CN217379324U - Energy-saving wall structure for installing framework structure composite heat-insulation board keel - Google Patents

Abstract

The utility model discloses an energy-conserving wall body structure of frame construction composite heat preservation board fossil fragments installation, it includes composite heat preservation board, the metal joist, the connecting piece, high-efficient insulation material and outer wall inner panel, the metal joist is used for the installation to set up the inside at building beam column position, composite heat preservation board sets up in the outside of metal joist, the connecting piece is connected in the outside of composite heat preservation board and metal joist, composite heat preservation board includes organic material layer and inorganic material layer, inorganic material layer connects in the lateral surface on organic material layer, high-efficient insulation material is located between outer wall inner panel and composite heat preservation board's the inboard, and high-efficient insulation material connects in the metal joist, outer wall inner panel is connected in building beam column position and/or metal joist. The composite heat-insulating board formed by the organic material layer and the inorganic material layer and the high-efficiency heat-insulating material are combined and applied to the premise of ensuring safety and fire prevention, and the requirements of building energy conservation and even ultra-low energy consumption building energy conservation and heat insulation are met.

Description

Energy-saving wall structure for installing framework structure composite heat-insulation board keel

Technical Field

The utility model relates to an energy-conserving wall body structure of frame construction composite insulation board fossil fragments installation.

Background

China is a big energy consumption country, wherein the building energy consumption accounts for about 30% of the total social energy consumption. In recent years, the nation has vigorously popularized ultra-low energy consumption and near-zero energy consumption buildings, accelerated development of novel building industrialization, and actively implemented carbon peak reaching and carbon neutralization actions in the building field. In order to reduce the energy consumption of the building, the country requires that the newly built residential building strictly execute the relevant standard requirements of energy conservation. The outer protection system of the frame structure building generally adopts aerated concrete blocks or battens to build on site at present, and then constructs the inner/outer heat-insulating layer in a bonding mode of bonding and anchoring, so that the building efficiency is low, the site is dirty and messy, the labor consumption is large, and the outer protection system does not have the industrialized characteristics of buildings. With the further improvement of the energy-saving requirement, the outer protection system generally considers the measures of increasing the thickness of the heat-insulating layer and breaking the heat bridge so as to achieve the higher-level energy-saving requirement; however, there are more methods for forbidding external heat preservation, bonding and anchoring in provinces and cities in the country, and if aerated concrete blocks or laths are still adopted for on-site building, the situation that no heat preservation method is available is faced. And the heat preservation is too thick, must have the risk that drops and will increase obviously than traditional heat preservation, and the heat bridge problem of beam column part can not be solved to interior heat preservation again. Therefore, the heat preservation and enclosure integration method aiming at the requirements of high efficiency and high energy saving of the frame structure is in short supply.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the above-mentioned not enough of current existence, the utility model provides an energy-conserving wall body structure of frame construction composite insulation board fossil fragments installation.

The utility model discloses a realize through following technical scheme:

the utility model provides an energy-conserving wall body structure of frame construction composite insulation board fossil fragments installation, its includes composite insulation board, metal fossil fragments, connecting piece, high-efficient insulation material and outer wall inner panel, metal fossil fragments are used for the installation to set up the inside at building beam column position, composite insulation board set up in the outside of metal fossil fragments, the connecting piece connect in composite insulation board with the outside of metal fossil fragments, composite insulation board includes organic material layer and inorganic material layer, inorganic material layer connect in the lateral surface of organic material layer, high-efficient insulation material is located the outer wall inner panel with between composite insulation board's the inboard, just high-efficient insulation material connect in metal fossil fragments, outer wall inner panel connect in building beam column position and/or metal fossil fragments.

Further, the inorganic material layer is completely coated on the organic material layer, so that the organic material layer is located in the inorganic material layer.

Further, the energy-saving wall structure installed by the framework structure composite insulation board keel further comprises a bracket, wherein the bracket is connected to the metal keel and is arranged on the end face of the composite insulation board in a lining mode.

Further, the metal joist includes main joist and false keel, the main joist be used for with structural beam and/or structural column in the building beam column position are connected, the false keel along vertical and/or slope distribution and connect in the main joist.

Further, the organic material layer includes, but is not limited to, one or more of XPS extruded sheet, EPS polystyrene board;

and/or the material of the inorganic material layer is polymer mortar.

Further, at least one reinforcing mesh member is provided within the organic material layer and/or the inorganic material layer.

Further, the high-efficiency heat insulation material is embedded in the metal keel, so that the inner side and the outer side of the metal keel are respectively abutted against the outer wall inner plate and the composite heat insulation plate;

or the high-efficiency heat-insulating material is completely coated on the metal keel.

Furthermore, the energy-saving wall structure installed on the framework structure composite heat-insulation plate keel further comprises a bonding layer, wherein the bonding layer is located between the high-efficiency heat-insulation material and the outer wall inner plate and connected with the high-efficiency heat-insulation material and the outer wall inner plate.

Further, the high-efficiency thermal insulation material comprises one or more of EPS molding polyphenyl board, XPS extruded polyphenyl board, graphite molding polyphenyl board, graphite extruded polyphenyl board, polyurethane thermal insulation material and rock wool thermal insulation material;

and/or the outer wall inner plate is made of calcium silicate plates, gypsum plates, concrete precast slabs, concrete autoclaved aerated concrete blocks or ALC laths.

Furthermore, the energy-saving wall structure installed on the framework structure composite insulation board keel further comprises a protective layer, the protective layer comprises anti-crack mortar and alkali-resistant glass fiber gridding cloth, the anti-crack mortar is connected to the outer side face of the composite insulation board, and the alkali-resistant glass fiber gridding cloth is arranged in the anti-crack mortar;

and/or the outer surface of the composite heat-insulation board and/or the outer wall inner board is provided with a finishing coat.

The beneficial effects of the utility model reside in that:

the utility model discloses an energy-conserving wall body structure of frame construction composite insulation board fossil fragments installation, the composite insulation panel who forms through organic material layer and inorganic material layer and high-efficient insulation material's combination is used under the prerequisite of ensureing safe fire prevention, satisfies building energy conservation, and the ultralow energy consumption building energy conservation heat preservation requirement even. The structural position relationship between the composite heat-insulating board and the high-efficiency heat-insulating material avoids the common internal heat-insulating defects (condensation, mildew, split layers with beam-column parts and the like) generated when internal and external combination heat insulation is adopted to achieve the energy-saving effect. Meanwhile, the structure connection is firm, the material is fireproof and safe, the heat insulation effect is good, the energy-saving effect is obvious, and the construction is convenient.

Drawings

Fig. 1 is the structure schematic diagram of the energy-saving wall body structure installed by the framework structure composite heat-insulation board keel in the use of the utility model embodiment 1.

Fig. 2 is the internal structure schematic diagram of the energy-saving wall structure installed by the framework structure composite heat-insulating board keel of the embodiment 1 when in use.

Fig. 3 is the utility model discloses the internal structure schematic diagram of the energy-conserving wall body structure of frame construction composite insulation board fossil fragments installation.

Fig. 4 is the internal structure schematic diagram of the energy-saving wall structure installed by the framework structure composite heat-insulating board keel of the utility model embodiment 2 when in use.

Fig. 5 is the utility model discloses the internal structure schematic diagram of the energy-conserving wall body structure of frame construction composite insulation board fossil fragments installation.

Description of reference numerals:

composite heat insulation board 1

Inorganic material layer 11

Organic material layer 12

Metal keel 2

High-efficiency heat-insulating material 3

Outer wall inner plate 4

Connecting piece 5

Protective layer 6

Finishing layer 7

Bracket 8

Building beam column portion 10

Structural beam 101

Structural columns 102

Detailed Description

The following description of the embodiments refers to the accompanying drawings, which are included to illustrate specific embodiments in which the invention may be practiced.

Example 1

As shown in fig. 1, 2 and 3, the present embodiment discloses an energy-saving wall structure installed with frame structure composite insulation board keel, the energy-saving wall structure for installing the framework structure composite insulation board keel comprises a composite insulation board 1, a metal keel 2, a high-efficiency insulation material 3, an outer wall inner board 4 and a connecting piece 5, wherein the metal keel 2 is used for being installed inside a beam column part 10 of a building, the composite insulation board 1 is arranged on the outer side of the metal keel 2, the connecting piece 5 is connected to the outer sides of the composite insulation board 1 and the metal keel 2, the composite insulation board 1 comprises an organic material layer 12 and an inorganic material layer 11, the inorganic material layer 11 is connected to the outer side surface of the organic material layer 12, the high-efficiency insulation material 3 is positioned between the outer wall inner board 4 and the inner side of the composite insulation board 1, and the high-efficiency heat-insulating material 3 is connected to the metal keel 2, and the outer wall inner plate 4 is connected to the beam column part 10 and/or the metal keel 2 of the building.

The metal keel 2 is arranged inside the building beam column part 10, and the outer side surface of the metal keel 2 is flush with the outer side surface of the building beam column part 10, so that the composite heat insulation board 1 is convenient to install and connect. The composite insulation board 1 is connected with the metal keel 2 through the connecting piece 5, and the metal keel 2 is connected with the building beam column part 10, so that the structural connection strength is effectively enhanced, and the composite insulation board 1 is safely prevented from falling off. The building beam column part 10 comprises a structural beam 101 and a structural column 102, and the metal keel 2 is arranged between the structural beam 101 and the structural column 102 of the building beam column part 10 and is firmly connected with the structural beam 101 on the upper layer and/or the structural beam 101 and/or the structural column 102 on the lower layer to form a keel frame system. The composite heat-insulating board 1 is arranged on the outer side of the keel frame system and is firmly connected with the keel frame system through a connecting piece 5.

The composite heat-insulating board 1 comprises an organic material layer 12 and an inorganic material layer 11, and the composite heat-insulating board 1 formed by the organic material layer 12 and the inorganic material layer 11 and the high-efficiency heat-insulating material 3 are combined and applied on the premise of ensuring safety and fire resistance, so that the building energy-saving and even ultra-low energy consumption building energy-saving and heat-insulating requirements are met. Meanwhile, the structural position relationship between the composite heat-insulating board 1 and the high-efficiency heat-insulating material 3 avoids the common internal heat-insulating defects (dew formation, mildew formation, staggered layers with beam-column parts and the like) generated when internal and external combination heat insulation is adopted to achieve the energy-saving effect. Meanwhile, the structural design that the high-efficiency heat-insulating material 3 is arranged in front of the composite heat-insulating plate 1 and the outer wall inner plate 4 provides possibility for adopting a non-flame-retardant organic heat-insulating material with better heat-insulating effect, and has no fire safety problem, so that the overall thickness of the building outer wall can be further reduced, and the using area in the building sleeve is increased. The structure firm in connection, the material fire prevention is safe, and it is effectual to keep warm, and energy-conserving effect is obvious and the construction of being convenient for. Wherein, the end face of the composite heat-insulating board 1 contacting with the adjacent heat-insulating material can be additionally provided with a waterproof structure to prevent the water seepage at the abutted seam.

In the present embodiment, the inorganic material layer 11 completely covers the organic material layer 12, such that the organic material layer 12 is located in the inorganic material layer 11. The inorganic material layer 11 is completely coated on the organic material layer 12, that is, the inorganic material layer 11 coats six sides of the organic material layer 12, so as to achieve better heat preservation effect and material physical property under the condition of meeting the fireproof requirement.

The organic material layer 12 includes, but is not limited to, one or more of XPS extruded board, EPS polystyrene board. Thereby promoting the overall heat-insulating effect of the finally formed wall body and meeting the energy-saving requirement of the energy-saving wall body structure installed by the frame structure composite heat-insulating plate keel.

The material of the inorganic material layer 11 is polymer mortar. The polymer mortar is coated on the organic material layer 12, so that the organic material layer 12 is protected. Preferably, the polymer mortar can adopt functional heat-insulating mortar, anti-cracking mortar and the like.

The organic material layer 12 and/or the inorganic material layer 11 have at least one reinforcing mesh member therein. The reinforcing net component has a reinforcing effect, and when the effect of cracking resistance of the inorganic material layer 11 is played, the structure of penetrating the embedded reinforcing net component is additionally arranged in the structure that the connecting piece 5 penetrates through the composite heat-insulation board 1 and is connected with the metal keel 2, so that the connection of the connecting piece 5 and the reinforcing net layer is effectively enhanced, and the anti-falling effect is further improved.

The metal runners 2 comprise main runners for connection with structural beams 101 and/or structural columns 102 in the building beam column portion 10 and cross runners distributed vertically and/or at an angle and connected to the main runners. The main joist is used for being connected with the structural beam 101 of upper strata and lower floor, both sides structural column 102 in the building beam column position 10, is connected with building beam column position 10 through the main joist, has effectively strengthened structural connection intensity, is connected with the main joist respectively through the both ends of false keel to promote metal joist 2's stability, firmness and antidetonation, shear resistance. Wherein, the material of metal fossil fragments 2 can be metal, also can be wood.

Wherein, the false keel can be a lacing wire. The extending direction of the lacing wire can be parallel to the main keel, and the added lacing wire can also be not parallel to the main keel, so that the auxiliary keel can provide oblique acting force for the main keel, and the safety under the use working condition is further improved; and meets the requirement of opening the window opening.

The energy-saving wall body structure of frame construction composite insulation board fossil fragments installation still includes the architectural surface 6, and architectural surface 6 includes anti-crack mortar and alkali-resisting glass fiber net cloth, and anti-crack mortar connects in composite insulation board 1's lateral surface, and alkali-resisting glass fiber net cloth sets up in anti-crack mortar. The anti-crack mortar is used for leveling protection, the whole structural firmness of the protective layer 6 can be enhanced when the alkali-resistant glass fiber grids are arranged in the anti-crack mortar, and the safety and stability of the energy-saving wall structure installed on the framework structure composite heat-insulation board keel are improved.

The outer surface of the composite heat-insulating board 1 and/or the outer wall inner board 4 is provided with a finishing coat 7. The integrated finishing coat 7 can be prefabricated on the surfaces of the composite heat-insulation board 1 and/or the inner board 4 of the outer wall, so that the construction process can be further simplified, the prefabricated integration of materials is improved, and the construction efficiency and quality are further improved. Meanwhile, the added veneer layer 7 is used for protecting the wall body, beautifying the building and meeting the use requirement.

The energy-saving wall structure for installing the framework structure composite insulation board keel further comprises a bracket 8, and the bracket 8 is connected to the metal keel 2 and is arranged on the end face of the composite insulation board 1 in a lining mode. The bracket 8 is arranged on the bottom surface of the composite heat-insulation board 1 or the peripheral end surfaces of the composite heat-insulation board 1 in a lining manner and provides acting force for the composite heat-insulation board 1, so that the composite heat-insulation board 1, the protective surface layer 6 and the decorative surface layer 7 have supporting and hanging effects, the structural connection is firm, and the anti-falling safety performance of the composite heat-insulation board 1 is further improved; and is convenient for construction.

In this embodiment, high-efficient insulation material 3 inlays in metal joist 2 to make the inside and outside both sides of metal joist 2 support respectively to lean on in outer wall inner panel 4 and compound insulation board 1. When the thickness of high-efficient insulation material 3 is less than or equal to the thickness of metal joist 2, high-efficient insulation material 3 will be embedded into metal joist 2 completely to make the inside and outside both sides of metal joist 2 closely lean on respectively in outer wall inner panel 4 and composite insulation panel 1 and be connected with outer wall inner panel 4 and composite insulation panel 1.

The energy-saving wall structure installed on the framework structure composite heat-insulation plate keel further comprises a bonding layer, wherein the bonding layer is located between the high-efficiency heat-insulation material 3 and the outer wall inner plate 4 and is connected with the high-efficiency heat-insulation material 3 and the outer wall inner plate 4. The bonding strength between the high-efficiency heat-insulating material 3 and the outer wall inner plate 4 can be effectively enhanced through the bonding layer, and the high-efficiency heat-insulating material 3 is more firmly connected with the outer wall inner plate 4.

The high-efficiency thermal insulation material 3 comprises one or more of EPS molding polyphenyl plate, XPS extruding polyphenyl plate, graphite molding polyphenyl plate, graphite extruding polyphenyl plate, polyurethane thermal insulation material and rock wool thermal insulation material. Thereby promoting the overall heat-insulating effect of the finally formed wall body and meeting the energy-saving requirement of the energy-saving wall body structure installed by the framework structure composite heat-insulating plate keel. The high-efficiency heat insulation material 3 is preferably a spray polyurethane foam material so as to be better suitable for the non-planar structure of the keel frame system.

The outer wall inner plate 4 is made of calcium silicate boards, gypsum boards, concrete precast slabs, concrete steam-pressed aerated building blocks or ALC battens. Thereby further improving the overall heat-insulating effect of the finally formed wall body. Wherein, when outer wall inner panel 4 adopted concrete to evaporate and press aerated building block or ALC slat, connecting piece 5 can follow the outside-in setting of composite insulation panel 1, and connecting piece 5 will pass behind composite insulation panel 1 and high-efficient insulation material 3, ligature with the horizontal lacing wire that stretches out from the building structure of both sides to further promote the firmness of structure. The connection 5 may be an anchor connection 5.

The energy-saving wall structure installed by the framework structure composite heat-insulation board keel of the embodiment comprises the following steps:

step S1, splicing and connecting the metal keels 2 to each other and installing the metal keels at the beam column part 10 of the building to form a keel frame system; step S2, installing the composite heat-insulation board 1 on the outer side of the keel frame system, and firmly connecting the composite heat-insulation board 1 and the keel frame system by a connecting piece 5; step S3, arranging a high-efficiency heat-insulating material 3 at the inner side of the keel frame system; and step S4, installing the outer wall inner plate 4 on the inner side of the high-efficiency heat insulation material 3.

In order to improve the stability, firmness and other properties such as earthquake resistance and shear resistance of the keel frame system or meet the requirements of opening the window opening, the auxiliary keels which are not parallel to the vertical main keels can be arranged in a non-parallel mode when the step S1 is carried out.

In order to achieve better thermal insulation effect and material physical properties under the condition of meeting the fireproof requirement, the composite thermal insulation board 1 adopted in the step S2 can be a composite thermal insulation board 1 in which organic materials can be six-sided coated by inorganic materials.

In order to further improve the anti-falling effect, at least one layer of reinforcing net component is embedded in the organic material layer 12 and/or the inorganic material layer 11 of the composite thermal insulation board 1 adopted in the step S2, so that the anti-cracking function of the inorganic material layer 11 is achieved, and meanwhile, a structure penetrating through the embedded reinforcing net component is additionally arranged in a structure of the connecting piece 5 penetrating through the composite thermal insulation board 1 and being connected with the keel frame system.

Further, in step S2, the bottom of the keel frame system is provided with an extended bracket 8 to support the composite thermal insulation board 1, so as to improve the anti-falling safety performance of the thermal insulation material.

In order to improve the overall heat insulation effect of the finally formed wall body and meet the requirement of energy conservation of the ultra-low energy consumption building, the high-efficiency heat insulation material 3 adopted in the step S3 can be one or more of heat insulation materials such as EPS molding polystyrene board, XPS extruded polystyrene board, graphite molding polystyrene board, graphite extruded polystyrene board, polyurethane heat insulation material, rock wool and the like so as to improve the overall heat insulation effect of the finally formed wall body; and the other is sprayed with polyurethane foaming materials so as to better adapt to the non-planar structure of the keel frame system.

In order to further improve the overall heat insulation effect of the finally formed wall body, the outer wall inner plate 4 adopted in the step S4 can be a calcium silicate plate, a gypsum board, a concrete precast slab, a concrete autoclaved aerated concrete block, an ALC batten and the like.

When the outer wall inner plate 4 adopts concrete steam-pressing aerated blocks or ALC laths in the step S4, an anchoring connecting piece 5 with an anchor disc structure can be arranged from the outside to the inside of the composite heat-insulating plate 1, and after an anchor rod of the anchoring connecting piece 5 penetrates through the composite heat-insulating plate 1, the metal keel 2 and the high-efficiency heat-insulating material 3, the anchor rod is bound with transverse tie bars extending out of building structures at two sides; further improving the firmness of the structure.

In order to prevent the water seepage at the abutted seams, the end face of the composite heat-insulating board 1, which is in contact with the adjacent heat-insulating material, can be additionally provided with a waterproof structure.

Steps S5 and S6 are added after step S4, and step S5 is to perform a leveling and decoration construction process on the inner side of the outer wall/inner panel 4. And step S6, carrying out flattening and decoration construction treatment on the outer side surface of the composite heat-insulation board 1. Step S5 and step S6 may be performed sequentially or simultaneously.

For further construction efficiency and quality, the surface of the composite thermal insulation board 1 and/or the surface of the outer wall inner panel 4 adopted in the steps S1 and S4 are/is prefabricated with the integrated veneer layer 7 by a factory.

Example 2

As shown in fig. 4, the same parts of the energy-saving wall structure installed by the framework structure composite insulation board keel of the embodiment 2 as those of the embodiment 1 are not repeated, and only the differences will be described. In example 1, the inorganic material layer 11 is completely coated on the organic material layer 12. In this embodiment 2, the inorganic material layer 11 is not coated on the organic material layer 12, and the inorganic material layer 11 is connected to the outer surface of the organic material layer 12. Of course, in other embodiments, the inorganic material layer 11 may also be disposed at other positions of the organic material layer 12, and is not limited in particular.

Example 3

As shown in fig. 5, the same parts of the energy-saving wall structure installed by the framework structure composite insulation board keel of the embodiment 3 as those of the embodiment 1 are not repeated, and only the differences will be described. In this embodiment 3, the high efficiency thermal insulation material 3 is completely coated on the metal keel 2. The thickness of high-efficient insulation material 3 also can be greater than the thickness of metal joist 2 to make metal joist 2 be located high-efficient insulation material 3 and be connected with connecting piece 5, high-efficient insulation material 3 wraps up in the medial surface of metal joist 2 completely.

The above disclosure is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the scope of the invention, which is defined by the appended claims.

Claims (10)

1. An energy-saving wall structure installed by framework structure composite heat-insulation board keels is characterized in that, which comprises a composite heat-insulating plate, a metal keel, a connecting piece, a high-efficiency heat-insulating material and an outer wall inner plate, the metal keel is used for being arranged inside a beam column part of a building, the composite heat-insulation board is arranged outside the metal keel, the connecting piece is connected with the composite heat-insulating board and the outer side of the metal keel, the composite heat-insulating board comprises an organic material layer and an inorganic material layer, the inorganic material layer is connected with the outer side surface of the organic material layer, the high-efficiency heat-insulating material is positioned between the outer wall inner plate and the inner side of the composite heat-insulating plate, and the high-efficiency heat-insulating material is connected with the metal keel, and the inner plate of the outer wall is connected with the beam column part of the building and/or the metal keel.

2. An energy saving wall structure with framing structure composite insulation board keel mounted according to claim 1, wherein the inorganic material layer is completely coated on the organic material layer, so that the organic material layer is located in the inorganic material layer.

3. The frame structure composite insulation panel keel mounted energy saving wall structure of claim 1, further comprising brackets connected to said metal keel and lining the end faces of said composite insulation panels.

4. A frame structure composite insulation panel keel mounted energy saving wall structure as claimed in claim 1, wherein said metal keel comprises main keel for connection with structural beam and/or column in said building beam column portion and cross keels distributed vertically and/or obliquely and connected to said main keel.

5. A framework structure composite insulation panel keel mounted energy saving wall structure as claimed in claim 1, wherein said organic material layer comprises one or more of but not limited to XPS extruded sheet, EPS polystyrene board;

and/or the material of the inorganic material layer is polymer mortar.

6. A framework structure composite insulation panel keel mounted energy saving wall structure as claimed in claim 1, wherein said organic material layer and/or said inorganic material layer has at least one reinforcing mesh component therein.

7. The energy-saving wall structure installed by the framework structure composite heat-insulation plate keel according to claim 1, wherein the high-efficiency heat-insulation material is embedded in the metal keel, so that the inner side and the outer side of the metal keel are respectively abutted against the outer wall inner plate and the composite heat-insulation plate;

or the high-efficiency heat-insulating material is completely coated on the metal keel.

8. The energy-saving wall structure installed by the framework structure composite insulation board keel according to claim 1, wherein the energy-saving wall structure installed by the framework structure composite insulation board keel further comprises an adhesive layer, and the adhesive layer is located between the high-efficiency insulation material and the outer wall inner plate and connected with the high-efficiency insulation material and the outer wall inner plate.

9. An energy-saving wall structure installed by framing construction composite insulation board keels according to claim 1, wherein the high efficiency insulation material includes but is not limited to one or more of EPS molded polystyrene board, XPS extruded polystyrene board, graphite molded polystyrene board, graphite extruded polystyrene board, polyurethane insulation material, rock wool insulation material;

and/or the outer wall inner plate is made of calcium silicate plates, gypsum plates, concrete precast slabs, concrete autoclaved aerated concrete blocks or ALC laths.

10. The energy-saving wall structure installed on the framework structure composite insulation board keel according to claim 1, wherein the energy-saving wall structure installed on the framework structure composite insulation board keel further comprises a facing layer, the facing layer comprises anti-crack mortar and alkali-resistant fiberglass gridding cloth, the anti-crack mortar is connected to the outer side surface of the composite insulation board, and the alkali-resistant fiberglass gridding cloth is arranged in the anti-crack mortar;

and/or the outer surface of the composite heat-insulation board and/or the outer wall inner board is provided with a finishing coat.

Images