can be discharged to the ground. At this time, the angle between the second waterway surface 5212 and the first waterway surface 5211 may be maintained at 25 to 35 degrees so that condensed water can easily rise.

The condensed water is collected on the first water passage surface 5211, and the collected condensed water may be discharged to the bottom along the second water passage surface 5212. In addition, the collected condensed water may be discharged from the end point of the second water passage surface 5212 or may be discharged to the ground through a discharge passage 523 formed in a part of the discharge water passage 521.

The butt means 5213 is bent in an oblique direction inside both ends of the discharge channel 521, and the discharge channel 521 does not touch the aluminum thin plate 130 due to the fixing body 511 of the fixing pin 510 In order to prevent the situation, the discharge waterway 521 can be coupled to the fixing pin 510 and then bent in an inward oblique direction so as to be supported against the thin aluminum plate 130.

Coupling rings 522 are formed at both ends of the discharge waterway 521 and coupled with the coupling protrusions 513 protruding from the fixing pin 510 to support the discharge waterway 521 so as to face the aluminum thin plate 130. can

The discharge passage 523 is repeatedly formed at a predetermined distance apart from a part of the discharge waterway 521, and the second waterway surface 5212 is perforated to form a discharge hole 5231 and the opposite side of the second waterway surface 5212. A passage for discharging condensed water may be formed.

The discharge passage 523 may have an oblique cut at an end of the discharge passage 523 so that the condensed water moved through the discharge hole 5231 is discharged more quickly.

The discharge hole 5231 may be perforated in a part of the discharge channel 521 so that the condensed water collected on the first water channel surface 5211 and the second water channel surface 5212 is discharged to the ground through the discharge passage 523.

Next, a process in which condensed water is discharged to the ground through the condensed water discharge unit of the insulating wall to which the heat reflective insulator for high temperature climate according to the present invention is applied will be described in more detail.

6 is a perspective view illustrating a state in which condensation water is generated and discharged on one side of a heat insulating wall to which a heat reflective heat insulating material corresponding to a high temperature climate is applied in FIG. 3 .

Referring to FIG. 6, in the heat reflective insulator 100, condensation occurs due to a temperature difference between the aluminum thin plate 130 and the air layer formed outside, and condensation water forms on the aluminum thin plate 130, and when exposed for a long time, dust in the condensed water Foreign substances such as , etc. stick to it and reduce the efficiency of heat reflection. At this time, the condensed water discharge unit 500 faces the aluminum thin plate 130 to induce the condensed water to be discharged to the ground, and the condensed water that has fallen on the ground can be rapidly evaporated by air circulation in the air layer and other ventilation structures. .

In the condensed water discharge unit 500, the condensed water rises above the discharge waterway 521 by the first waterway surface 5211 facing the aluminum thin plate 130, and the condensation water moves along the second waterway surface 5212. Water may be discharged to the ground through the discharge passage 523.

Here, while the condensed water discharged through the discharge passage 523 falls to the ground to the condensed water formed at the bottom, the effect of discharging the condensed water can be increased.

Through this, the insulation wall to which the high-temperature climate responsive heat reflective insulation material is applied fixes the heat reflective insulation material 100 to one side of the building 10, while condensation water generated on one side of the aluminum thin plate 130 exposed to the outside to the ground A condensed water discharge unit 500 may be provided.

In addition, the condensed water discharge unit 500 is formed in a thin shape to cover only a small area so as to maximize the heat reflection effect on the thin aluminum plate 130, and as the condensed water is left for a long time, dust and foreign substances in the air layer adhere to the heat reflection efficiency. drop can be minimized.

In addition, the oxidation prevention coating, UV coating, and high deposition coating formed on the aluminum thin plate 130 provide oxidation prevention, weather resistance, and corrosion resistance that increase the lifespan of the heat reflective insulator 100, and the aluminum thin plate by the high deposition coating emissivity can be further increased.

In the above, the heat insulating wall to which the heat reflective insulating material for high temperature climate is applied according to the embodiment of the present invention has been described, but the spirit of the present invention is not limited to the embodiment presented herein. In addition, those skilled in the art who understand the spirit of the present invention may easily suggest other embodiments by adding, changing, deleting, adding, etc., components within the scope of the same spirit, but this is also within the spirit of the present invention. will say that

10: building 100: heat reflective insulation
100 ': double heat reflective insulation 110: adhesive layer
120: core material 130: aluminum thin plate
131: multi-purpose coating layer 200: rectangular
300: finishing material 500: condensation water discharge unit
510: fixing pin 511: fixing body
512: fixing bolt 513: coupling protrusion
520: condensation water outlet 521: discharge waterway
5211: 1st waterway surface 5212: 2nd waterway surface
5213: butting means 522: coupling ring
523: discharge passage 5231: discharge hole

Claims (10)

A heat reflective insulator having an adhesive layer attached to one surface of a building, a core material for blocking outside air transmitted from the building, and thin aluminum plates provided on both sides of the core material to reflect heat transmitted by radiation;
a rectangular member provided outside the heat reflective heat insulating material to fix the heat reflective heat insulating material to one surface of the building; and
A heat-insulating wall to which a high-temperature climate-responsive heat-reflective heat insulating material is applied, including a finishing material provided on the outside of the rectangular material to finish one side of the building and to form an air layer in the heat-reflective heat insulating material. According to claim 1,
The aluminum thin plate is produced by applying any one of glass fiber, non-woven fabric, plastic thin film or tarpaulin material,
A heat-insulating wall to which a high-temperature climate-responsive heat reflective insulator is applied, characterized in that it has a multi-purpose coating layer forming oxidation prevention, weather resistance, and corrosion resistance on one surface exposed to the outside of the aluminum thin plate. According to claim 2,
The multi-purpose coating layer is an antioxidant coating for applying an antioxidant coating solution to prevent an oxidation reaction due to an alkaline component occurring in the building,
UV coating to increase weather resistance by reducing peeling, corrosion and discoloration of the thin aluminum plate due to direct long-term exposure to high-temperature solar radiation;
A heat-insulating wall to which a high-temperature climate-responsive heat reflective insulator is applied, characterized in that it has a high-deposition coating having a high-deposition vacuum coating method for increasing the emissivity of the aluminum thin plate. According to claim 3,
The core material is formed of any one of perforated PE foam, non-perforated PE foam, air cap, or non-woven fabric to increase heat insulation performance, characterized in that the high temperature climate responsive heat reflective insulation wall applied. According to claim 4,
The adhesive layer is a heat-insulating wall with a high-temperature climate-responsive heat reflective insulation material, characterized in that it is easily attached to one side of the building in the field by applying an oil-based and water-based adhesive to one side of the core material and attaching a release paper. According to claim 5,
The heat reflective heat insulating material is a heat insulating wall applied with a heat reflective heat insulating material corresponding to a high temperature climate, characterized in that to maximize the heat insulation performance by providing one more heat reflective heat insulating material on one side according to the environment of the building. According to claim 6,
The heat reflective heat insulating material is fixed to the building, and the condensation water generated on one side of the aluminum thin plate is further provided with a condensed water discharge unit for flowing and discharging the condensed water generated on one side of the aluminum thin plate. . According to claim 7,
The condensation water discharge unit includes a fixing pin for fixing the heat reflective insulation to the building;
Insulation wall to which the high-temperature climate-responsive heat reflective insulation material is applied, characterized in that it has a condensation water discharge stand for discharging condensation water coupled to the fixing pin so that the condensation water generated on one side of the aluminum thin plate flows to the ground. According to claim 8,
The condensation water discharge stand has one side facing the aluminum thin plate and a discharge channel for flowing condensed water;
Coupling rings formed at both ends of the discharge channel to form grooves so as to be coupled to the fixing pins;
A heat-insulating wall with a high-temperature climate-responsive heat reflective insulation material, characterized in that it is provided with a discharge passage that is perforated on one side of the discharge channel and extends in the direction of the ground and discharges the condensed water flowing from the discharge channel to the ground. According to claim 9,
The discharge waterway has a first waterway surface in which one surface faces the aluminum thin plate;
A second waterway surface whose outer surface is formed as an inclined surface to discharge condensation water generated from the aluminum thin plate;
The discharge waterway is coupled to the fixing pin and the first waterway surface is provided with a butting means in which a portion is bent in an oblique direction so that the surface of the first waterway is abutted to the aluminum thin plate. .

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