CN111636616A - Assembly type architectural decoration system, ceiling system and wall surface system - Google Patents

Abstract

The invention relates to an assembly type building decoration system, a ceiling system and a wall surface system, which belong to the technical field of assembly type buildings, and comprise a plurality of modules which are mutually connected in a building space, wherein each module comprises a main keel unit, a modeling main keel unit, a secondary keel unit and a facing substrate layer; the assembly is carried out through a prefabricated modular structure, so that the resonance phenomenon is not easy to generate, and the safety coefficient is high; the outer side surface of the first short plate in the main molding keel is in a linear or fold line shape, and can be directly installed only by determining the elevations of two points, so that the installation is convenient and the installation precision is high; different shapes can be set according to the demand for the difference of the extension length of the first long plate in the main molding keel, the special-shaped structure molding keel is suitable for assembly type construction of various special-shaped structures, and the application range is wide.

Description

Assembly type architectural decoration system, ceiling system and wall surface system

Technical Field

The invention relates to the technical field of assembly type buildings, in particular to an assembly type building decoration system, a ceiling system and a wall surface system.

Background

The existing structural system is designed by CAD software, a main steel structure is formed by welding large I-shaped steel or channel steel, secondary keels are connected by angle steel, and the back of the glass fiber reinforced gypsum board facing material is embedded with an angle code and manually installed in a screw rod hoisting mode. The glass fiber reinforced gypsum board is produced by manually proportioning raw materials such as gypsum powder, glass fiber and the like, the model is manufactured by reverse-mode processing according to a space model manufacturing mold, and the gypsum board is naturally maintained and dried and then transported to a construction site.

The existing structural system is complex in installation process, large in labor intensity, long in construction period, easy to generate resonance phenomenon and low in safety factor, and a large number of workers are required to complete construction at the same time.

Disclosure of Invention

In order to overcome the problems in the prior art, the invention provides an assembly type architectural decoration system which comprises a plurality of modules which are mutually connected in a building space, wherein the plurality of modules are prefabricated and are directly assembled and connected by a small number of workers on site, so that the construction time can be greatly saved, the labor cost can be saved, and each module comprises a main keel unit, a modeling main keel unit, a secondary keel unit and a veneer base plate layer;

the main keel unit is connected with a steel structure conversion layer and comprises a plurality of main keels which are distributed in parallel;

the modeling main keel unit comprises a plurality of modeling main keels distributed in parallel, each modeling main keel comprises a first short plate, and the edge ends of the first short plates integrally extend to form a first long plate forming a preset angle with the first short plates;

the outer side surfaces of the first short plates are linear or zigzag, the plurality of first short plates are sequentially and vertically connected to the bottom surface of the main keel unit through the outer side surfaces of the first short plates, the first long plates extend towards the direction far away from the first short plates according to the required shape of the building space, the shape of the first long plates is set according to the required shape of the building space, and the special-shaped keel unit is suitable for shape construction of various special spaces such as narrow spaces, special-shaped spaces and the like and is wide in application range;

the secondary keel units comprise a plurality of secondary keels distributed in parallel, and the secondary keels are sequentially and vertically fixed to one ends, far away from the first short plates, of the first long plates along the length direction of the first long plates;

the veneer basal plate layer can be detachably connected with the bottom surface of the secondary keel.

Furthermore, the modules are marked with different identifiers, so that the building system can be rapidly installed, a suitable substitute can be rapidly found according to the identifiers in the later maintenance and repair process, the repair speed is increased, and meanwhile, according to the digital management mode, vulnerable points in the assembly type building decoration system can be conveniently counted and analyzed, so that targeted improvement or redesign is performed.

Further, the bottom of first long slab along length direction be equipped with secondary joist matched with a plurality of bayonet socket, the secondary joist corresponds to weld in every in the bayonet socket, make the relation of connection between secondary joist and the molding main joist fasten more.

Furthermore, the modeling main keel and the secondary keel are both galvanized steel plates.

Further, the secondary joist is L-shaped, the length dimension of the cross section of the secondary joist is 22-35 mm, the width dimension of the cross section of the secondary joist is 5-15 mm, so that the secondary joist has certain bending toughness and is simultaneously adapted to the linear modeling and the curved modeling of the bottom end of the modeling main joist.

Further, the veneer substrate layer is of a double-layer plate structure, wherein the thickness of each layer plate is 4-15 mm.

Further, every layer all includes the compound crooked board of silicon pottery of a plurality of seam connections in the double-deck plate structure, and the setting of staggering of seam between a plurality of compound crooked boards of silicon pottery between two-layer, when satisfying structural connection intensity, can effectively cut apart the weight on veneer base plate layer, the transportation, the transport and the installation on veneer base plate layer of being convenient for are difficult to produce in transport and transportation and are out of shape, and the installation accuracy is high.

Furthermore, the seam gap is 3-5 mm, seam paste is filled in the seam gap, and the seam is located on the bottom surface of the secondary keel so as to improve the overall structural connection strength of the system.

Further, every main joist all is equipped with a plurality of first through-holes along length direction in the main joist unit in proper order, the molding main joist is equipped with just right the second through-hole of first through-hole, through the positioning action of first through-hole and second through-hole, can install main joist and molding main joist fast.

The application still provides an utilize above-mentioned assembled architectural decoration system's furred ceiling system, steel construction conversion layer level keeps in the top, assembled architectural decoration system level keeps in the below, the steel construction conversion layer through a plurality of galvanized lead screw connect in first through-hole with the second through-hole through galvanized lead screw connection steel construction conversion layer and assembled architectural decoration system, makes this assembled architectural decoration system be applicable to furred ceiling system.

Furthermore, the galvanized screw rod penetrates through the first through hole and the second through hole, and a first double nut is screwed on the top surface of the first through hole and the bottom surface of the second through hole;

the galvanized screw rod penetrates through the steel structure conversion layer, and second double nuts are screwed on the upper surface and the lower surface of the steel structure conversion layer.

The application also provides a wall surface system utilizing the assembly type building decoration system, the steel structure conversion layer is kept on a wall surface, and the assembly type building decoration system is positioned on one side of the steel structure conversion layer relative to the wall surface;

the wall system still includes a plurality of zinc-plated square tube, zinc-plated square tube perpendicular to respectively steel construction conversion layer with the main joist, and respectively with steel construction conversion layer with main joist welded connection, through zinc-plated square tube respectively perpendicular connection steel construction conversion layer and main joist, make this assembled architectural decoration system be applicable to the wall system.

Has the advantages that: compared with the prior art, the assembled architectural decoration system, the ceiling system and the wall surface system are different in that the assembled architectural decoration system, the ceiling system and the wall surface system comprise a plurality of modules which are mutually connected in a building space, wherein each module comprises a main keel unit, a modeling main keel unit, a secondary keel unit and a facing substrate layer; the assembly is carried out through a prefabricated modular structure, so that the resonance phenomenon is not easy to generate, and the safety coefficient is high; the outer side surface of the first short plate in the main molding keel is in a linear or fold line shape, and can be directly installed only by determining the elevations of two points, so that the installation is convenient and the installation precision is high; different shapes can be set according to the demand for the difference of the extension length of the first long plate in the main molding keel, the special-shaped structure molding keel is suitable for assembly type construction of various special-shaped structures, and the application range is wide.

Drawings

Fig. 1 is a schematic structural view of a ceiling system according to a preferred embodiment of the present application.

Fig. 2 is an enlarged schematic view of a portion a in fig. 1.

FIG. 3 is a front view of a ceiling system according to a preferred embodiment of the present application.

Fig. 4 is an enlarged schematic view of a portion B in fig. 3.

Fig. 5 is a schematic structural view of a wall system according to a preferred embodiment of the present application.

FIG. 6 is a front view of a wall system according to a preferred embodiment of the present application.

Fig. 7 is an enlarged schematic view of portion C of fig. 6.

The system comprises a 100-module, a 101-steel structure conversion layer, a 1-main keel, 11-first through holes, a 2-modeling main keel, 21-first short plates, 22-first long plates, 221-bayonets, 3-secondary keels, a 4-decorative base plate layer, 41-self-tapping screws, a 5-ceiling system, 51-galvanized lead screws, 52-first double nuts, 53-second double nuts, a 6-wall surface system and 61-galvanized square tube.

Detailed Description

The invention is further described with reference to the following figures and specific examples.

Referring to fig. 1 to 4, the present invention provides a fabricated architectural decoration system including a plurality of modules 100 interconnected in a building space, wherein each of the modules 100 includes a main runner unit, a molding main runner unit, a cross runner unit, and a finishing substrate layer.

Wherein, the main joist unit is connected with the steel structure conversion layer 101. The main runner unit includes a predetermined number of main runners 1 arranged in parallel. Fig. 1 exemplarily shows four main runners 1 in one of the modules 100, and the number of the main runners 1 may be three or five according to the structural configuration and/or the size of the module 100, and the main runners 1 are selected to be 50mm by 50mm customized main runners without any specific number limitation.

Wherein, the main molding keel unit comprises a predetermined number of main molding keels 2 which are distributed in parallel. The main molding keel 2 is preferably made of galvanized steel sheet. Figure 1 illustrates ten castellated main runners 2 in one module 100 as described above. Each modeling main keel 2 is vertical to the main keel 1. The sculpted main runner 2 comprises a first short plate 21. The edge end of the first short plate 21 integrally extends to form a first long plate 22 having a predetermined angle with the first short plate 21, and the predetermined angle can be selected to be 90 °.

The outer side surfaces of the first short plates 21 are linear or fold-line-shaped, wherein ten first short plates 21 which are distributed in parallel are sequentially and vertically connected to the bottom surface of the main keel 1 through the outer side surfaces. The connection is preferably by welding. Through the design of the linear or fold line shape, when two adjacent modules 100 are connected, the direct installation can be realized only by determining the elevations of two points, so that the assembly speed and the assembly precision are effectively improved, and meanwhile, the later maintenance and repair are facilitated.

The first long board 22 extends in a direction away from the first short board 21 according to the desired configuration of the building space, so as to form different structural configurations, thereby achieving the structural configuration desired by the customer or the structural configuration capable of being accommodated by the special-shaped space. Fig. 1 shows an exemplary embodiment in which the bottom of one of the modules 100 is shaped as a fold line.

Wherein the cross runner unit comprises a predetermined number of cross runners 3 distributed in parallel. The secondary joist 3 is preferably made of galvanized steel. Figure 1 illustrates eight cross runners. Each secondary keel 3 is sequentially and vertically fixed on one end of ten first long plates 22 far away from the first short plate 21, namely the bottom end of the first long plate 22, along the length direction of the first long plate 22.

The modeling main keel 2 and the secondary keel 3 can be directly divided into digital modules, and the modules are produced in a standardized structure and processed in batches.

Wherein, the veneer basal plate layer 4 can be dismantled and connect in the bottom surface of secondary joist 3. The connection is preferably fixed by self-tapping screws 41.

Preferably, the plurality of modules 100 provided in the building space are each marked with a different identification to facilitate quick installation of the building system and during later maintenance and repair. According to the identification, a proper substitute can be quickly found, the maintenance speed is improved, and meanwhile, according to the digital management mode, the vulnerable points in the assembly type architectural decoration system can be conveniently counted and analyzed, so that targeted improvement or redesign is performed.

Preferably, the bottom end of the first long plate 22 is provided with eight bayonets 221 matched with the cross runners 3 along the length direction. The secondary joist 3 is correspondingly welded in each bayonet 221, so that the whole structure is more compact, and meanwhile, the connection relation between the secondary joist 3 and the modeling main joist 2 is more fastened.

Preferably, the cross runners are L-shaped. The length dimension of the cross section of the secondary keel is 22-35 mm, the width dimension of the cross section of the secondary keel is 5-15 mm, and the optimal length-width ratio of the cross section of the secondary keel is 29mm 9 mm. A large number of experiments verify that the secondary keel 3 has the best plastic shape and structural strength in the proportioning interval. When the fixing device is installed on the bayonet 221 on the bottom surface of the main molding keel 2, arc transition or height difference may exist due to different shapes of the bottom surface of the main molding keel 2, so as to form a certain curved surface or a straight line bending surface. The secondary keel 3 can meet the requirements of the whole curved surface or special-shaped surface of the bottom surface of the modeling main keel 2 after installation, thereby being suitable for the assembly type construction of various special-shaped structures.

Preferably, the veneer substrate layer 4 is a double-layer plate structure, wherein the thickness of each layer plate is 4 mm-15 mm, and the standard numerical control machine is adopted for production, and the specification is as follows: 1820mm 910mm, the thickness is preferably 5mm, so that the material has relatively high plasticity, and construction and installation of the special-shaped curved surface can be carried out according to the system structure.

Preferably, each layer in the double-layer plate structure comprises a silicon ceramic composite bent plate connected by a preset number of joints, and the joints between the two layers of silicon ceramic composite bent plates are arranged in a staggered mode. Satisfy structural joint strength simultaneously, can effectively cut apart the weight of veneer base plate layer 4, the transportation, the transport and the installation of veneer base plate layer 4 of being convenient for. From this, avoided using the various problems that a monoblock composite sheet brought, for example carry, carry inconvenient, the cost of transportation is high, yielding etc. but, this compound crooked board of double-deck silicon pottery can reach the veneer basic unit effect the same with the monoblock bold.

Preferably, the seam gap is 3mm to 5 mm. And joint paste is filled in the joint gap. The seam is located on the bottom surface of the secondary joist 3 to improve the structural connection strength of the whole system.

Preferably, each main joist 1 in the main joist unit is provided with a plurality of first through holes 11 along the length direction in turn. The modeling main keel 2 is provided with a second through hole which is opposite to the first through hole 11. Through the positioning action of first through-hole 11 and second through-hole, can install main joist 1 and molding main joist 2 fast.

The present application further provides a ceiling system 5 utilizing the above-described fabricated architectural decoration system. The steel structure transfer floor 101 is horizontally held above. The fabricated architectural decoration system is horizontally maintained below. The steel structure conversion layer 101 is connected to the first through hole 11 and the second through hole through a predetermined number of galvanized lead screws 51. Of these, nine galvanized lead screws 51 are shown in fig. 1 by way of example. Three main keels 1 in the four main keels 1 are respectively connected with the steel structure conversion layer 101 through three galvanized lead screws 51. The number of the galvanized lead screws 51 can be adjusted adaptively according to the difference of the structural shape and/or the difference of the size of the module 100, and the number of the galvanized lead screws 51 connected with the steel structure conversion layer 101 in each main keel 1 can also be adjusted adaptively, and the number is not limited specifically herein. The steel structure conversion layer 101 and the fabricated architectural decoration system are connected through the galvanized screw 51, so that the fabricated architectural decoration system is suitable for the ceiling system 5.

Preferably, the galvanized screw rod 51 penetrates through the first through hole 11 and the second through hole, and a first double nut 52 is screwed on the top surface of the first through hole 11 and the bottom surface of the second through hole. Nuts are arranged on the top surface of the first through hole 11 and the bottom surface of the second through hole to form a double-nut structure, so that high connection strength between the galvanized screw rod 51 and the main keel 1 and between the galvanized screw rod and the modeling main keel 2 is ensured, and safety is improved;

the galvanized screw rod 51 penetrates through the steel structure conversion layer 101, the second double nuts 53 are screwed on the upper surface and the lower surface of the steel structure conversion layer 101, and the nuts are also mounted on the top surface and the bottom surface of the steel structure conversion layer 101, so that the connection strength of the galvanized screw rod 51 and the steel structure conversion layer 101 is improved, and the safety is improved.

Referring to fig. 5 to 7, the present application also provides a wall surface system 6 using the above-described fabricated building decoration system. Wherein the steel structure transfer layer 101 is held on a wall surface. Steel construction conversion layer 101 can set up with the wall parallel, also can form certain contained angle according to some special needs and wall and set up. The assembly type architectural decoration system is located on one side, opposite to the wall surface, of the steel structure conversion layer 101.

The wall system 6 also includes a predetermined number of galvanized square tubes 61. The galvanized square tube 61 is perpendicular to the steel structure conversion layer 101 and the main joist 1 respectively and is welded to the steel structure conversion layer 101 and the main joist 1 respectively, wherein fig. 5 exemplarily shows three main joists 1 and nine galvanized square tubes 61, and each main joist 1 is connected to the steel structure conversion layer 101 through three galvanized square tubes 61. The steel structure conversion layer 101 and the main keel 1 are respectively and vertically connected through the galvanized square tube 61, so that the assembly type building decoration system is suitable for a wall surface system. Fig. 6 illustrates one of the builds in a wall system that integrates both curved and straight or fold line builds. Therefore, in the wall surface system, diversified special-shaped space shapes can be provided, the shape shapes can be customized according to the requirements of customers, and the wall surface system can be customized according to the space environment and has very wide adaptability.

It should be noted that the terms "first and second" in the present invention are used for descriptive purposes only, do not denote any order, are not to be construed as indicating or implying any relative importance, and are to be interpreted as names.

The above embodiments are merely preferred embodiments of the present disclosure, which are not intended to limit the present disclosure, and any modifications, equivalents, improvements and the like, which are within the spirit and principle of the present disclosure, should be included in the scope of the present disclosure.

Claims (12)

1. An assembly type architectural decoration system is characterized by comprising a plurality of modules which are mutually connected in a building space, wherein each module comprises a main keel unit, a modeling main keel unit, a secondary keel unit and a decorative surface substrate layer;

the main keel unit is connected with a steel structure conversion layer and comprises a plurality of main keels which are distributed in parallel;

the modeling main keel unit comprises a plurality of modeling main keels distributed in parallel, each modeling main keel comprises a first short plate, and the edge ends of the first short plates integrally extend to form a first long plate forming a preset angle with the first short plates;

the outer side surfaces of the first short plates are linear or fold-line-shaped, the plurality of first short plates are sequentially and vertically connected to the bottom surface of the main keel unit through the outer side surfaces of the first short plates, and the first long plates extend towards the direction far away from the first short plates according to the required shape of the building space;

the secondary keel units comprise a plurality of secondary keels distributed in parallel, and the secondary keels are sequentially and vertically fixed to one ends, far away from the first short plates, of the first long plates along the length direction of the first long plates;

the veneer basal plate layer can be detachably connected with the bottom surface of the secondary keel.

2. The fitted architectural decoration system of claim 1 wherein the plurality of modules are each marked with a different logo.

3. The system of claim 1, wherein the bottom end of the first elongated panel is provided with a plurality of notches along the length direction for engaging with the cross runners, and the cross runners are correspondingly welded in each of the notches.

4. The system of assembled architectural decoration of claim 1 wherein the sculpted main runner and the cross runners are galvanized steel.

5. The assembly type architectural decoration system according to claim 4, wherein the cross-sectional shape of.

6. The fitted architectural decoration system of claim 1 wherein the veneer substrate layer is a double-layer plate structure, wherein each layer has a thickness of 4mm to 15 mm.

7. The fabricated architectural decoration system of claim 6, wherein each of the two-layer plate structures comprises a plurality of silicon ceramic composite curved plates connected by seams, and the seams between the plurality of silicon ceramic composite curved plates between the two layers are staggered.

8. The assembly type architectural decoration system of claim 7, wherein the joint gap is 3mm to 5mm, the joint gap is filled with joint compound, and the joint is positioned on the bottom surface of the cross runner.

9. The assembly type architectural decoration system according to any one of claims 1 to 8, wherein each of the main runners of the main runner unit is provided with a plurality of first through holes in sequence in a length direction, and the molding main runner is provided with a second through hole facing the first through hole.

10. A ceiling system using the fabricated architectural decoration system of claim 9, wherein the steel structural conversion layer is horizontally maintained at an upper side, the fabricated architectural decoration system is horizontally maintained at a lower side, and the steel structural conversion layer is connected to the first through hole and the second through hole by a plurality of galvanized lead screws.

11. The ceiling system of claim 10, wherein the galvanized lead screw penetrates the first through hole and the second through hole, and a first double nut is screwed on the top surface of the first through hole and the bottom surface of the second through hole;

the galvanized screw rod penetrates through the steel structure conversion layer, and second double nuts are screwed on the upper surface and the lower surface of the steel structure conversion layer.

12. A wall surface system using the fabricated building decoration system of any one of claims 1 to 9, wherein the steel structural conversion layer is held to a wall surface, and the fabricated building decoration system is located at a side of the steel structural conversion layer opposite to the wall surface;

the wall surface system further comprises a plurality of galvanized square tubes, wherein the galvanized square tubes are perpendicular to the steel structure conversion layer and the main keels respectively and are connected with the steel structure conversion layer and the main keels in a welded mode.

Images