DE202022100809U1 - Heat insulating structure of a wall - Google Patents

Abstract

Heat-insulating structure of a wall, wherein a wall (1), a layer of heat-insulating mortar (2) and a heat-reflecting coating (3) are provided, characterized in that
- that the wall (1) is a wall of different buildings;
- that the layer of thermal insulation mortar (2) is arranged on the outside of the wall (1), the layer of thermal insulation mortar (2) comprising a base material (21) consisting of cement mortar and a plurality of aerogels (22), hollow aggregates (23 ) and fiber materials (24) are filled into the base material (21) in a uniform distribution, and a binder is mixed into the base material (21), through which the base material (21), the airgel (22), the hollow aggregate (23 ) and connect the fiber material (24) to form a structural unit;
- that the heat-reflecting coating (3) is applied to the outside of the layer of thermal insulation mortar (2) arranged on the outer end surface of the wall (1), the heat-reflecting coating (3) having a high solar reflection index [SRI, Solar Reflectance Index], and wherein the metal oxide particles are added to the thermal reflective coating (3) to increase the solar reflective index, and a hollow material is added to the thermal reflective coating (3).

Description

[Technical Field]

The invention relates to a heat insulating structure of a wall, particularly to a heat insulating structure that makes the wall of a building more effective in terms of heat insulation, heat resistance and energy saving to reduce temperature conduction and maintain an appropriate indoor temperature.

[State of the art]

All kinds of buildings provide a living environment that people need when living, working, etc. Located in the subtropical region, Taiwan experiences several months of hot climate throughout the year. Because the existing reinforced concrete buildings absorb solar radiation heat easily, after absorbing solar radiation heat, the building continuously releases the absorbed thermal energy to the room, resulting in an increase in room temperature and affecting the comfort of people working in it.

In order to reduce the transmission of solar radiation heat through the wall of the building into the room, which causes the problem of rising room temperature, a base layer made of sand and cement is applied to the outside of the wall of the building. Thermally insulating foam materials such as phenolic foam boards, foam cement boards, foam polyurethane [PU], foam polyethylene [PE] or foam polystyrene [PS] are arranged on the base layer.

Gypsum boards, calcium silicate boards, etc. are then laid as a thermal insulation layer. The heat absorption from solar radiation is reduced by the thermal insulation layers mentioned above. However, the arrangement of the thermal insulation layers requires manpower to lay various foam boards, gypsum boards and calcium silicate boards on the base layer one by one, resulting in much labor and labor costs. The material of thermal insulation layers composed of these foam board, gypsum board, calcium silicate board, etc. is fragile and easily damaged by collision. In addition, thermal expansion and contraction caused by wind, sun and rain tend to cause cracks to appear and thermal insulation layers to detach from the base layer. A more serious problem is that the above foam boards are all made of combustible materials except phenolic foam boards and cement foam boards. In addition to the release of toxic substances due to high temperatures, fires often result in flashovers with a high number of victims. The related incidents are heard time and time again in fires both at home and abroad, with the damage caused being enormous.

From the pamphlet TW M577424 , which goes back to the same inventor as the present application, a "refractory, heat and sound insulating mortar structure" (published on May 1, 2019) is known, which has a base material of base material cement mortar and the base material. A plurality of porous cavities are formed on the base material. In addition, the base material contains airgel, hollow aggregate, and fiber materials, all of which are filled in the porous cavities of the base material in a uniform manner, such that the base material is integrally formed with the airgel, aggregate, and fiber materials.

[Object of the invention]

The object of the present invention is to provide a heat-insulating structure of a wall which can make the wall of a building more effective in terms of heat insulation, heat resistance and energy saving to reduce thermal conduction and maintain an appropriate indoor temperature.

[Technical solution]

This object is achieved according to the invention by a heat-insulating structure of a wall having the features specified in claim 1. Further advantageous developments of the invention emerge from the dependent claims.

The invention relates to a thermally insulating structure of a wall, wherein a layer of thermal insulation mortar is arranged on the outside of a wall. The thermal insulation mortar layer has a base material, with a variety of aerogels, hollow aggregates and fiber materials being filled in the base material evenly distributed. The base material, the airgel, the hollow aggregate and the fiber material are combined by a binder to form a structural unit. A thermal reflective coating is applied to the outside of the thermal barrier mortar layer, the thermal reflective coating having a high solar reflectance index [SRI, Solar Reflectance Index], metal oxide particles added to the thermal reflective coating to increase the solar reflective index, and hollow material added to the thermal reflective coating is. In this way, the wall of the building can be more heat-insulating, heat-resistant and energetic be made more energy efficient, reducing temperature conduction and maintaining an appropriate internal temperature.

character list

• 1 zeigt eine perspektivische Darstellung eines Ausführungsbeispiels einer erfindungsgemäßen wärmeisolierenden Struktur einer Wand;
• 2 zeigt einen Schnitt durch das Ausführungsbeispiel einer erfindungsgemäßen wärmeisolierenden Struktur einer Wand; und
• 3 zeigt einen Schnitt durch ein weiteres Ausführungsbeispiel einer erfindungsgemäßen wärmeisolierenden Struktur einer Wand.

The invention and its configurations are explained in more detail below with reference to the drawings. In the drawings shows:

• 1 shows a perspective view of an embodiment of a heat insulating structure of a wall according to the invention;
• 2 shows a section through the embodiment of a heat insulating structure of a wall according to the invention; and
• 3 shows a section through a further exemplary embodiment of a heat-insulating structure of a wall according to the invention.

[Explanation of the preferred embodiment]

How from the 1 and 2 visible, a wall 1, a thermal insulation mortar layer 2 and a heat-reflecting coating 3 are provided.

The wall 1 is a wall 1 of various buildings, the wall 1 being selected from a group consisting of a cement wall 1 and a brick wall 1 .

The layer of thermal insulation mortar 2 is arranged on the outside of the wall 1 . As an alternative to this, the layer of thermal insulation mortar 2 can be arranged on the outside and inside of the wall 1 at the same time. The thermal insulation mortar layer 2 has a base material 21 consisting of cement mortar. A plurality of aerogels 22, hollow aggregates 23 and fibrous materials 24 are filled in the base material 21 evenly distributed. A binder is mixed into the base material 21, through which the base material 21, the airgel 22, the hollow aggregate 23 and the fiber material 24 combine to form a structural unit. The airgel 22 is a fire resistant and heat insulating material. The hollow aggregate 23 may be foamed material, pumice, volcanic rock, ceramic beads, glass beads, vermiculite, perlite, or a combination thereof. The fibrous material 24 may be fiberglass, mineral fiber, rock wool, metal fiber, or a combination thereof. The metal fiber is preferably a stainless steel fiber.

The heat-reflecting coating 3 is coated on the outside of the thermal insulation mortar layer 2 arranged on the outer end face of the wall 1 . The heat-reflecting coating 3 has a high solar reflection index [SRI, Solar Reflectance Index]. In order to increase the solar reflection index, pigments with a high refractive index are commonly used, such as e.g. B.: Titanium dioxide with the refractive index of 2.81, red iron oxide with the refractive index of 2.80. Metal oxide particles are added to the heat reflecting coating 3 to increase the solar reflectance index. The heat-reflective coating 3 is a hollow material such. B. Ceramics, pozzolanic white sand deposits [sirasu] or a combination thereof are added to improve thermal insulation and reduce heat conduction.

With the above-mentioned design, the layer of thermal insulation mortar 2 can be applied to the outside of the wall 1 or to the inside and outside of the wall 1 at the same time. In addition, an interior paint layer 4 is applied to the outside of the thermal insulation mortar layer 2 . Using the low conductivity of the airgel 22 contained in the thermal insulation mortar layer 2 and the hollowness of the aggregates 23, the temperature conduction can be reduced, thereby maintaining an appropriate indoor temperature. The heat-reflecting coating 3 is coated on the outside of the thermal insulation mortar layer 2 arranged on the outer end face of the wall 1 . By using the heat-reflecting coating 3 for insulation and reducing the heat conduction effect, better heat-dissipating, heat-resistant, and energy-saving effects can be obtained.

Below is on 3 referenced. Further, between the inside of the heat reflecting coating 3 and the thermal insulating mortar layer 2 is disposed a low thermal conductivity heat resistance coating 5 selected from a group consisting of hollow glass paint, hollow ceramic paint and airgel. With this, the thermal resistance coating 5 can have ultra-low thermal conductivity properties [k<0.03 W/m·K]. During use, the heat-dissipating, heat-resistant and energy-saving effects can be further achieved by the arrangement of the heat-resistance coating 5.

Compared with the prior art, the wall of the building can be made more heat-insulating, heat-resistant and energy-saving, reducing the temperature conduction and maintaining a suitable indoor temperature.

QUOTES INCLUDED IN DESCRIPTION

This list of the documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• TW M577424 [0005]

Claims (10)

Heat-insulating structure of a wall, wherein a wall (1), a layer of heat-insulating mortar (2) and a heat-reflecting coating (3) are provided, characterized in that - the wall (1) is a wall of different buildings; - that the layer of thermal insulation mortar (2) is arranged on the outside of the wall (1), the layer of thermal insulation mortar (2) comprising a base material (21) consisting of cement mortar and a plurality of aerogels (22), hollow aggregates (23 ) and fiber materials (24) are filled into the base material (21) in a uniform distribution, and a binder is mixed into the base material (21), through which the base material (21), the airgel (22), the hollow aggregate (23 ) and connect the fiber material (24) to form a structural unit; - that the heat-reflecting coating (3) is applied to the outside of the layer of thermal insulation mortar (2) arranged on the outer end surface of the wall (1), the heat-reflecting coating (3) having a high solar reflection index [SRI, Solar Reflectance Index], and wherein the metal oxide particles are added to the thermal reflective coating (3) to increase the solar reflective index, and a hollow material is added to the thermal reflective coating (3). Heat insulating structure of a wall after claim 1 , characterized in that the thermal insulation mortar layer (2) is arranged at the same time on the inside of the wall (1). Heat insulating structure of a wall after claim 1 , characterized in that the airgel (22) of the thermal insulation mortar layer (2) is a fire-resistant and heat-insulating material. Heat insulating structure of a wall after claim 1 characterized in that the hollow aggregate (23) is foamed material, pumice, volcanic rock, ceramic beads, glass beads, vermiculite, perlite, or a combination thereof. Heat insulating structure of a wall after claim 1 , characterized in that the fiber material (24) is glass fiber, mineral fiber, rock wool, metal fiber, or a combination thereof. Heat insulating structure of a wall after claim 5 , characterized in that the metal fiber is a stainless steel fiber. Heat insulating structure of a wall after claim 1 , characterized in that the pigment used in the heat reflective coating (3) is selected from a group comprising titanium dioxide and red iron oxide. Heat insulating structure of a wall after claim 1 , characterized in that the heat-reflecting coating (3) is added with a hollow material selected from the group comprising ceramics, pozzolanic white sand deposits [sirasu] or a combination thereof. Heat insulating structure of a wall after claim 1 , characterized in that a heat resistance coating (5) with low thermal conductivity is arranged between the inside of the heat-reflecting coating (3) and the thermal insulation mortar layer (2). Heat insulating structure of a wall after claim 1 characterized in that the low thermal conductivity thermal resistance coating (5) is selected from a group consisting of hollow glass paint, hollow ceramic paint and aerogel.

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