CN214461574U - Heat exchange low-carbon building energy-saving wall - Google Patents

Abstract

The utility model relates to the technical field of building energy conservation, in particular to a heat exchange low-carbon building energy-saving wall, which comprises a wall body, wherein the wall body comprises a far infrared textile layer, an inner heat-preservation and heat-insulation layer, a building base layer, an outer heat-preservation and heat-insulation layer and a sun-proof isolation layer which are sequentially bonded from the inside of the wall to the outside of the wall; in practical application, an inner heat-preservation heat-insulation layer and an outer heat-preservation heat-insulation layer are respectively arranged on the inner side and the outer side of a building base layer, so that the inner side and the outer side of a building wall are effectively heat-preservation and heat-insulation; far infrared rays are emitted through the far infrared textile layer, after the far infrared rays are absorbed by an indoor human body, the far infrared heat energy can be transferred to a deeper part under the skin of the human body due to the resonance effect generated by biological cells, the temperature of the lower deep layer rises, and the generated warm heat is emitted outwards from the inside of the human body to automatically compensate the temperature of the human body in the wall; the utility model discloses can reduce the building energy consumption, human body temperature in can also the automatic compensation wall, it is effectual to insulate against heat to keep warm.

Description

Heat exchange low-carbon building energy-saving wall

Technical Field

The utility model relates to a building energy conservation technical field specifically is a heat exchange low carbon building energy-saving wall.

Background

With the rapid development of the world economy, the shortage of energy becomes a practical problem that cannot be ignored. At present, nearly 30 percent of energy is consumed in buildings all over the world, and the sustainable development of the world economy is seriously influenced and restricted for a long time. Energy conservation has received widespread attention from all countries in the world, and China is no exception. At present, the energy consumption of buildings in China approximately accounts for 1/4 total energy used in China, and the energy consumption is the first, especially the energy consumption of heating and air conditioning of buildings, and the energy consumption of the buildings is on the rising trend year by year, so the energy saving of the buildings is very slow. The building energy-saving design is an important link in the comprehensive building energy saving, and is beneficial to stopping the waste of energy from the source. The outer wall serving as an outer enclosure structure in a building is a main part for energy consumption, so the energy-saving design of the outer wall is the most important part. The heat conductivity coefficient of air at normal temperature is 0.03W/(m.K), which is far lower than that of the heat insulating material commonly used in buildings, so that the temperature inside the outer wall is easily affected by the temperature outside the outer wall, and the structure of the outer wall is modified.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to foretell not enough, provide one kind can reduce the building energy consumption, human body temperature in can also the automatic compensation wall, the effectual heat exchange low carbon building energy-saving wall that insulates against heat and keep warm.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a heat exchange low carbon building energy-saving wall, includes the wall body, the wall body is including the far infrared textile layer, interior heat preservation insulating layer, building basic unit, outer heat preservation insulating layer and the sun-proof isolation layer that bond the setting in proper order outside the wall from the wall in to.

Further, the far infrared textile layer comprises a composite weaving layer and a far infrared ceramic powder spraying layer, the composite weaving layer is bonded on the inner side of the inner heat-preservation and heat-insulation layer, and the far infrared ceramic powder spraying layer is sprayed on the inner side of the composite weaving layer.

Further, the inner heat-insulation layer comprises a calcium silicate board layer and an inner wall heat-insulation board layer which are sequentially bonded from inside to outside, the outer side of the inner wall heat-insulation board layer is bonded with the building base layer, and the inner side of the calcium silicate board layer is bonded with the far infrared textile layer.

Further, building basic unit includes by interior sound insulation sheet layer, steel construction filling layer, outer sound insulation sheet layer and the waterproof rete that sets gradually outward, the steel construction filling layer includes steel structural framework, fills grout in the steel structural framework is husky, outer heat preservation insulating layer bonds in the waterproof rete outside, interior heat preservation insulating layer bonds interior sound insulation sheet layer is inboard.

Further, the outer heat-preservation and heat-insulation layer comprises an outer wall heat-preservation and heat-insulation plate layer and a cement pressure plate layer which are sequentially bonded from inside to outside, and the sun-proof isolation layer is bonded on the outer side of the cement pressure plate layer.

Further, the sunscreen isolation layer comprises a waterproof coating, and the sunscreen coating is sprayed on the outer side of the waterproof coating.

The utility model has the advantages that:

in practical application, an inner heat-preservation heat-insulation layer and an outer heat-preservation heat-insulation layer are respectively arranged on the inner side and the outer side of a building base layer, so that the inner side and the outer side of a building wall are effectively heat-preservation and heat-insulation; far infrared rays are emitted through the far infrared textile layer, after the far infrared rays are absorbed by an indoor human body, the far infrared heat energy can be transferred to a deeper part under the skin of the human body due to the resonance effect generated by biological cells, the temperature of the lower deep layer rises, and the generated warm heat is emitted outwards from the inside of the human body to automatically compensate the temperature of the human body in the wall; the utility model discloses can reduce the building energy consumption, human body temperature in can also the automatic compensation wall, it is effectual to insulate against heat to keep warm.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

reference numerals: a far infrared textile layer 1; a composite braid 11; a far infrared ceramic powder spray coating layer 12; an inner heat insulation layer 2; a calcium silicate board layer 21; an inner wall insulation board heat insulation board layer 22; a building base 3; an inner sound insulation sheet layer 31; a steel structure filler layer 32; a steel structural frame 321; cement paste sand 322; an outer sound-insulating sheet layer 33; a waterproof membrane layer 34; an outer heat insulation layer 4; an outer wall heat insulation slab layer 41; a cement pressure plate layer 42; a sun-screening barrier layer 5; a waterproof coating layer 51; a sunscreen coating 52.

Detailed Description

As shown in figure 1, the heat exchange low-carbon building energy-saving wall comprises a wall body, wherein the wall body comprises a far infrared textile layer 1, an inner heat-insulating layer 2, a building base layer 3, an outer heat-insulating layer 4 and a sun-proof isolation layer 5 which are sequentially bonded from the inside of the wall to the outside of the wall.

When the building wall is used, the inner heat-preservation and heat-insulation layer 2 and the outer heat-preservation and heat-insulation layer 4 are respectively arranged on the inner side and the outer side of the building base layer 3, so that the inner side and the outer side of the building wall are effectively heat-preservation and heat-insulation; far infrared rays are emitted through the far infrared textile layer 1, and after the far infrared rays are absorbed by indoor human bodies, water molecules in the bodies can resonate, so that the water molecules are activated, the intermolecular binding force of the water molecules is enhanced, biological macromolecules such as protein and the like are activated, and the cells of the organisms are at the highest vibration energy level; because the biological cells generate resonance effect, the far infrared heat energy can be transmitted to the deeper part of the human skin, the temperature of the lower deep layer rises, the generated warm heat is emitted outwards from the inside of the human body, the temperature of the human body in the wall is automatically compensated, and a certain health care effect is also achieved; the utility model discloses can reduce the building energy consumption, human body temperature in can also the automatic compensation wall, it is effectual to insulate against heat to keep warm.

As shown in fig. 1, the far infrared textile layer 1 comprises a composite woven layer 11 and a far infrared ceramic powder spraying layer 12, the composite woven layer 11 is bonded on the inner side of the inner heat-insulating layer 2, and the far infrared ceramic powder spraying layer 12 is sprayed on the inner side of the composite woven layer 11; in the embodiment, the composite woven layer 11 is bonded on the inner side of the inner heat-insulating layer 2, the far infrared rays are emitted through the far infrared ceramic powder spraying layer 12, and after the far infrared rays are absorbed by indoor human bodies, water molecules in the bodies can resonate, so that the water molecules are activated, the intermolecular binding force of the water molecules is enhanced, and therefore, biological macromolecules such as protein and the like are activated, and biological cells are at the highest vibration energy level; because the biological cells generate resonance effect, the far infrared heat energy can be transferred to the deeper part of the human skin, the temperature of the lower deep layer rises, the generated warm heat is emitted outwards from the inside of the human body, the temperature of the human body in the wall is automatically compensated, and a certain health care effect is achieved.

As shown in fig. 1, the inner heat-insulating layer 2 comprises a calcium silicate board layer 21 and an inner wall heat-insulating board layer 22 which are sequentially bonded from inside to outside, the building base layer 3 is bonded to the outer side of the inner wall heat-insulating board layer 22, and the far infrared textile layer 1 is bonded to the inner side of the calcium silicate board layer 21; in the embodiment, the heat insulation slab layer 22 of the inner wall heat insulation board can effectively insulate heat for the inner side of the wall; the novel environment-friendly building material calcium silicate board layer 21 has excellent fireproof performance and moisture resistance, and the service life is super long.

As shown in fig. 1, the building base layer 3 includes an inner sound insulation board layer 31, a steel structure filling layer 32, an outer sound insulation board layer 33 and a waterproof film layer 34, which are sequentially arranged from inside to outside, the steel structure filling layer 32 includes a steel structure frame 321, and cement mortar 322 filled in the steel structure frame 321, the outer heat insulation layer 4 is bonded on the outer side of the waterproof film layer 34, and the inner heat insulation layer 2 is bonded on the inner side of the inner sound insulation board layer 31; in this embodiment, prevent through interior sound insulation sheet layer 31 that the inside sound of wall body from spreading out, through sound insulation sheet layer 31 and outer sound insulation sheet layer 33 in the steel construction filling layer 32 installation, prevent through outer sound insulation sheet layer 33 that the outside noise of wall body from spreading into indoor, it is effectual to give sound insulation, through waterproof rete 34 effective waterproof.

As shown in fig. 1, the outer thermal insulation layer 4 comprises an outer thermal insulation board layer 41 and a cement pressure board layer 42 which are sequentially bonded from inside to outside, and the sunscreen isolation layer 5 is bonded on the outer side of the cement pressure board layer 42; in the embodiment, the heat preservation and insulation of the outer side of the wall body are effectively realized through the outer wall heat preservation and insulation plate layer 41; the novel building board cement pressure plate layer 42 has excellent moisture-proof and fireproof performances and an environment-friendly function.

As shown in fig. 1, the sun-proof isolation layer 5 comprises a waterproof coating 51, a sun-proof coating 52 sprayed on the outer side of the waterproof coating 51; in this embodiment, the waterproof coating 51 enhances the waterproof capability of the exterior of the wall, and the sunscreen coating 52 enhances the sunscreen capability of the exterior of the wall, thereby prolonging the service life of the wall.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein will be apparent to those skilled in the art without departing from the scope and spirit of the invention as defined in the accompanying claims.

Claims (6)

1. The utility model provides a heat exchange low carbon building energy-saving wall which characterized in that: the wall body comprises a wall body, and the wall body comprises a far infrared textile layer (1), an inner heat insulation layer (2), a building base layer (3), an outer heat insulation layer (4) and a sun-proof isolation layer (5) which are sequentially bonded from the inside of the wall to the outside of the wall.

2. The heat exchange low-carbon building energy-saving wall as claimed in claim 1, characterized in that: the far infrared textile layer (1) comprises a composite weaving layer (11) and a far infrared ceramic powder spraying layer (12), the composite weaving layer (11) is bonded on the inner side of the inner heat-insulating layer (2), and the far infrared ceramic powder spraying layer (12) is sprayed on the inner side of the composite weaving layer (11).

3. The heat exchange low-carbon building energy-saving wall as claimed in claim 1, characterized in that: interior heat preservation insulating layer (2) are including calcium silicate board layer (21) and interior wall insulation board heat insulation board layer (22) that bond in proper order from interior to exterior, interior wall insulation board heat insulation board layer (22) outside bonds building basic unit (3), the inboard bonding of calcium silicate board layer (21) far infrared textile layer (1).

4. The heat exchange low-carbon building energy-saving wall as claimed in claim 1, characterized in that: building basic unit (3) include by interior sound insulation sheet layer (31), steel construction filling layer (32), outer sound insulation sheet layer (33) and waterproof rete (34) that set gradually outward, steel construction filling layer (32) include steel structural framework (321), fill grout sand (322) in steel structural framework (321), outer heat preservation insulating layer (4) bond waterproof rete (34) outside, interior heat preservation insulating layer (2) bond interior sound insulation sheet layer (31) are inboard.

5. The heat exchange low-carbon building energy-saving wall as claimed in claim 1, characterized in that: the outer heat-insulation layer (4) comprises an outer wall heat-insulation plate layer (41) and a cement pressure plate layer (42) which are sequentially bonded from inside to outside, and the sun-proof isolation layer (5) is bonded on the outer side of the cement pressure plate layer (42).

6. The heat exchange low-carbon building energy-saving wall as claimed in claim 1, characterized in that: the sun-proof isolation layer (5) comprises a waterproof coating (51) and a sun-proof coating (52) sprayed on the outer side of the waterproof coating (51).

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