阅读说明：本技术 弧形面快速装配结构 (Arc-shaped surface rapid assembly structure ) 是由 滨冈寛亘 于 2021-10-18 设计创作，主要内容包括：本发明公开了一种弧形面快速装配结构,包含：承载组件、造型龙骨组件、封板组件；封板组件设置在造型龙骨组件上,封板组件由若干个第一封板、若干个第一紧固件、若干个第二封板与若干个第二紧固件组成,若干个第一封板与若干个第二封板包括但不限于可弯曲不回弹板；造型龙骨组件设置在承载组件上,承载组件与外部的建筑物相连。本发明解决了现有技术中容易产生声音共振的缺陷,具有防火性能良好、安装精度高,装配速度快、稳定性高的特点。(The invention discloses a rapid assembly structure for an arc surface, which comprises: the device comprises a bearing assembly, a modeling keel assembly and a sealing plate assembly; the sealing plate assembly is arranged on the molding keel assembly and consists of a plurality of first sealing plates, a plurality of first fasteners, a plurality of second sealing plates and a plurality of second fasteners, and the plurality of first sealing plates and the plurality of second sealing plates comprise but are not limited to bendable non-resilient plates; the molding keel assembly is arranged on the bearing assembly, and the bearing assembly is connected with an external building. The invention overcomes the defect that sound resonance is easy to generate in the prior art, and has the characteristics of good fireproof performance, high installation precision, high assembly speed and high stability.)

1. The utility model provides an arcwall face rapid Assembly structure which characterized in that contains: the device comprises a bearing assembly, a modeling keel assembly and a sealing plate assembly;

the sealing plate assembly is arranged on the molding keel assembly;

the modeling keel assembly is arranged on the bearing assembly;

the load bearing assembly is connected to an external building.

2. The arcuate-face quick assembly structure of claim 1, wherein said carrier assembly comprises: and one end of the connecting piece is fixed on the building, and the other end of the connecting piece is connected with the modeling keel component.

3. The arcuate-face quick assembly structure of claim 2, wherein said carrier assembly further comprises: the hanging pieces are arranged on the modeling keel assembly, and the hanging pieces are connected with the other end of the connecting piece and used for connecting the modeling keel assembly and the connecting piece.

4. The arcuate-face quick assembly structure of claim 2, wherein said carrier assembly further comprises: the bearing parts are arranged on the outer wall of the building, and the bearing parts are connected with one end of the connecting part and used for fixing one end of the connecting part on the building.

5. The arcuate-faced quick assembly structure as set forth in claim 1, wherein said sculpted keel assembly comprises: a plurality of main keels and a plurality of auxiliary keels;

the main keels are connected with the bearing component block;

a plurality of false keel sets up one side of a plurality of main joist, every the false keel with a plurality of main joist links to each other, and is adjacent the interval of false keel is 50mm ~300mm, and is adjacent the interval scope of main joist is 100mm ~1000 mm.

6. The arcuate-faced quick assembly structure as recited in claim 5, wherein said sculpted keel assembly further comprises: a plurality of third fossil fragments, a plurality of third fossil fragments set up between a plurality of main joist and a plurality of false keel, arbitrary third fossil fragments are connected respectively a plurality of main joist, a plurality of false keel, it is adjacent the interval scope of third fossil fragments is 50mm ~300 mm.

7. The rapid assembling structure for the arc-shaped surface according to claim 5, wherein a plurality of first assembling grooves are formed in one side of the main keel, the distance between every two adjacent first assembling grooves is 20 mm-1000 mm, and the auxiliary keel is fixed on the first assembling grooves.

8. The arcwall-shaped face rapid assembly structure of claim 6, wherein the main keel, the cross runner and the third keel are all any one of galvanized steel plates, angle steels, square tubes, channel steels and light steel keels.

9. The cambered surface rapid assembly structure of claim 6, wherein one side or two sides of the third keel are provided with a plurality of second assembly grooves, the distance between every two adjacent second assembly grooves ranges from 20mm to 1000mm, and the main keel and the auxiliary keel are fixedly arranged in the second assembly grooves.

10. The arcuate-face quick assembly structure as claimed in claim 1, wherein said plate assembly includes: the sealing device comprises a plurality of first sealing plates, a plurality of first fasteners, a plurality of second sealing plates and a plurality of second fasteners;

the plurality of first sealing plates are arranged on the other side of the molding keel component;

the plurality of first fastening pieces are arranged on the plurality of first sealing plates and connected with the molding keel assembly;

the second sealing plates are staggered and covered on the first sealing plates;

the plurality of second fasteners are arranged on the plurality of second sealing plates and penetrate through the plurality of first sealing plates to be connected with the molding keel assembly.

11. The arcuate-face quick assembly structure as claimed in claim 10, wherein said first plurality of closure plates and said second plurality of closure plates include, but are not limited to, flexible non-resilient plates.

Technical Field

The invention relates to the technical field of building structures, in particular to a rapid arc-shaped surface assembling structure.

Background

In the prior art, the arc surface assembly structure is usually made of: wood board, gypsum board, calcium silicate board, aluminum board and glass fiber reinforced gypsum board; the arc-shaped surface assembly structure made of the wood board has the defect of poor toughness, is easy to crack after being bent, and has low fire-proof grade, poor dimensional stability and large deformation; the arc-shaped surface assembly structure made of the gypsum board has the defect of poor toughness, is easy to crack after being bent and processed, and has low fire-proof grade; the arc-shaped surface assembly structure made of the calcium silicate plate has the defect of poor toughness, is easy to crack after being bent and processed, and has low fire-proof grade; the arc-shaped surface assembly structure made of the aluminum plate is easy to generate a sound resonance phenomenon, cannot be used in places with acoustic requirements, and has a plurality of assembly gaps; the arc-shaped surface assembling structure of the glass fiber reinforced gypsum board material is heavy, the assembling speed is low, and the assembling precision is low; and the arc-shaped surface rapid assembly structure made of the materials can not be bent on site, and the manufacturing and installation time is long.

Disclosure of Invention

According to an embodiment of the present invention, there is provided an arc-shaped surface rapid assembly structure, including: the device comprises a bearing assembly, a modeling keel assembly and a sealing plate assembly;

the closing plate component is arranged on the modeling keel component;

the modeling keel assembly is arranged on the bearing assembly;

the load bearing assembly is connected to an external building.

Further, the bearing assembly comprises: one end of the connecting piece is fixed on the building, and the other end of the connecting piece is connected with the modeling keel component.

Further, the bearing component also comprises: the plurality of hanging pieces are arranged on the modeling keel assembly, and the plurality of hanging pieces are connected with the other end of the connecting piece and used for connecting the modeling keel assembly and the connecting piece.

Further, the bearing component also comprises: the bearing parts are arranged on the outer wall of the building, and the bearing parts are connected with one ends of the connecting pieces and used for fixing one ends of the connecting pieces on the building.

Further, the molding keel assembly comprises: a plurality of main keels and a plurality of auxiliary keels;

a plurality of main keels are connected with the bearing component;

a plurality of false keel sets up in one side of a plurality of main joist, and every false keel links to each other with a plurality of main joist, and the interval of adjacent false keel is 50mm ~300mm, and the interval scope of adjacent main joist is 100mm ~1000 mm.

Further, the molding keel assembly further comprises: a plurality of third fossil fragments, a plurality of third fossil fragments set up between a plurality of main joist and a plurality of rider keel, and a plurality of main joist, a plurality of rider keel are connected respectively to arbitrary third fossil fragments, and the interval scope of adjacent third fossil fragments is 50mm ~300 mm.

Further, one side of main joist is equipped with the first assembly groove of a plurality of, and the interval scope of adjacent first assembly groove is 20mm ~1000mm, and the false keel is fixed on first assembly groove.

Further, the main keel, the auxiliary keel and the third keel are any one of galvanized steel plates, angle steels, square tubes, channel steels and light steel keels.

Furthermore, one side or both sides of third fossil fragments are equipped with a plurality of second assembly groove, and the interval scope of adjacent second assembly groove is 20mm ~1000mm, and main joist and false keel are fixed to be set up in the second assembly groove.

Further, the closure plate assembly comprises: the sealing device comprises a plurality of first sealing plates, a plurality of first fasteners, a plurality of second sealing plates and a plurality of second fasteners;

the plurality of first sealing plates are arranged on the other side of the molding keel component;

the first fastening pieces are arranged on the first sealing plates and connected with the molding keel assembly;

the second sealing plates are staggered and covered on the first sealing plates;

a plurality of second fastener sets up on a plurality of second shrouding, and a plurality of second fastener runs through the first shrouding of a plurality of and links to each other with the molding keel subassembly.

Further, the plurality of first closing plates and the plurality of second closing plates include, but are not limited to, flexible non-resilient plates.

According to the arc-shaped surface rapid assembly structure provided by the embodiment of the invention, the defect that sound resonance is easily generated in the prior art is overcome, and the arc-shaped surface rapid assembly structure has the characteristics of good fireproof performance, high installation precision, high assembly speed and high stability.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and are intended to provide further explanation of the claimed technology.

Drawings

FIG. 1 is an assembly diagram of an arcuate-face quick assembly structure according to an embodiment of the present invention;

FIG. 2 is a cross-sectional view of an arcuate-face quick-fit structure according to an embodiment of the present invention;

FIG. 3 is an assembly diagram of a second arcuate-face quick assembly structure according to an embodiment of the present invention;

FIG. 4 is a cross-sectional view of a two arc-shaped face quick assembly structure according to an embodiment of the present invention;

FIG. 5 is an assembly diagram of a three arc-shaped surface rapid assembly structure according to an embodiment of the present invention;

FIG. 6 is a cross-sectional view of a three arc face quick assembly structure according to an embodiment of the present invention;

FIG. 7 is an assembly diagram of a four arc-shaped surface rapid assembly structure according to an embodiment of the present invention;

FIG. 8 is a cross-sectional view of a four arc face quick-fit arrangement according to an embodiment of the present invention;

FIG. 9 is an assembly view of a five arc-shaped face quick assembly structure according to an embodiment of the present invention;

fig. 10 is a cross-sectional view of a five arc-shaped face quick-assembly structure according to an embodiment of the invention.

Detailed Description

The present invention will be further explained by describing preferred embodiments of the present invention in detail with reference to the accompanying drawings.

First, a rapid arc-shaped surface assembling structure according to an embodiment of the present invention will be described with reference to fig. 1 to 10, which has a wide application range.

As shown in fig. 1 to 10, the arc-shaped surface rapid assembly structure according to the embodiment of the present invention includes: bearing component, molding keel component, shrouding subassembly.

Specifically, as shown in fig. 1 to 10, the bearing assembly is disposed at one side of the molding keel assembly, and the bearing assembly is connected to the building 4 and used for fixing the molding keel assembly on the building 4.

Further, as shown in fig. 1 to 10, the carrier assembly includes: the connecting piece 11, the material of connecting piece 11 is steel, and the one end of connecting piece 11 is fixed on building 4, and the other end of connecting piece 11 links to each other with the molding keel subassembly, and the molding keel subassembly passes through connecting piece 11 to be fixed on building 4.

Further, as shown in fig. 1 to 10, the carrying assembly may further use a plurality of hanging members 12; the plurality of hanging parts 12 are arranged on one side of the modeling keel assembly, the other end of the connecting part 11 is fixed with the plurality of hanging parts 12 and used for fixing the modeling keel assembly on the connecting part, and a user can adjust the distance between the modeling keel assembly and the building 4 by adjusting the plurality of hanging parts 12 and the connecting part 11.

Further, as shown in fig. 1-10, the bearing component can also use a plurality of bearing parts 13, the plurality of bearing parts 13 are embedded in the outer wall of the building 4, one end of the connecting part 11 is connected with the plurality of bearing parts 13, the effect of increasing the binding force between the embodiment and the building 4 is achieved, the plurality of bearing parts 13 are made of steel plates, and the stability of the whole structure is enhanced.

Specifically, as shown in fig. 1 to 10, the molding keel assembly is disposed on the bearing assembly, and the molding keel assembly is fixed to the building 4 through the bearing assembly.

Further, as shown in fig. 1-4 and 7-10, the molding keel assembly comprises: a plurality of main keels 21 and a plurality of auxiliary keels 22; a plurality of main keels 21 are connected with the bearing component; a plurality of false keel 22 sets up the opposite side at a plurality of main joist 21, and every false keel 22 links to each other with a plurality of main joist 21 for strengthen the stability of the inner structure of arcwall face rapid Assembly structure, simultaneously, main joist 21 and false keel 22 can carry out preprocessing according to the drawing requirement, more can accord with the molding of drawing requirement.

Further, as shown in fig. 5-6, the molding keel assembly further comprises: a plurality of third fossil fragments 23, a plurality of third fossil fragments 23 set up between a plurality of main joist and a plurality of rider keel, a plurality of main joist is connected respectively to arbitrary third fossil fragments 23, a plurality of rider keel links to each other, a plurality of main joist sets up the one side at third fossil fragments 23, a plurality of rider keel sets up the opposite side at a plurality of third fossil fragments 23, the interval scope of adjacent third fossil fragments 23 is 50mm ~300mm, the stability of this embodiment inner structure has been strengthened, and simultaneously, main fossil fragments 21 and rider keel 22 and third fossil fragments 23 all can be preprocessed according to the drawing requirement, more can accord with the molding of drawing requirement.

Further, as shown in fig. 1 to 10, the fixing manner among the adjacent main keel 21, the adjacent cross keel 22 and the adjacent third keel 23 includes, but is not limited to: welding fixation, clamping fixation and screw connection fixation.

Further, as shown in fig. 1 to 10, the distance between the adjacent furring channels 22 is 50mm to 300 mm.

Further, as shown in fig. 5 and 6, the distance between the adjacent third keels 23 ranges from 50mm to 300 mm.

Further, as shown in fig. 1 to 10, the distance between the adjacent main keels 21 ranges from 100mm to 1000 mm.

Further, as shown in fig. 1 to 10, the main keel 21, the cross keel 22 and the third keel 23 are made of any one of galvanized steel plates, angle steels, square steel tubes, square aluminum tubes, channel steels and light steel keels, and are made of a fire-proof material of grade a1, so that the main keel 21, the cross keel 22 and the third keel 23 are made of a fire-proof material of good fire-proof performance, light weight, strong ductility and strong load capacity, and a user can process the main keel 21, the cross keel 22 and the third keel 23 according to the drawing requirements and can better meet the modeling requirements of the drawing.

Further, as shown in fig. 3 to 4 and 7 to 8, one side of the main keel 21 is provided with a plurality of first assembling grooves 211, the first assembling grooves 211 include but are not limited to convex grooves or concave grooves, and the cross keel 22 is fixedly arranged in the first assembling grooves 211 for bearing the closing plate assembly.

Further, as shown in fig. 3 to 4 and 7 to 8, the auxiliary keels 22 are fixedly arranged on the first assembling grooves 211, and the scheme is an optimal scheme, so that the assembly is convenient, the installation time is reduced, and the installation accuracy of the invention is improved.

Further, as shown in fig. 3 to 4 and 7 to 8, the distance between the adjacent first assembling grooves 211 ranges from 20mm to 1000mm, the bearing space of the main keel 21 is fully utilized, and the mounting precision of the invention is improved.

Further, as shown in fig. 5 to 6, one side or both sides of the third keel 23 are provided with a plurality of second assembling grooves 233, and the main keel 21 and the cross keel 22 are fixed in the adjacent second assembling grooves 233, so that the structural stability of the embodiment is enhanced.

Further, as shown in fig. 5 to 6, the distance between the adjacent second assembling grooves 233 ranges from 20mm to 1000mm, the bearing space of the main keel 21 and the third keel 23 is fully utilized, and the mounting precision of the invention is improved.

Further, as shown in fig. 5-6, the third keel 23 is integrally formed by adopting a laser cutting technology, so that the production cost of the third keel 23 is reduced, the modeling accuracy is improved, and the structural stability of the third keel 23 is enhanced.

Further, as shown in fig. 9 to 10, one side of the main keel 21 is provided with a plurality of first assembling grooves 211, and the cross keel 22 is fixed between the adjacent first assembling grooves 211, so that the structural stability of the embodiment is enhanced.

Further, as shown in fig. 9 to 10, the distance between the adjacent first assembling grooves 211 ranges from 20mm to 1000mm, the bearing space of the main keel 21 is fully utilized, and the mounting precision of the invention is improved.

Further, as shown in fig. 9-10, the main keel 21 is integrally formed by adopting a laser cutting technology, so that the production cost of the main keel 21 is reduced, the modeling accuracy is improved, and the structural stability of the main keel 21 is enhanced.

Specifically, as shown in fig. 1 to 10, the closing plate assembly is disposed at the other side of the molding keel assembly.

Further, as shown in fig. 1 to 10, the sealing plate assembly includes: a plurality of first closing plates 31, a plurality of first fasteners 32, a plurality of second closing plates 33 and a plurality of second fasteners 34; a plurality of first closing plates 31 are arranged at the other side of the auxiliary keel 22; the first fastening pieces 32 are screws, the first fastening pieces 32 are nailed from one side of the first sealing plate 31 and penetrate through the first sealing plates 31 to be connected with the false keel 22, and the first fastening pieces 31 are used for fixing the first sealing plates 31 on the false keel 22 without welding, so that the operation is simple and the assembly is convenient; the plurality of second sealing plates 33 are staggered and covered on one sides of the plurality of first sealing plates 31; the plurality of second fastening pieces 34 are screws, the plurality of second fastening pieces 34 are nailed from one side of the second sealing plate 33 and penetrate through the plurality of second sealing plates 33 and the plurality of first sealing plates 31 to be connected with the false keel 22, and the plurality of second sealing plates 33 are fixed on the plurality of first sealing plates 31; meanwhile, the stability of the arc-shaped surface rapid assembly structure is ensured, welding is not needed, and the device has the advantages of simplicity in operation and convenience in assembly; the first sealing plates 31 and the second sealing plates 33 can be provided with through holes according to acoustic requirements, so that the effect of absorbing noise is achieved, the phenomenon of sound resonance is avoided, the sound absorption condition of acoustics is met, and meanwhile, a user can increase the number of mounting layers of the first sealing plates and the second sealing plates according to the acoustic requirements, so that the effect of reflecting sound waves is achieved.

Further, as shown in fig. 1 to 10, each of the plurality of first sealing plates 31 and the plurality of second sealing plates 33 includes, but is not limited to, a bendable non-resilient plate formed by compounding one or more materials, such as gypsum, calcium silicate, cement, ceramic, fiber, and other inorganic materials, with other auxiliary materials, wherein the bendable non-resilient plate is a preferred embodiment of the present invention, and has good fire resistance, and the bendable non-resilient plate can be directly bent at a rear or on-site to be sufficiently fitted to the shapes of the main keel 21 and the cross keel 22, so that the present invention has the characteristics of being bendable and non-resilient, and is convenient to process, short in installation time, and high in stability.

Further, when the hoisting position of the invention reaches a certain height from the ground, a conversion floor (not shown in the figure) can be added according to the building regulations.

The first embodiment is as follows: as shown in fig. 1-2, one end of the connecting member 11 is directly fixed on the top or wall of the building 4, or a plurality of bearing members 13 are embedded in the top or wall of the building 4, the connecting member 11 is connected with the plurality of bearing members 13 at one end of the connecting member 11 and is made of steel, the main keel 21 is directly fixed at the other end of the connecting member 11, or the other end of the connecting member 11 can be connected with a plurality of hanging members 12 fixed on the main keel 21, the hanging members 12 are made of steel materials including but not limited to steel, and the main keel can be made of any one of galvanized steel plates, angle steel, square tubes, channel steel and light steel keels. The cross runners 22 are arranged on one side of the main runners 21, each cross runner 22 is connected with a plurality of main runners 21, and the cross runners can be made of any one of galvanized steel plates, angle steels, square tubes, channel steels and light steel runners. The main keel 21 and the auxiliary keel 22 can be preprocessed according to the requirements of drawings, and the modeling of the drawings can be met. The plurality of first sealing plates 31 are arranged on one side of the false keel 22, the plurality of first fasteners 32 are nailed from one side of the first sealing plates 31 and penetrate through the plurality of first sealing plates 31 to be connected with the false keel 22, and the plurality of first sealing plates 31 are fixed on the false keel 22; the plurality of second sealing plates 33 are staggered and covered on one sides of the plurality of first sealing plates 31; a plurality of second fasteners 34 are driven into the second sealing plates 33 from one side of the second sealing plates 33, penetrate through the second sealing plates 33 and the first sealing plates 31 and are connected with the furring channel 22, and the second sealing plates 33 are fixed on the first sealing plates 31.

Example two: as shown in fig. 3 to 4, one end of the connecting member 11 is directly fixed on the top or the wall of the building 4, or a plurality of bearing members 13 are embedded in the top or the wall of the building 4, one end of the connecting member 11 is connected with the plurality of bearing members 13, the connecting member 11 is made of steel, the main keel 21 is arranged at the other end of the connecting member 11 and is directly fixed, or the other end of the connecting member 11 is connected with a plurality of hanging members 12 fixed on the main keel 21, the plurality of hanging members 12 are made of materials including but not limited to steel, the main keel 21 is made of light gauge steel, the cross runners 22 are fastened on a plurality of first assembling grooves 211 on one side of the main keel 21, each cross runner 22 is connected with a plurality of main keels 21, the main keel 21 and the cross runners 22 can be preprocessed according to the requirements of drawings, and can better meet the modeling requirements of drawings. The plurality of first sealing plates 31 are arranged on one side of the false keel 22, the plurality of first fasteners 32 are nailed from one side of the first sealing plates 31 and penetrate through the plurality of first sealing plates 31 to be connected with the false keel 22, and the plurality of first sealing plates 31 are fixed on the false keel 22; the plurality of second sealing plates 33 are staggered and covered on one sides of the plurality of first sealing plates 31; a plurality of second fasteners 34 are driven into the second sealing plates 33 from one side of the second sealing plates 33, penetrate through the second sealing plates 33 and the first sealing plates 31 and are connected with the furring channel 22, and the second sealing plates 33 are fixed on the first sealing plates 31.

Example three: as shown in fig. 5 to 6, one end of the connecting member 11 is directly fixed on the top or wall of the building 4, or a plurality of bearing members 13 are embedded on the top or wall of the building 4, one end of the connecting member 11 is connected with the plurality of bearing members 13, the connecting member 11 is made of steel, the main keel 21 is directly fixed with the other end of the connecting member 11, or the other end of the connecting member 11 is connected with a plurality of hanging members 12 fixed on the main keel 21, the plurality of hanging members 12 are made of steel materials including but not limited to steel, and the main keel 21 can be made of any one of galvanized steel plates, angle steel, square tubes, channel steel and light gauge steel. The third keel 23 is fixed on one side of the main keel 21, each third keel 23 is connected with a plurality of main keels 21, the third keel 23 is formed by processing galvanized steel sheets, the false keel 22 is fixed on the third keel 23, and the third keel 23 is positioned between the main keel and the false keel. One side or both sides of third fossil fragments 23 can also be equipped with a plurality of second assembly groove 233, main joist and false keel can also be fixed to be set up in a plurality of second assembly groove 233, and every false keel 22 connects many third fossil fragments 23, and false keel 22 can adopt any one of galvanized steel sheet, angle steel, square pipe, channel-section steel and light gauge steel. The main keel 21, the auxiliary keel 22 and the third keel 23 can be preprocessed according to the drawing requirements, and the modeling of the drawing requirements can be further met. The plurality of first sealing plates 31 are arranged on one side of the false keel 22, the plurality of first fasteners 32 are nailed from one side of the first sealing plates 31 and penetrate through the plurality of first sealing plates 31 to be connected with the false keel 22, and the plurality of first sealing plates 31 are fixed on the false keel 22; the plurality of second sealing plates 33 are staggered and covered on one sides of the plurality of first sealing plates 31; a plurality of second fasteners 34 are driven into the second sealing plates 33 from one side of the second sealing plates 33, penetrate through the second sealing plates 33 and the first sealing plates 31 and are connected with the furring channel 22, and the second sealing plates 33 are fixed on the first sealing plates 31.

In the fourth embodiment, as shown in fig. 7 to 8, one end of the connecting member 11 is directly fixed to the outer wall of the pillar or wall of the building 4. Or, a plurality of bearing parts 13 are pre-buried on the outer wall of the pillar or wall of the building 4, one end of each connecting part 11 is connected with the corresponding bearing part 13, the connecting part 11 is made of steel, the main keel 21 is directly fixed to the other end of the corresponding connecting part 11, or the other end of the corresponding connecting part 11 is connected with a plurality of hanging parts 12 fixed to the main keel 21, the plurality of hanging parts 12 are made of steel, the installation position of the main keel 21 can be adjusted by adjusting the positions of the plurality of hanging parts 12 on the connecting part 11, the main keel 21 is made of light steel keels, the auxiliary keel 22 is fixedly arranged on a plurality of first assembling grooves 211 on the other side of the main keel 21, the auxiliary keel 22 is made of light steel keels, the main keel 21 and the auxiliary keel 22 can be preprocessed according to drawing requirements, and the modeling which can meet the drawing requirements can be better. The plurality of first sealing plates 31 are arranged on one side of the false keel 22, the plurality of first fasteners 32 are nailed from one side of the first sealing plates 31 and penetrate through the plurality of first sealing plates 31 to be connected with the false keel 22, and the plurality of first sealing plates 31 are fixed on the false keel 22; the plurality of second sealing plates 33 are staggered and covered on one sides of the plurality of first sealing plates 31; a plurality of second fasteners 34 are driven into the second sealing plates 33 from one side of the second sealing plates 33, penetrate through the second sealing plates 33 and the first sealing plates 31 and are connected with the furring channel 22, and the second sealing plates 33 are fixed on the first sealing plates 31.

In the fifth embodiment, as shown in fig. 9 to 10, one end of the connecting member 11 is directly fixed to the outer wall of the pillar or wall of the building 4. Or, a plurality of bearing parts 13 are pre-buried on the outer wall of the pillar or wall of the building 4, one end of the connecting part 11 is connected with the plurality of bearing parts 13, the connecting part 11 is made of steel, the main keel 21 is directly fixed at the other end of the connecting part 11, or the other end of the connecting part 11 is connected with a plurality of hanging parts 12 fixed on the main keel 21, the plurality of hanging parts 12 are made of steel, the mounting position of the main keel 21 can be adjusted by adjusting the positions of the hanging parts 12 on the connecting part 11, the main keel 21 is formed by processing galvanized steel plates, the auxiliary keel 22 is arranged on a second assembling groove 233 at the outer side of the main keel 21, and the auxiliary keel 22 can be made of any one of galvanized steel plates, angle steels, square pipes, channel steels and light steel keels. The main keel 21 and the auxiliary keel 22 can be preprocessed according to the requirements of drawings, and the modeling of the drawings can be met. The plurality of first sealing plates 31 are arranged on one side of the false keel 22, the plurality of first fasteners 32 are nailed from one side of the first sealing plates 31 and penetrate through the plurality of first sealing plates 31 to be connected with the false keel 22, and the plurality of first sealing plates 31 are fixed on the false keel 22; the plurality of second sealing plates 33 are staggered and covered on one sides of the plurality of first sealing plates 31; a plurality of second fasteners 34 are driven into the second sealing plates 33 from one side of the second sealing plates 33, penetrate through the second sealing plates 33 and the first sealing plates 31 and are connected with the furring channel 22, and the second sealing plates 33 are fixed on the first sealing plates 31.

The installation mode of the invention is as follows:

the installation method is as follows: the main runner 21 and the cross runners 22 are pre-machined by the user to the desired configuration. After the bearing component is fixed with an external building, the bearing component is fixedly connected with the main keel 21. The main keel 21 is fixedly connected with the auxiliary keel 22. Finally, the user staggers and installs the first closure plates 31 and the second closure plates 33 on the cross runner 22.

The second installation mode: the user will take the molding keel assembly to the site after assembling and molding at the background. After the bearing assembly is fixed with an external building, the bearing assembly is fixedly connected with the modeling keel assembly, and the first closing plate 31 and the plurality of second closing plates 33 are installed on the auxiliary keel 22 in a staggered mode.

The mounting mode is three: the user will assemble the molding keel assembly with the first closure plate 31 at the back. After the user has secured the carrier assembly to the external structure, the user attaches the carrier assembly to the combination of the profile keel assembly and the first closure plate 31 and mounts the second closure plate 33 to the first closure plate 31 with a staggered seam.

The arc-shaped surface rapid assembly structure according to the embodiment of the invention is described above with reference to fig. 1 to 10, so that the defect that sound resonance is easily generated in the prior art is overcome, and the arc-shaped surface rapid assembly structure has the characteristics of good fire resistance, high installation accuracy, high assembly speed and high stability.

It should be noted that, in the present specification, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

While the present invention has been described in detail with reference to the preferred embodiments, it should be understood that the above description should not be taken as limiting the invention. Various modifications and alterations to this invention will become apparent to those skilled in the art upon reading the foregoing description. Accordingly, the scope of the invention should be determined from the following claims.