CN219364998U - Full-assembled decoration and heat preservation integrated structure - Google Patents

Abstract

The utility model provides a full assembly decorates heat preservation integrated structure, includes the cement-based artificial stone slab body of taking the veneer, the nut has been buried in slab body back, the screw of nut is located the back of slab body, and the screw internal screw of nut has connecting screw, wears to be equipped with metal string A, heat preservation material layer, metal string B on the connecting screw, metal string A and metal string B are put the heat preservation material layer in the middle of with the clamp, and connecting screw's outer end screw has the first gland nut of pressing metal string B at heat preservation material layer back, and metal string A and metal string B are located the position in slab body edge outside and are equipped with the dress through-hole of hanging. The metal hanging strip A can completely control the flatness of the plate, and can form a fully assembled installation structure for clamping any heat insulation material by combining the metal hanging strip B, thereby thoroughly solving various defects and hidden dangers of the prior chemical glue, mortar, clamping anchors, single hanging strip and the like.

Description

Full-assembled decoration and heat preservation integrated structure

Technical Field

The utility model relates to the field of building decoration, in particular to a full-assembled decoration and heat preservation integrated structure.

Background

Energy conservation and carbon reduction have been related to human survival and development. And the carbon emission in the using process of the building accounts for nearly one third of the total carbon emission, so that the energy conservation and carbon reduction of the building are imperative. Whether the building can realize energy conservation or not, the key point is whether the enclosure system has efficient heat preservation and heat insulation functions. The heat insulating materials are fixedly arranged inside and outside the building outer enclosure wall, so that the heat insulating material is a main technical means for solving the heat insulating problem of the building in the prior art, and the surface of the inner wall and the outer wall of the building is required to be provided with decoration after the heat insulating materials are arranged, so that the building can be a usable finished energy-saving building. The use of the thin plastering insulation systems of the prior art has gradually been reduced due to various drawbacks. The main principle of the existing heat-insulating and decorating integrated plate is that a solid stone plate, a metal plate, a silicon-calcium plate and the like are adopted as facing plates, and then the facing plates and heat-insulating materials such as extruded sheets and rock wool are compounded to form the integrated plate. Because the solid facing plates and the heat insulation materials do not have the connecting function, the existing heat insulation and decoration integrated plate can be formed by combining the facing plates and the heat insulation materials only by adopting chemical glue. When the chemical glue is used for adhering filiform and flocculent heat-insulating materials such as rock wool, glass wool and the like, the bonding strength of the heat-insulating materials is extremely low, so that the heat-insulating materials are extremely difficult to adhere and compound, but the heat-insulating materials are generally A-level fireproof materials, the existing heat-insulating and decorating integrated plate can only be adhered in multiple layers by using the chemical glue, a bottom plate and the like, the cost is increased, and the probability of layering and falling is increased as the chemical glue which is inevitably degraded is used more. The composite heat-insulating and decorating integrated plate has no external connection function, and can be mounted only by means of adhesive bonding of mortar, so that the viscosity of the mortar can be reduced, and a great potential safety hazard is necessarily formed. In order to prevent the thermal insulation and decoration integrated plate pasted by mortar from falling off, the clamping anchor reinforcing mode of a metal clamp is added on the side surface of the integrated plate in the prior art, but the metal clamp can only perform connection and fixation by slotting and punching on a solid veneer, if slotting or punching is performed on a thinner veneer plate, the thin plate is easy to collapse and fall off, and meanwhile, the hanging force is small and the anti-seismic performance is poor; if thicker plates are adopted, although a certain hanging strength is increased, the plates with large weight are difficult to ensure the safety of the metal clips, and if the natural stone is feasible, the large metal framework is used for dry hanging at a very high cost. Therefore, the existing heat-insulating and decorating integrated plate has great potential safety hazard of falling off. To solve the problems, patent (201610259172X) is a production and installation method of a nano cement-based high-strength artificial slab stone with heat preservation, patent (2016203512307) is a nano cement-based high-strength artificial slab stone with heat preservation, patent (2018114914707) is a cement-based ultra-high-performance artificial stone heat preservation and sound insulation integrated plate, and patent (patent number: 2018114916100) is a production and installation method of a cement-based ultra-high-performance artificial stone heat preservation and sound insulation integrated plate. Above-mentioned patent adopts cement-based material preparation to form artificial stone panel to bury the nut in panel back, wear to establish extruded sheet, rock wool etc. insulation material after implanting the screw rod in the nut, the screw rod wears to establish metal string after passing insulation material at the screw rod tip, and fix metal string at insulation material back through the nut, metal string can produce the clamping effect to insulation material certainly, install cement-based insulation decoration intergral template at the wall body through metal string at last, thereby solve the composite insulation decoration intergral template of solid panel such as current stone material, calcium silicate board, can only adopt mortar to paste or increase the various potential safety hazards that the anchor reinforcement exists. However, if the metal hanging strip is clamped by the heat-insulating material, the veneer and the heat-insulating material are adhered without chemical glue, after the metal hanging strip is fixedly installed through the expansion bolt, the clamped heat-insulating material has certain thickness, so that the veneer and the metal hanging strip form a certain suspension distance, after the metal hanging strip with a certain suspension distance is fixed with the veneer, the flatness of the veneer cannot be effectively controlled at all, the problem that the veneer is uneven or sprung cannot be necessarily caused, the upper and lower veneer boards are uneven in dislocation, the aesthetic property of decoration and the acceptance of engineering can be influenced, cracks can be generated, water seepage can be generated, the heat-insulating material can be corroded, the heat-insulating function can be reduced, the metal hanging strip is oxidized and corroded, the building structure and the steel bars can be corroded even, and the series of potential safety hazards can be caused. For producing certain control to the decorative board, the aforesaid patent has adopted chemical glue adhesion insulation material and decorative board equally, and chemical glue adhesion can have three major problems: 1. the chemical glue can be aged and degraded inevitably, and particularly the outdoor environment used by the heat-insulating and decorating integrated plate can accelerate the generation of the phenomenon. 2. The adhesion of the chemical glue can only lead two materials with certain strength to adhere to each other, and the thread-shaped and flocculent heat-insulating materials such as inorganic rock wool, glass wool and the like which are mainly class A fireproof can not generate effective adhesion strength, so that the veneer can not be controlled, thereby greatly limiting the application of the heat-insulating materials in the aspect of the patent. And 3, even if the chemical adhesive is made of glue with excellent weather resistance and an insulating material with excellent adhesion, the larger the thickness of the insulating material is, the poorer the control force of the metal hanging strip on the veneer is, so that the probability of cracking caused by bouncing the veneer is also larger. The inability to effectively control the trim panel, inability to ensure trim panel flatness, is a major drawback of the above-mentioned patents, and thus can create serious series of problems.

Disclosure of Invention

The utility model aims to provide a full-assembled decoration and heat preservation integrated structure so as to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a full assembly decorates heat preservation integrated structure, includes the cement-based artificial stone slab body of taking the veneer, the nut has been buried in slab body back, the screw socket of nut is located the back of slab body, the screw socket internal screw of nut has connecting screw, wear to be equipped with metal string A, heat preservation material layer, metal string B on the connecting screw, metal string A and metal string B are with heat preservation material layer clamp in the middle of, connecting screw's outer end spiro union has the first gland nut with metal string B suppression heat preservation material layer back, metal string A and metal string B are located the position in slab body edge outside and are equipped with the dress through-hole of hanging.

Preferably, the metal hanging strip a is bent toward one side in the direction of the metal hanging strip B to form a stopper portion.

Preferably, a second compression nut for pressing the metal hanging strip A is screwed on the connecting screw rod.

Preferably, a sleeve is arranged on the connecting screw rod between the metal hanging strip A and the metal hanging strip B in a penetrating way.

Preferably, a notch is arranged at the side part of the hanging through hole of the metal hanging strip A.

Preferably, the connecting screw is coated with a thermal insulator.

Preferably, a sound insulation material layer is further arranged between the metal hanging strip A and the metal hanging strip B.

Preferably, the hanging screw rod is arranged in the hanging through holes of the metal hanging strip A and the metal hanging strip B in a penetrating mode, and the hanging screw rod main body is fixed with the wall body.

Preferably, the hanging screw is covered with a thermal insulator.

Preferably, a sleeve is sleeved on the hanging screw rod between the metal hanging strip A and the metal hanging strip B.

Preferably, the board body is an ultra-high performance cement-based artificial stone board prepared with ultra-high performance.

According to the utility model, by utilizing the screw connection advantage principle of the embedded nut at the back of the cement-based artificial stone slab, the connecting screw is implanted in the nut, and after the metal hanging strip A with the hanging function is arranged on the connecting screw in a penetrating way, the metal hanging strip A is tightly attached to the back of the slab body by adopting the second compression nut arranged on the connecting screw. The heat insulation material and the sound insulation material which are continuously penetrated on the connecting screw rod can be clamped by the metal hanging strip B which is finally penetrated on the connecting screw rod and is screwed and fixed through the first compression nut, so that the heat insulation material and the sound insulation material are completely clamped between the two metal hanging strips. The clamping structure formed by the mechanical connection principle of full-screwed interconnection can completely solve the falling hidden trouble of chemical glue. Meanwhile, the heat insulation material can be mechanically clamped with the advantages of any material and any thickness, and various composite problems of low-strength and loose heat insulation materials such as rock wool and glass wool can be solved.

According to the utility model, the metal hanging strip A with certain hardness is arranged on the back of the plate body in a penetrating way, and the metal hanging strip A is tightly attached to the back of the plate. According to different installation requirements, different end parts of the metal hanging strip A are arranged into inwards bent shapes, so that different connection stop parts are formed. During installation, the hanging holes of the metal hanging strips A and the hanging holes of the metal hanging strips B are simultaneously used for fixing the artificial stone slab with the heat insulation materials clamped on the building wall body through the same hanging screw rod. When another plate is installed, the metal hanging strips A which are arranged on the other plate are hooked or clamped on the fixed hanging screw rods or the back of the plate according to different plate seams, and the fastening screw rods which are hooked or clamped with the upper and lower metal hanging strips A are fastened by fastening tools for large plate seams, so that the flatness of the upper and lower plates is completely maintained; when the plate seam is very small or seamless, the metal hanging strip A of the other plate is directly clamped on the fixed hanging screw rod with the same spigot, or is directly clamped on the back of the plate, and the plate with the same thickness and the metal hanging strip with certain hardness can also ensure the flatness between the very small fine seam or the seamless plates. The full assembly structure formed by the bidirectional metal hanging strip, different rabbets formed by different bending parts of the metal hanging strip, different openings, different compression nuts, different connecting modes and the like can completely eliminate any chemical glue and mortar, so that various problems that in the background art, a single hanging strip cannot control a facing plate, the existing heat-insulating and decorating integrated plate must rely on chemical glue and mortar, the potential safety hazard of anchor clamping and reinforcement is large, and any heat-insulating material cannot be randomly compounded can be thoroughly solved.

The utility model can clamp heat-insulating and sound-insulating materials with any thickness and any material quality, and can ensure the generation of flatness and cracks. The series of innovations of the utility model are effectively implemented through repeated experiments. After the method is adopted for installation, the formed full-assembly integral interconnection structure can also lead the load of the plate to be completely conducted to the structure which is necessarily existed in the building through the interconnection structure formed by the metal hanging strip A, and the full-interconnection structure can greatly improve the safety of hanging the integral plate on the wall body which is generally made of light materials, which cannot be realized by the prior heat-insulation decorative integral plate and the patents in the background art.

The cement-based artificial stone plate can reach the highest standard of green building materials from material sources to production and use. The surface of the plate body can form various decorative effects of stone, metal, wood and the like through various treatment methods, the clamping principle formed by the bidirectional hanging strips can clamp any A-level heat insulation material, and can also clamp sound insulation materials which are extremely difficult to compound in the prior art, so that the professional-level sound insulation function is easily realized. The utility model can truly solve the energy-saving and carbon-reducing problems of the existing building, thus being an innovative utility model for benefiting all mankind.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a side cross-sectional view of FIG. 1;

FIG. 3 is a side cross-sectional view of the present utility model showing the structure of a second compression nut threaded onto the connecting screw;

FIG. 4 is a side cross-sectional view of a sleeve inserted over a connecting screw according to the present utility model;

FIG. 5 is a rear partial cross-sectional view of a panel body of another construction according to the utility model;

FIG. 6 is a side cross-sectional view of FIG. 5;

FIG. 7 is a partial cross-sectional view of the back of a sheet body with metal hanger A being another metal hanger;

FIG. 8 is a rear partial cross-sectional view of a panel body of yet another construction according to the present utility model;

FIG. 9 is a side cross-sectional view of a metal strap A according to the present utility model;

FIG. 10 is a side cross-sectional view of the installation between sheets of the present utility model;

FIG. 11 is an enlarged view of FIG. 10 at A;

FIG. 12 is a side cross-sectional view of another panel-to-panel installation of the present utility model;

FIG. 13 is an enlarged view of FIG. 12 at B;

FIG. 14 is a side cross-sectional view of yet another alternate panel to panel installation in accordance with the present utility model;

FIG. 15 is an enlarged view of FIG. 14 at C;

FIG. 16 is an enlarged view of another structure at C in FIG. 14;

fig. 17 is a side sectional view of the sandwich insulation material and sound insulation material of the present utility model.

In the figure: 1-a plate body; 2-a nut; 3-a metal hanging strip A; 4-a heat preservation material layer; 5-a metal hanging strip B; 6-connecting a screw; 7-a layer of sound insulating material; 9-hanging a screw; 11-a sleeve; 12-mesh; 13-wall body; 16-steel bar; 17-expansion bolts; 18-a wall penetrating screw; 31-hanging through holes; 32-notch; 33-a stopper portion; 52-hanging through holes of the metal hanging strips B; 61-a first compression nut; 62-a second compression nut; 64-sleeve; 65-third compression nut.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

For further improvement, a number of embodiments are provided below, it being evident that the embodiments described are only some, but not all, of the embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Embodiment one:

from fig. 1 and fig. 2, it can be known that a full-assembled decoration and heat preservation integrated structure comprises a cement-based artificial stone slab body with a facing, wherein a nut 2 is buried at the back of the slab body 1, a screw of the nut 2 is positioned at the back of the slab body 1, a connecting screw 6 is screwed in the screw of the nut 2, and a thermal insulator is wrapped on the connecting screw 6. The connecting screw rod 6 is provided with a metal hanging strip A3, a heat-insulating material layer 4 and a metal hanging strip B5 in a penetrating way, the metal hanging strip A3 and the metal hanging strip B5 clamp the heat-insulating material layer 4 in the middle, the outer end of the connecting screw rod 6 is screwed with a first compression nut 61 for pressing the metal hanging strip B5 on the back of the heat-insulating material layer 4, and a hanging through hole 31 is arranged at the position of the metal hanging strip A3, which is positioned outside the edge of the plate body 1, according to requirements; the metal hanging strip B5 is provided with a hanging through hole 52 at the outer side of the edge of the plate body 1.

In order to better limit and fix the thermal insulation material layer 4, the side of the metal hanging strip A3, which is close to the direction of the metal hanging strip B5, is further bent to form a stop portion 33, and the stop portion 33 may be formed after secondary bending.

Embodiment two:

unlike the first embodiment, the following is: as can be seen from fig. 3, a second compression nut 62 for pressing the metal hanging strip A3 is screwed on the connecting screw 6. As can be seen from fig. 4, a sleeve 64 is provided on the connecting screw 6 between the metal hanging strip A3 and the metal hanging strip B5.

As can be seen from fig. 9-10, the installation structure of the whole assembly decoration and heat preservation integration further comprises a plurality of cement-based artificial stone slab bodies with veneers, wherein the hanging screw rods 9 are arranged in the hanging through holes 31 and 52 of the metal hanging strip A3 and the metal hanging strip B5 in a penetrating manner, and the metal hanging strip A3 comprises an upper metal hanging strip a (the metal hanging strip A3 on the upper part of the same slab) positioned on the upper part of the slab body 1 and a lower metal hanging strip a (the metal hanging strip A3 on the upper part and the lower part of the same slab) positioned on the lower part of the slab body 1. The metal hanging strip B5 comprises an upper metal hanging strip B5 (the metal hanging strip B5 on the upper part of the same plate and the same as the lower metal hanging strip B5 on the lower part of the plate) and a lower metal hanging strip B5 (the metal hanging strip B5 on the lower part of the same plate and the same as the lower metal hanging strip B5 on the lower part of the plate) which are arranged on the upper part of the plate body 1.

When the sheet material bodies are assembled in a seamless manner through the thin seam, the hanging screw 9 sequentially passes through the hanging through hole 31 on the spigot part 33 of the upper metal hanging strip A and the hanging through hole 52 of the upper metal hanging strip B to be fixed with the wall 13, then another sheet material body is arranged on the wall, and the end part of the lower metal hanging strip A of the other sheet material body is inserted between the sheet material body and the nut end of the hanging screw 9 and is leaning against the back of the sheet material body 1. The lower metal hanging strip B can be transversely fixed with the wall body. The best state of assembly between the plate bodies is: the end of the screw cap of the hanging screw 9 is tightly attached to the end of the lower metal hanging strip A of the other plate body, so that when the other plate body is pushed, the end of the lower metal hanging strip A of the other plate body just abuts against the end of the screw cap of the hanging screw 9, and the problem that the other plate body is inclined inwards, so that the plates are uneven is solved. Similarly, when another plate body is pulled, the end part of the lower metal hanging strip A of the other plate body is leaned against the back of the plate body 1, so that the problem of uneven plates caused by outward inclination of the other plate body is prevented.

A sleeve 11 can be sleeved on the hanging screw rod 9 between the metal hanging strip A3 and the metal hanging strip B5, and the sleeve 11 can prevent the inward inclination during the installation between plates.

The mechanical connection installation of the inner and outer bidirectional metal hanging strips and the full-screwed interconnection can lead the cement-based artificial stone slab body with the facing, the heat insulation material and the building wall to form strong locking force, the full-assembled installation method not only completely omits the steps of chemical glue compounding and mortar pasting installation of the existing integrated plate, but also solves the problems that the existing heat insulation and decoration integrated plate must be shoveled to remove old paint, ceramic tile and other facing layers and empty and expanded and sanded plastering layers, and the structural force and the adhesive force must be realized by re-plastering, so that the installation can be fixed by using mortar, and only one of the problems can save great cost compared with the existing heat insulation and decoration integrated plate. Meanwhile, the metal hanging strips which are arranged in the inner and outer directions can be reinforced by the clamping anchors of the existing heat-insulating and decorating integrated plate and the single hanging strip of the existing cement-based integrated plate, so that the hanging strip has higher hanging strength and higher anti-seismic performance, and further can achieve longer service life.

Embodiment III:

as can be seen from fig. 5, 6 and 7, unlike the second embodiment, the side portion of the hanging hole of the metal hanging strip A3 is provided with a notch 32. A third compression nut 65 or a cushion block can be arranged on the connecting screw rod 6 in a penetrating way, and the third compression nut 65 or the cushion block and the first compression nut 61 clamp the metal hanging strip B5.

The embodiments of fig. 12-13 provide a form in which a plurality of faced cementitious artificial stone panel bodies are mounted together. The hanging screw rods 9 are arranged in the hanging through holes 31 and 52 of the metal hanging strip A3 and the metal hanging strip B5 in a penetrating way. When the plate bodies are assembled (the nut end of the hanging screw rod 9 is positioned in the plate seam), the hanging screw rod 9 sequentially passes through the hanging through hole 31 on the spigot part 33 of the upper metal hanging strip A, the hanging through hole 52 of the upper metal hanging strip B and is fixed with the wall body 13, and at the moment, a space with the thickness of the lower metal hanging strip A is reserved between the nut end of the hanging screw rod 9 and the upper metal hanging strip A; and then another plate is arranged above the metal hanging strip A, a hanging through hole provided with a notch 32 at the lateral part of the outer end of the metal hanging strip A under the other plate is buckled or hooked on a hanging screw 9 for reserving the thickness space of the metal hanging strip A, and finally the hanging screw 9 can be adjusted in a wide seam through an adjusting tool, so that the flatness among the plates is adjusted. The hanging screw 9 is covered with a thermal insulator to break the bridge.

The hanging through holes of the metal hanging strip A on the plate body and the hanging through holes of the lower metal hanging strip A of the other plate body can be coaxially arranged, so that the flatness between the plates can be ensured during plate installation, and the phenomenon of uneven and the like can be avoided. The plate body 1 is sequentially fixed on the outer side or the inner side of the wall body according to the installation method.

Sleeve 11 can be sleeved on hanging screw 9 between metal hanging strip A3 and metal hanging strip B5, sleeve 11 can prevent not only the buckling or hooking error between the plate bodies, but also the inward inclination during the installation between the plates.

Embodiment four:

as can be seen from fig. 8, unlike the second embodiment, the following is: the upper metal hanging strip A3 positioned at the upper part of the plate body 1 and the lower metal hanging strip A3 positioned at the lower part of the plate body 1 are respectively provided with a stop part 33 formed by bending at one side close to the direction of the metal hanging strip B5.

As further shown in fig. 16, when the plate bodies are assembled (the adjusting tool can pass through the plate seam), the hanging screw 9 sequentially passes through the hanging through hole 31 on the upper end stop portion 33 of the upper metal hanging strip A3, and the hanging through hole of the upper metal hanging strip B5 is fixed with the wall 13, at this time, a space with the thickness of the lower metal hanging strip A3 is reserved between the nut end of the hanging screw 9 and the upper metal hanging strip A3, then another plate is installed above the space, the hanging through hole with the notch 32 on the side portion of the lower end of the lower metal hanging strip A3 of another plate is buckled or hooked on the hanging screw 9 with the reserved space with the thickness of the lower metal hanging strip a, and finally, the adjusting tool can pass through the plate seam to adjust the hanging screw 9, thereby adjusting the flatness between the plates. The hanging screw 9 is covered with a thermal insulator to break the bridge.

Fifth embodiment: as can be seen from fig. 9, the difference from the fourth embodiment is that: the whole metal hanging strip A3 is adopted to replace the two metal hanging strips A, and two sides of the metal hanging strip A3, which lean against the direction of the metal hanging strip B5, are respectively provided with a bending stop part 33.

As can be seen from fig. 14-15, the installation structure of the whole assembly decoration and heat preservation integration further comprises a plurality of cement-based artificial stone slab bodies with veneers, the hanging screw rods 9 are penetrated through the hanging through holes 31 and 52 of the metal hanging strip A3 and the metal hanging strip B5, when the slab bodies are subjected to fine seam seamless assembly, the hanging screw rods 9 sequentially penetrate through the hanging through holes 31 on the upper end stop part 33 of the upper metal hanging strip a, and when the hanging through holes of the upper metal hanging strip B are fixed with the wall 13, a space with the thickness of the lower metal hanging strip a is reserved between the nut end of the hanging screw rod 9 and the upper metal hanging strip a, then another slab is installed above the space with the nut end of the upper metal hanging strip, and the hanging through hole with the notch 32 is buckled or hung on the hanging screw rods 9 with the reserved thickness space of the lower metal hanging strip a, so that the assembly installation is completed. The hanging screw 9 is covered with a thermal insulator to thermally break the bridge.

Sleeve 11 can be sleeved on hanging screw 9 between metal hanging strip A3 and metal hanging strip B5, sleeve 11 can prevent not only the buckling or hooking error between the plate bodies, but also the inward inclination during the installation between the plates.

Wherein the optimal states among the plates are as follows: when the notch 32 arranged at the side part of the hanging through hole 31 on the metal hanging strip is arranged transversely, the plates can be perfectly connected in series.

Example six:

as can be seen from fig. 17, the second embodiment is different from the first embodiment in that: the plate body 1 is an ultra-high-performance cement-based artificial stone plate prepared with ultra-high performance, and the plate body 1 is internally provided with a net sheet 12. And a sound insulation material layer 7 or a composite material layer formed by the heat insulation material layer and the sound insulation material layer is arranged between the metal hanging strip A3 and the metal hanging strip B5.

The mounting structure of full assembly decoration heat preservation integration still includes polylith cement-based artificial stone slab body, the string dress screw rod 9 of taking the veneer, the thermal insulator is covered on the string dress screw rod 9. A sleeve 11 is sleeved on the hanging screw 9 between the metal hanging strip A3 and the metal hanging strip B5. If the light wall is installed, firstly, steel bars 16 are required to be fixed, specifically: the steel bars 16 are fixed on the upper and lower ring beams of the lightweight wall body by implanting expansion bolts 17, steel bars and the like. And then the hanging screw rod 9 passes through, the hanging through hole 31 on the metal hanging strip stop part 33, the sleeve 11, the hanging through hole of the upper metal hanging strip B and the steel bar 16 are fixed with the light wall body. The mounting structure between the plates is the same as that of the plates in the above embodiment. The plate body 1 can be sequentially fixed on the outer side or the inner side of the light wall according to the installation method.

In order to fasten the vertical steel bars to the wall, a transverse steel bar can be added to the steel bars 16 placed vertically, and wall penetrating screws 18 can be directly inserted into other through holes of the steel bars 16.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof.

The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. q any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (10)

1. The utility model provides a full assembly decorates heat preservation integrated structure, includes the cement-based artificial stone slab body of taking the veneer, nut (2) have been buried in slab body (1) back, the screw socket of nut (2) is located the back of slab body (1), its characterized in that: the utility model discloses a heat insulation plate, including nut (2), connecting screw (6), metal string strip A (3), heat preservation material layer (4), metal string strip B (5) are worn to be equipped with in the screw of nut (2), metal string strip A (3) and metal string strip B (5) are put heat preservation material layer (4) in the middle of, the outer end spiro union of connecting screw (6) has first gland nut (61) at heat preservation material layer (4) back with metal string strip B (5) suppression, the position that metal string strip A (3) and metal string strip B (5) are located the edge outside of panel body (1) is equipped with the dress through-hole of hanging.

2. The fully assembled decorative and thermal insulation integrated structure according to claim 1, wherein: the metal hanging strip A (3) is bent towards one side of the direction of the metal hanging strip B (5) to form a stop part (33).

3. The fully assembled decorative and thermal insulation integrated structure according to claim 1 or 2, wherein: the connecting screw (6) is screwed with a second compression nut (62) for pressing the metal hanging strip A (3).

4. The fully assembled decorative and thermal insulation integrated structure according to claim 1 or 2, wherein: a sleeve (64) is arranged on the connecting screw rod (6) between the metal hanging strip A (3) and the metal hanging strip B (5) in a penetrating way.

5. The fully assembled decorative and thermal insulation integrated structure according to claim 1 or 2, wherein: the side part of the hanging through hole of the metal hanging strip A (3) is provided with a notch (32).

6. The fully assembled decorative and thermal insulation integrated structure according to claim 1 or 2, wherein: the connecting screw (6) is coated with a thermal insulator.

7. The fully assembled decorative and thermal insulation integrated structure according to claim 1, wherein: and a sound insulation material layer (7) is arranged between the metal hanging strip A (3) and the metal hanging strip B (5).

8. The fully assembled decorative and thermal insulation integrated structure according to claim 1, wherein: the hanging screw rods (9) are arranged through hanging holes of the metal hanging strips A (3) and the metal hanging strips B (5) in a penetrating mode, and the main bodies of the hanging screw rods (9) are fixed with the wall body.

9. The fully assembled decorative and thermal insulation integrated structure according to claim 8, wherein: the hanging screw rod (9) is coated with a thermal insulator.

10. The fully assembled decorative and thermal insulation integrated structure according to claim 8, wherein: a sleeve (11) is sleeved on the hanging screw rod (9) between the metal hanging strip A (3) and the metal hanging strip B (5).