CN217759390U - Heat preservation lines component of prefabricated integrated bearing installation component and energy-saving wall body structure thereof - Google Patents

Abstract

The utility model discloses a prefabricated integrated bearing installation component's heat preservation lines component and energy-conserving wall body structure thereof, prefabricated integrated bearing installation component's heat preservation lines component includes L type bearing installation component, the heat preservation lines, the insulation material layer with link wall spare, L type bearing installation component includes interconnect's first mounting panel and second mounting panel, first mounting panel and heat preservation lines are connected respectively in the inside and outside both sides on insulation material layer, and first mounting panel laminating in insulation material layer's medial surface, the one end of linking wall spare is connected in insulation material layer, the other end of linking wall spare passes first mounting panel and is used for being connected with basic unit's wall body, the second mounting panel laminating in insulation material layer's terminal surface, and the second mounting panel is connected in insulation material layer and is used for meeting with energy-conserving window and/or heat preservation. Effectively promote the installation degree of stability, effectively avoid taking place to break away from the problem for energy-conserving window is held in the bearing of L type installation component, and insulation material layer load alleviates greatly.

Description

Heat preservation lines component of prefabricated integrated bearing installation component and energy-saving wall body structure thereof

Technical Field

The utility model relates to a prefabricated integrated bearing installation component's heat preservation lines component and energy-conserving wall body structure thereof.

Background

At present, the building energy consumption of China is about 1/3 of the total social energy consumption, the high-energy-consumption building proportion is high, and the building energy-saving pressure is high. The demand of building energy conservation is increasingly prominent under the large environment of energy conservation and emission reduction and achieving the aim of 'double carbon' as soon as possible. In recent years, the building energy-saving standards of all parts of the country are gradually improved according to the actual conditions of all parts of the country, and higher building energy-saving standard requirements such as 'ultra-low energy consumption building standards' are more provided. Besides energy saving and emission reduction of equipment, the requirements of building heat preservation and door and window energy saving are higher and higher. Under the increasing energy-saving requirement, the conventional method adopted in the field of building heat preservation for meeting the requirement of building energy conservation at present is to realize better energy-saving effect through a thickened heat preservation layer; the energy saving aspect of the door and window adopts the form of three-glass two-cavity and energy-saving window frame to meet the energy saving requirement. Although the method can solve the problem of building energy conservation, the method brings a series of problems that the safety accidents of hollowing, cracking, falling off and the like of the heat-insulating layer caused by over-thick heat-insulating layer are caused, and the like compared with the traditional window frame of the energy-saving window frame due to the dead weight, the energy-saving window frame can only be arranged on a concrete structure for realizing firm installation, so that the integrity and the continuity of a building heat-insulating system are influenced.

Meanwhile, with the increasing of the building design concept, in more and more building facade design schemes in recent years, heat insulation lines for decoration are arranged between layers and on the side edge of a window so as to increase the stereoscopic impression and the aesthetic degree of a building, but the construction can be carried out only by adopting a method of pasting the lines with mortar. After the method is used for a period of time, the conditions of line separation, edge warping and even falling caused by the quality problems of construction or used materials often occur. At present, a solution scheme that a heat-insulating layer safety support and an energy-saving window frame which can meet the higher standard energy-saving requirements of buildings are firmly installed on a better part (above a heat-insulating layer) and a decorative line can be simply and efficiently installed is urgently needed, so that the multiple requirements of the heat-insulating layer support, the window frame installation and the line installation at the part are met.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the above-mentioned not enough of current existence, the utility model provides a prefabricated integrated bearing installation component's heat preservation lines component and energy-conserving wall body structure thereof.

The utility model discloses a realize through following technical scheme:

the utility model provides a prefabricated integrated bearing installation component's heat preservation lines component, its includes L type bearing installation component, heat preservation lines, insulation material layer and links the wall spare, L type bearing installation component includes interconnect's first mounting panel and second mounting panel, first mounting panel with the heat preservation lines connect respectively in the inside and outside both sides of insulation material layer, just first mounting panel laminate in the medial surface of insulation material layer, the one end of linking the wall spare connect in the insulation material layer, the other end of linking the wall spare passes first mounting panel is used for being connected with basic unit's wall body, the second mounting panel laminate in the terminal surface of insulation material layer, just the second mounting panel connect in the insulation material layer is used for meeting with energy-conserving window and/or heat preservation.

Furthermore, the heat preservation lines with the heat preservation material layer is split type structure, the heat preservation lines component of prefabricated integrated bearing installation component still includes adapting unit, adapting unit connect in the heat preservation lines with the heat preservation material layer.

Further, adapting unit includes connecting sleeve and connecting screw, connecting sleeve is pre-buried and connect in the insulation material layer is in situ, connecting sleeve has expose in the connection chamber of insulation material layer lateral surface, connecting screw's one end connect in connect the intracavity, connecting screw's the other end connect in the heat preservation lines.

Furthermore, an opening is formed in one end, facing the first mounting plate, of the connecting sleeve, the opening is communicated with the connecting cavity, and the end of the wall connecting piece penetrates through the opening and is connected with the connecting cavity;

and/or the connecting sleeve is connected to the first mounting plate.

Furthermore, a first reinforcing net is arranged in the heat-insulating material layer, and the wall connecting piece and/or the connecting piece are/is connected to the first reinforcing net;

and/or a second reinforcing net is arranged in the heat preservation line, and the connecting part is connected to the second reinforcing net.

Further, the heat insulation line and the heat insulation material layer are integrally formed;

and/or the heat-insulating material layer is made of A-grade fireproof heat-insulating material.

Furthermore, the wall connecting piece comprises an anchor disc and an anchor rod, the anchor disc is abutted against the outer side face of the heat insulation material layer, one end of the anchor rod is connected to the anchor disc, and the other end of the anchor rod penetrates through the heat insulation material layer and the first mounting plate and is connected with the base layer wall;

and/or the heat insulation material layer is made of an organic-inorganic composite heat insulation material.

Furthermore, the L-shaped bearing installation component also comprises a reinforcing rib which is arranged on the side edge of the heat insulation material layer in advance and is connected with the first installation plate and the second installation plate;

and/or the L-shaped bearing mounting component also comprises at least one convex rib, one end of the convex rib is connected with the first mounting plate and/or the second mounting plate, and the other end of the convex rib extends into the heat-insulating material layer and is connected with the heat-insulating material layer;

and/or the heat-insulating material layer is made of a silicon graphene heat-insulating material.

An energy-saving wall structure comprises a basic wall, an energy-saving window, an insulating layer and the insulating line member which is prefabricated, integrated and supports an installation part.

Furthermore, the energy-saving wall structure also comprises a finishing layer and/or a finishing layer, wherein the finishing layer and/or the finishing layer are connected to the outer side surface of the heat-insulating line component of the prefabricated integrated bearing installation component;

and/or, energy-conserving wall body structure still includes the screed-coat, the screed-coat connect in the medial surface of basic unit's wall body.

The beneficial effects of the utility model reside in that:

the utility model discloses a prefabricated integrated bearing installation component's heat preservation lines component and energy-conserving wall body structure thereof, L type bearing installation component set up between insulation material layer and basic unit's wall body through first mounting panel, realize that insulation lines, L type bearing installation component, insulation material layer and basic unit's wall body are connected as a whole, effectively promote the installation degree of stability, effectively avoid taking place to break away from the problem, have improved the safety and stability nature of energy-conserving wall body structure greatly. Simultaneously, L type bearing installation component passes through second mounting panel erection joint in insulation material layer and energy-conserving window for L type bearing installation component holds and holds energy-conserving window, and insulation material layer load alleviates greatly, makes the great energy-conserving window of dead weight realize installing the better installation node of this kind of heat preservation effect on the insulation material layer.

Drawings

Fig. 1 is the utility model discloses embodiment 1's integrated bearing installation component's of prefabrication heat preservation lines component's internal structure sketch map.

Fig. 2 is an internal structural schematic view of an energy-saving wall structure according to embodiment 1 of the present invention.

Fig. 3 is the internal structure diagram of the heat preservation line member of the prefabricated integrated bearing installation component of embodiment 2 of the present invention.

Fig. 4 is an internal schematic structural diagram of an energy-saving wall structure according to embodiment 2 of the present invention.

Figure 5 is the utility model discloses embodiment 3's prefabricated integrated bearing installation component's heat preservation lines component's internal structure schematic diagram.

Fig. 6 is an internal structural schematic view of an energy-saving wall structure according to embodiment 3 of the present invention.

Figure 7 is the utility model discloses embodiment 4's integrated bearing installation component's of prefabricating internal structure schematic diagram of moulding component that keeps warm.

Fig. 8 is an internal structural schematic view of an energy-saving wall structure according to embodiment 4 of the present invention.

Fig. 9 is an internal structural view of a heat insulating line member of a prefabricated integrated bearing mounting component according to embodiment 5 of the present invention.

Fig. 10 is a schematic view of an internal structure of an energy-saving wall structure according to embodiment 5 of the present invention.

Fig. 11 is a schematic diagram of the internal structure of the energy-saving wall structure according to embodiment 6 of the present invention during construction.

Fig. 12 is an internal schematic structural view of an energy-saving wall structure according to embodiment 6 of the present invention.

Description of the reference numerals:

insulating material layer 1

First reinforcing mesh 11

Heat preservation line 2

Second reinforcing mesh 21

L-shaped support mounting member 3

First mounting plate 31

Second mounting plate 32

Reinforcing ribs 33

Convex rib 34

Wall connecting piece 4

Anchor disc 41

Anchor rod 42

Connecting part 5

Connecting sleeve 51

Connection cavity 511

Connecting screw 52

Anchoring connection 6

Base wall 10

Energy saving window 20

Finishing layer 30

Leveling course 40

Thermal insulation layer 50

Detailed Description

The following description of the various 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 and 2, the present embodiment discloses an energy-saving wall structure, which includes a basement wall 10, an energy-saving window 20, and a heat-insulating strip member prefabricated to support and mount a component. The heat preservation line component of the prefabricated integrated bearing installation component comprises a heat preservation material layer 1, a heat preservation line 2, an L-shaped bearing installation component 3 and a wall connecting piece 4, the L-shaped bearing installation component 3 comprises a first installation plate 31 and a second installation plate 32 which are connected with each other, the first installation plate 31 and the heat preservation line 2 are respectively connected to the inner side and the outer side of the heat preservation material layer 1, the first installation plate 31 is attached to the inner side face of the heat preservation material layer 1, one end of the wall connecting piece 4 is connected to the heat preservation material layer 1, and the other end of the wall connecting piece 4 penetrates through the first installation plate 31 and is connected with a base wall 10.

Basic unit's wall body 10 and heat preservation lines 2 connect respectively in the inside and outside both sides of insulation material layer 1, first mounting panel 31 sets up between insulation material layer 1 and basic unit's wall body 10, pass first mounting panel 31 through even wall spare 4 and be connected in insulation material layer 1 and basic unit's wall body 10, realize heat preservation lines 2, L type bearing installation component 3, insulation material layer 1 and basic unit's wall body 10 are connected into a whole, effectively promote the installation degree of stability, effectively avoid taking place to break away from the problem, the safety and stability of energy-conserving wall body structure has been improved greatly.

The second mounting plate 32 is attached to the end face of the thermal insulation material layer 1, and the second mounting plate 32 is connected to the thermal insulation material layer 1 and used for being connected to the energy saving window 20. First mounting panel 31 is laminated in insulation material layer 1's medial surface, second mounting panel 32 is laminated in insulation material layer 1's terminal surface, L type bearing installation component 3 passes through second mounting panel 32 erection joint in insulation material layer 1 and energy-conserving window 20, make L type bearing installation component 3 bearing live energy-conserving window 20 and not in basic unit's wall body 10 top, insulation material layer 1 load alleviates greatly, make the great energy-conserving window 20 of dead weight realize installing the better installation node of this kind of heat preservation effect on insulation material layer 1.

Be equipped with first reinforcing mesh 11 in the insulation material layer 1, link wall spare 4 is connected in first reinforcing mesh 11. Can effectively strengthen insulation material layer 1's self structural strength through first reinforcing mesh 11, and effectively strengthened insulation material layer 1, link wall spare 4 and basic unit's wall body 10 joint strength, further improved the safety and stability of energy-conserving wall body structure. The first reinforcing mesh 11 may be a metal reinforcing mesh or an FRP reinforcing mesh.

In this embodiment, the wall connecting member 4 includes an anchor plate 41 and an anchor rod 42, the anchor plate 41 is abutted against the outer side surface of the thermal insulation material layer 1, one end of the anchor rod 42 is connected to the anchor plate 41, and the other end of the anchor rod 42 penetrates through the thermal insulation material layer 1 and the first mounting plate 31 and is connected with the base wall 10. The wall connecting piece 4 is abutted against the outer side face of the heat insulation material layer 1 through the anchor disc 41 and is connected with the base layer wall body 10 through the anchor rod 42, so that the connection strength between the heat insulation material layer 1, the L-shaped bearing mounting component 3 and the wall connecting piece 4 is effectively enhanced, and the safety and stability of the energy-saving wall structure are further improved. Meanwhile, the structure is simple, and the use is convenient.

The first mounting plate 31 is provided with a through hole, and the anchor rod 42 passes through the through hole and extends out of the inner side surface of the thermal insulation material layer 1, so as to be conveniently connected with the base layer wall 10. The anchor rod 42 can be provided with external threads, and the anchor rod 42 can be connected with a nut and used for clamping the first mounting plate 31 and the thermal insulation material layer 1, so that the structural connection strength of the thermal insulation line member of the prefabricated integrated bearing mounting component is effectively enhanced. Certainly, in other embodiments, the wall connecting member 4 may also pass through the thermal insulation strips 2, the thermal insulation material layer 1, and the first mounting plate 31 from the outer side surfaces of the thermal insulation strips 2 and be connected with the base wall 10, so as to further enhance the structural connection strength of the thermal insulation strip member of the prefabricated integrated bearing and mounting component.

The heat preservation line component of prefabricated integrated bearing installation component still includes anchor connecting piece 6, and the lateral surface of anchor connecting piece 6 self preservation temperature material layer 1 plays to pass insulation material layer 1 and first mounting panel 31 and is connected with basic unit's wall body 10, and anchor connecting piece 6 supports and leans on in insulation material layer 1's lateral surface. Can link together insulation material layer 1, L type bearing installation component 3 with even wall spare 4 through anchor connecting piece 6, effectively strengthen the joint strength of the heat preservation lines component of prefabricated integrated bearing installation component, improve the safety and stability of energy-conserving wall body structure greatly.

The material of the heat-insulating material layer 1 is an A-grade fireproof heat-insulating material, so that the heat-insulating property and the fireproof property of the energy-saving wall structure are effectively improved. Wherein, the material of the heat insulation material layer 1 is an organic-inorganic composite heat insulation material. The heat-insulating property of the organic-inorganic composite A-grade fireproof heat-insulating material can ensure that the strength meets the standard requirements of related products under the condition of the heat-insulating material with the same thickness, the fireproof property reaches A2 grade, and an inorganic plate is not required to be compounded to enhance the strength and the fireproof property.

The thermal insulation material layer 1 is made of a silicon graphene thermal insulation material. The heat preservation performance and the fire behavior of the heat preservation lines component of prefabricated integrated bearing installation component have effectively been guaranteed, the safety and stability nature of energy-conserving wall body structure has been improved greatly.

The material of the heat preservation line 2 can be the same as that of the heat preservation material layer 1. In this embodiment, the heat-insulating molding 2 and the heat-insulating material layer 1 are integrally molded. The heat-preservation raw materials are injected into the die and integrally processed and molded, so that the die is convenient to process and manufacture, does not need subsequent assembly and is very convenient to use; and the structural connection strength between the heat preservation lines 2 and the heat preservation material layer 1 is high, and the stability is high.

The energy-saving wall structure further comprises a plastering layer 30, and the plastering layer 30 is connected to the outer side face of the heat-insulating line component of the prefabricated integrated bearing installation component. The rendering coat layer 30 is connected to the outer side surfaces of the heat insulation material layer 1 and the heat insulation lines 2, and the outer side surfaces of the heat insulation material layer 1 and the heat insulation lines 2 can be effectively protected through the rendering coat layer 30, so that the stability of the energy-saving wall structure is further improved. The finishing layer 30 may be connected to the heat insulating material layer 1 and the partial end face of the heat insulating line 2 facing the energy saving window 20.

The plastering layer 30 comprises anti-crack mortar and alkali-resistant glass fiber gridding cloth, the anti-crack mortar is connected to the outer side surfaces of the heat insulation material layer 1 and the heat insulation line 2, and the alkali-resistant glass fiber gridding cloth is arranged in the anti-crack mortar. The anti-crack mortar is used for leveling protection, the alkali-resistant glass fiber grids are arranged in the anti-crack mortar, the integral structural firmness of the plastering layer 30 can be enhanced, and the safety and stability of the energy-saving wall structure are improved.

The energy-saving wall structure further comprises a finishing layer, and the finishing layer can be connected to one side of the rendering layer 30, which is back to the base layer wall 10. The energy-saving wall body structure is protected and the building is beautified through the veneer layer, and the use requirement is met. Wherein, the facing layer comprises paint, ceramic tiles, stone, metal plates and the like.

The wall construction further includes a screed 40, the screed 40 being attached to the inner side of the substrate wall 10. Wherein, the leveling layer 40 is connected to a part of the end surface of the base layer wall 10 facing the energy saving window 20. The leveling layer 40 can be used for leveling and protecting the base layer wall 10. The screed 40 may be mortar.

In this embodiment, a height difference is formed between the end surface of the energy saving window 20 and the end surface of the base wall 10 in the insulating molding member of the prefabricated integrated bearing and mounting component, so that the inner side surface of the energy saving window 20 is attached to and abutted against the outer side surface of the base wall 10. The terminal surface of insulating material layer 1 towards energy-conserving window 20 will be less than a terminal surface of basic unit's wall body 10 towards energy-conserving window 20 for the bottom of energy-conserving window 20 will be less than the up end of basic unit's wall body 10, and the lateral surface of basic unit's wall body 10 will laminate and lean on in the bottom of energy-conserving window 20 and the gap department between the heat preservation lines component of prefabricated integrated bearing installation component, with the waterproof construction of high outside low in forming, thereby improved the water-proof effects of energy-conserving wall body structure.

Example 2

As shown in fig. 3 and 4, the same parts of the energy-saving wall structure of embodiment 2 as those of embodiment 1 will not be repeated, and only the differences will be described. In this embodiment 2, insulating material layer 1 and heat preservation lines 2 are split type structure rather than integrated into one piece, and prefabricated integrated bearing installation component's heat preservation lines component still includes adapting unit 5, and adapting unit 5 is connected in heat preservation lines 2 and insulating material layer 1. The heat insulation material layer 1 and the heat insulation line 2 are respectively used for processing and manufacturing, and then the heat insulation material layer 1 and the heat insulation line 2 are assembled together through a connecting part 5.

In this embodiment 2, the connection part 5 includes a connection sleeve 51 and a connection screw 52, the connection sleeve 51 is embedded and connected in the thermal insulation material layer 1, the connection sleeve 51 has a connection cavity 511 exposed on the outer side surface of the thermal insulation material layer 1, one end of the connection screw 52 is connected in the connection cavity 511, and the other end of the connection screw 52 is connected to the thermal insulation strip 2. The connecting part 5 is formed by pre-burying the connecting sleeve 51 into the heat insulation material layer 1 and then connecting the connecting screw 52 into the connecting cavity 511 of the connecting sleeve 51, so that the heat insulation line 2 positioned on the connecting screw 52 is installed on the outer side surface of the heat insulation material layer 1. The connecting cavity 511 is an internal thread, the connecting screw rod 52 and the connecting sleeve 51 are in threaded connection, the mounting and the connection are very convenient, the structure is simple, and the processing and the manufacturing are convenient.

In this embodiment 2, when the thermal insulation line 2 adopts the post-installation form, a connecting sleeve 51 may be additionally provided in the thermal insulation material layer 1, a connecting cavity 511 matched with the connecting screw 52 on the thermal insulation line 2 is provided in the connecting sleeve 51, and the thermal insulation line 2 is installed on the outer side surface of the thermal insulation material layer 1 through the connecting screw 52 and the connecting sleeve 51 in a mechanical connection manner. Compared with the integral forming manufacturing, the mode is more beneficial to the construction/manufacturing operation of the heat preservation line member and the base wall 10 of the prefabricated integrated bearing installation component through the heat preservation and structure integration process (the disassembly-free heat preservation formwork process or the prefabricated concrete integrated heat preservation wall member manufacturing process), the damage to the convex heat preservation line 2 in the construction/manufacturing process is effectively avoided, and the manufacturing cost is increased (if the prefabricated member mould table does not need to be matched with the convex line molding for mould making and mould changing).

The connecting member 5 is connected to the first reinforcing mesh 11. Connecting sleeve 51 is pre-buried in to insulation material layer 1 and is connected with first reinforcing mesh 11, effectively strengthens adapting unit 5 and insulation material layer 1's joint strength, has further improved the safety and stability of the heat preservation lines component of prefabricated integrated bearing installation component.

A second reinforcing net 21 is arranged in the heat preservation line 2, and the connecting part 5 is connected to the second reinforcing net 21. The self structural strength of the heat preservation line 2 can be effectively enhanced through the second reinforcing mesh 21; meanwhile, one end of the connecting screw rod 52 penetrates through the heat preservation line 2 and is connected with the gasket nut, the other end of the connecting screw rod 52 is connected into the connecting cavity 511, the connecting screw rod 52 penetrates through and is connected to the second reinforcing net 21, the connecting strength of the connecting part 5 and the heat preservation line 2 is effectively enhanced, and the safety and stability of the heat preservation line component of the prefabricated integrated bearing installation part are further improved. The second reinforcing mesh 21 may be a metal reinforcing mesh or an FRP reinforcing mesh.

Example 3

As shown in fig. 5 and fig. 6, the same parts of the energy-saving wall structure of the embodiment 3 as those of the embodiment 2 will not be repeated, and only the differences will be described. In this embodiment 3, the length of the connecting sleeve 51 is smaller than the thickness of the thermal insulation material layer 1, and the connecting sleeve 51 is close to the left end of the thermal insulation material layer 1. In embodiment 3, the connection sleeve 51 is connected to the first mounting plate 31. The connecting sleeve 51 is connected with the L-shaped bearing installation component 3 into a whole in advance, and is connected with the basic layer wall body 10 through the L-shaped bearing installation component 3, so that the installation firmness of the heat preservation line 2 is further increased, and the stability of the energy-saving wall body structure is greatly improved.

In this embodiment 3, the length of the connecting sleeve 51 is equal to the thickness of the thermal insulation material layer 1, the left end of the connecting sleeve 51 is provided with an opening, the opening is communicated with the connecting cavity 511, the connecting screw 52 is connected with the connecting cavity 511 through the opening, and the right end of the connecting sleeve 51 is connected to the first mounting plate 31, so that the connecting sleeve 51 and the L-shaped bearing mounting component 3 are integrated in advance.

Example 4

As shown in fig. 7 and 8, the same parts of the energy-saving wall structure of the embodiment 4 as those of the embodiment 3 will not be repeated, and only the differences will be described. In the embodiment 4, an end of the connecting sleeve 51 facing the first mounting plate 31 is provided with an opening, the opening is communicated with the connecting cavity 511, and an end of the wall connecting member 4 passes through the opening and is connected to the connecting cavity 511. The connecting screw rod 52 is connected in the connecting cavity 511 at the left end of the connecting sleeve 51, the wall connecting piece 4 is connected in the connecting cavity 511 at the right end of the connecting sleeve 51, and the heat insulation line 2, the heat insulation material layer 1, the L-shaped bearing installation component 3 and the base layer wall 10 are connected into a whole through the connecting component 5 and the wall connecting piece 4, so that the installation stability of the energy-saving wall structure is further improved, and the stability of the energy-saving wall structure is greatly improved.

In the present embodiment, the number of the connection chambers 511 is two, and the two connection chambers 511 are respectively located at the left and right ends of the connection sleeve 51. Of course, the number of the connection cavities 511 may also be one, and one connection cavity 511 will penetrate the connection sleeve 51.

Example 5

As shown in fig. 9 and 10, the same parts of the energy-saving wall structure of the embodiment 5 as those of the embodiment 1 will not be repeated, and only the differences will be described. In this embodiment 5, the L-shaped supporting and mounting member 3 further includes a reinforcing rib 33, and the reinforcing rib 33 is pre-installed on the side of the thermal insulation material layer 1 and connected to the first mounting plate 31 and the second mounting plate 32. The reinforcing rib 33 can effectively reinforce the connection strength between the first mounting plate 31 and the second mounting plate 32, so that the stability and firmness of the L-shaped bearing mounting component 3 are improved, the connection strength between the L-shaped bearing mounting component 3 and the heat insulation material layer 1 is effectively reinforced, and the stability and reliability of the heat insulation line component of the prefabricated integrated bearing mounting component are further improved; and the L-shaped bearer mounting member is realized to have an effective support for the energy saving window 20. Wherein the number of the reinforcing ribs 33 is plural.

The L-shaped bearing installation component 3 also comprises at least one convex rib 34, one end of the convex rib 34 is connected with the first installation plate 31 and/or the second installation plate 32, and the other end of the convex rib 34 extends into the thermal insulation material layer 1 and is connected with the thermal insulation material layer 1. Will go deep into through protruding muscle 34 and be connected to insulation material layer 1 in to effectively having strengthened the joint strength between L type bearing installation component 3 and the insulation material layer 1, further improved the reliable and stable nature of the heat preservation lines component of prefabricated integrated bearing installation component.

Example 6

As shown in fig. 11 and 12, the same parts of the energy-saving wall structure of the present embodiment 6 as those of the embodiment 2 will not be repeated, and only the differences will be described. In this embodiment 6, this energy-conserving wall body structure includes heat preservation 50, and the bottom surface laminating of second mounting panel 32 is connected in heat preservation 1's terminal surface and with heat preservation 1, and heat preservation 50 will set up the top surface at second mounting panel 32, and second mounting panel 32 will have the bearing effect to heat preservation 50 to effectively realize fixed mounting to heat preservation 50, improved the safety and stability nature of energy-conserving wall body structure greatly.

In this embodiment 6, one end of the wall connecting member 4 is connected to the first mounting plate 31, and the other end is located inside the substrate wall 10 and connected to the substrate wall 10. The wall connecting piece 4 is provided with a bending part, so that the connecting strength of the wall connecting piece 4 and the base layer wall 10 is effectively enhanced, the separation problem is effectively avoided, and the safety and stability of the energy-saving wall structure are greatly improved; meanwhile, the structure is simple, and the processing and the manufacturing are very convenient. Of course, in other embodiments, the wall connecting member 4 may be rod-shaped, and the outer surface of the wall connecting member 4 may be provided with a rugged structure of protrusions and/or grooves.

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. The utility model provides a prefabricated integrated bearing installation component's heat preservation lines component, its characterized in that, it includes L type bearing installation component, heat preservation lines, insulation material layer and links the wall spare, L type bearing installation component includes interconnect's first mounting panel and second mounting panel, first mounting panel with the heat preservation lines connect respectively in the inside and outside both sides of insulation material layer, just first mounting panel laminate in the medial surface of insulation material layer, the one end of linking the wall spare connect in the insulation material layer, the other end of linking the wall spare passes first mounting panel is used for being connected with basic unit's wall body, the second mounting panel laminate in the terminal surface of insulation material layer, just the second mounting panel connect in the insulation material layer is used for meeting with energy-conserving window and/or heat preservation.

2. The preformed integrated bearer mounting component molding according to claim 1 wherein said molding and said insulating material layer are of split construction, said molding further comprising a connecting member connected to said molding and said insulating material layer.

3. The prefabricated integrated bearer mounting assembly thermal insulation line component of claim 2, wherein the connecting part comprises a connecting sleeve and a connecting screw, the connecting sleeve is embedded and connected in the thermal insulation material layer, the connecting sleeve is provided with a connecting cavity exposed on the outer side surface of the thermal insulation material layer, one end of the connecting screw is connected in the connecting cavity, and the other end of the connecting screw is connected to the thermal insulation line.

4. The preformed integrated bearer mounting component fox molding according to claim 3, wherein the connecting sleeve has an opening at an end facing the first mounting plate, the opening communicating with the connecting cavity, and an end of the wall connecting member passing through the opening and connecting to the connecting cavity;

and/or the connecting sleeve is connected to the first mounting plate.

5. The preformed integrated bearer attachment member molding according to claim 2 wherein a first reinforcement mesh is provided within said insulating material layer, said wall connecting member and/or said attachment member being attached to said first reinforcement mesh;

and/or a second reinforcing net is arranged in the heat preservation line, and the connecting part is connected to the second reinforcing net.

6. The preformed integrated bearer attachment member molding according to claim 1 wherein said molding and said layer of insulating material are integrally formed;

and/or the heat-insulating material layer is made of A-grade fireproof heat-insulating material.

7. The prefabricated integrated bearer mounting component molding according to claim 1, wherein said wall connecting member comprises an anchor plate and an anchor rod, said anchor plate is abutted against the outer side surface of said insulating material layer, one end of said anchor rod is connected to said anchor plate, and the other end of said anchor rod passes through said insulating material layer and said first mounting plate and is connected to said substrate wall;

and/or the heat insulation material layer is made of an organic-inorganic composite heat insulation material.

8. The preformed integrated bearer mounting component fox molding an insulating strand according to claim 1, wherein the L-shaped bearer mounting component further comprises stiffening ribs predisposed on the sides of the insulating material layer and connected to the first mounting plate and the second mounting plate;

and/or the L-shaped bearing mounting component also comprises at least one convex rib, one end of the convex rib is connected with the first mounting plate and/or the second mounting plate, and the other end of the convex rib extends into the heat-insulating material layer and is connected with the heat-insulating material layer;

and/or the heat-insulating material layer is made of a silicon graphene heat-insulating material.

9. An energy saving wall structure, characterized in that it comprises a basement wall, an energy saving window, an insulating layer and an insulating line member of a prefabricated integrated bearer mounting unit according to any one of claims 1-8.

10. The energy saving wall structure of claim 9, further comprising a finishing layer and/or a finishing layer, wherein the finishing layer and/or the finishing layer is attached to an outer side surface of the insulating line member of the prefabricated integrated bearing installation member;

and/or, energy-conserving wall body structure still includes the screed-coat, the screed-coat connect in the medial surface of basic unit's wall body.

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