CN108412051B - Connecting part of assembled building and assembled cage structure building - Google Patents

Abstract

The embodiment of the invention discloses a connecting part for an assembled building, which comprises a part body which is integrally in a hexagonal prism shape, wherein two opposite side edges of the part body are respectively provided with a first continuous groove, and the extending direction of the first continuous groove is consistent with the length direction of the part body; two side surfaces of the component body which are not adjacent to the first continuous groove are arranged in parallel; the cross section of the first continuous groove is isosceles trapezoid, two second continuous grooves are oppositely arranged on two side surfaces in the first continuous groove, and the component body is symmetrically arranged about the maximum diagonal surface passing through the side edges provided with the first continuous groove. The connecting component can be used for connecting and assembling the assembly modules of the fabricated building, and is directly assembled and connected with the assembly modules of the structural adaptations of the connecting component, so that the construction of the fabricated building can be completed without secondary construction, the construction is simple and convenient, and the connection is firm and reliable.

Description

Connecting part of assembled building and assembled cage structure building

Technical Field

The invention belongs to the technical field of buildings, and particularly relates to a connecting component of an assembled building and an assembled cage structure building.

Background

Fabricated building refers to a building assembled from prefabricated components at a worksite. The building has the advantages of high building speed, less limitation of weather conditions, labor saving and building quality improvement. At present, most of assembled buildings adopt traditional reinforced concrete materials as raw materials of assembled modules of the assembled buildings, the assembled modules are connected by adopting traditional modes of bolt connection, welding and the like, concrete is poured on the assembled connection parts at construction sites after the assembled connection, and the assembly of the modules can be completed after the concrete is poured and molded. Modular production and assembly of the building is not fully achieved.

Disclosure of Invention

At least one of the above problems is addressed by embodiments of the present invention which provide a connecting member for a fabricated building comprising a member body having a hexagonal prism shape as a whole, the member body being disposed symmetrically about its maximum diagonal surface.

The connecting component of the fabricated building comprises a component body which is integrally in a hexagonal prism shape, wherein two opposite side edges of the component body are respectively provided with a first continuous groove, and the extending direction of the first continuous groove is consistent with the length direction of the component body; two side surfaces of the component body which are not adjacent to the first continuous groove are arranged in parallel; the cross section of the first continuous groove is isosceles trapezoid, two second continuous grooves are oppositely arranged on two side surfaces in the first continuous groove, and the component body is symmetrically arranged about the maximum diagonal surface passing through the side edges provided with the first continuous groove.

Some embodiments of the invention provide a connecting component of a fabricated building, wherein the first continuous groove is an open groove.

Some embodiments of the invention provide a connecting component of a fabricated building, wherein a cavity penetrating through two bottom surfaces of the component body is arranged in the component body.

Some embodiments of the invention provide a connecting component of a fabricated building, wherein a plurality of cavities are independent of each other.

Some embodiments of the invention provide a connecting component for a fabricated building, with four cavities.

Some embodiments of the invention provide a connecting component of a fabricated building, wherein the connecting component is an integrally formed metal component, a wood component and an engineering plastic component.

Some embodiments of the present invention further provide an assembly module for an assembled building, where the assembly module includes a structure adapted to the connection component disclosed in the embodiments of the present invention.

The invention provides an assembly module of an assembly type building, which comprises a structure matched with a connecting part disclosed by the embodiment of the invention, wherein the side surface of the assembly module is provided with a concave structure, and the cross section of the concave structure is trapezoidal; the opening edges of the trapezoid concave structures are respectively provided with a first protruding part, and the two first protruding parts are arranged in opposite directions, so that the concave structures are in a necking trapezoid shape; a second protruding part is arranged on the first protruding part and faces the inside of the concave structure; when the connecting part is connected with the assembly module, the second protrusion is matched with the second continuous groove.

The assembly modules for the fabricated building disclosed by the embodiments of the invention are specifically column modules, beam modules or wall panel modules, and the column modules, the beam modules and/or the wall panel modules can be connected with each other by using the connecting parts of the fabricated building disclosed by the embodiments of the invention.

Some embodiments of the invention also disclose an assembled cage structure building, which comprises the connecting component of the assembled building disclosed by the embodiment of the invention and/or the assembly module disclosed by the embodiment of the invention.

The connecting component for the fabricated building disclosed by the invention is a fabricated building construction module produced in an industrial assembly line, and is assembled with other building modules, such as a column module, a wallboard module, a beam module and the like, on a construction site, so that the required high-cost, low-cost and emission-free structure can be obtained, the environmental protection requirement is met, the complete fabricated production of the building construction is realized, and the fabricated building construction component is a completely fabricated beam module and a fabricated cage-type structure building.

Drawings

FIG. 1 is a schematic perspective view of a connecting member of embodiment 1

FIG. 2 is a schematic perspective view of a connecting member of embodiment 2

FIG. 3 is a schematic view showing the structure of the bottom surface of the connecting member according to embodiment 2

FIG. 4 is a schematic view showing the structure of an assembled module adapted to the connection member according to embodiment 3

FIG. 5 is a schematic view showing a connection state of the connection member and the assembly module

FIG. 6 is a schematic perspective view of a connecting member of embodiment 4

Reference numerals

1. Component body 10, first continuous groove

100. Second continuous groove 2 cavity

21. First cavity 22 second cavity

3. Wallboard body 30, wallboard side

31. Recessed structure 311, first protruding portion

312. Second boss 32, wall surface

Detailed Description

Any "embodiment" described as "exemplary" in this disclosure is not necessarily to be construed as preferred or advantageous over other embodiments. Performance index testing in this method example unless otherwise specified, conventional testing methods in the art were employed.

Unless otherwise defined, technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Other raw materials, reagents, test methods and technical means not specifically mentioned in the present invention refer to raw materials and reagents commonly used by those skilled in the art, and experimental methods and technical means commonly employed. The first, second, etc. recited in the present invention are not strictly limited to the order of the first, second, etc. but are used for distinguishing between two or more elements. The numerical ranges disclosed herein, unless specifically stated otherwise, generally include all the optional values within the numerical ranges as well as the optional values within the error range that is generally acceptable in the art.

Numerous specific details are set forth in the following examples in order to provide a better understanding of the present invention. It will be understood by those skilled in the art that the present invention may be practiced without some of these specific details. In the examples, some methods, means, instruments, devices, etc. well known to those skilled in the art are not described in detail in order to facilitate the gist of the present invention.

As an alternative implementation manner provided by the disclosure embodiment, the connecting component of the fabricated building comprises a component body which is integrally in a hexagonal prism shape, wherein two opposite side edges of the component body are respectively provided with a first continuous groove, and the extending direction of the first continuous groove is consistent with the length direction of the component body; two side surfaces of the component body which are not adjacent to the first continuous groove are arranged in parallel; the cross section of the first continuous groove is isosceles trapezoid, two second continuous grooves are oppositely arranged on two side surfaces in the first continuous groove, and the component body is symmetrically arranged about the maximum diagonal surface passing through the side edges provided with the first continuous groove. As an alternative embodiment, the cross section of the connecting part body is regular hexagon, and the whole connecting part is regular hexagonal prism. As an alternative embodiment, the first continuous groove is generally configured as an open groove, i.e. the opening side of the isosceles trapezoid-shaped first continuous groove is long, the bottom side is small, and the open groove is favorable for assembling and adapting the connecting component and other assembly modules, so that the construction is facilitated.

As an alternative embodiment, the connecting part is internally provided with a cavity which penetrates through two bottom surfaces of the part body, and the arrangement of the cavity is beneficial to reducing the weight of the part and the cost; as a preferable technical scheme, the plurality of cavities are arranged in the connecting part and are mutually independent, and the plurality of cavities which are mutually independent are beneficial to reducing the weight of the connecting part and maintaining the strength of the structure of the connecting part; as an alternative embodiment, the connecting member is disposed axisymmetrically about its axis as a whole; as an alternative embodiment, the connection member is integrally formed from a metallic material, such as an aluminum alloy, steel, or the like. As an alternative embodiment, the connection part may be manufactured from wood, engineering plastic.

The embodiment of the invention discloses an assembly module for an assembly type building, which comprises a structure matched with a connecting part disclosed by the embodiment of the invention, and particularly, the side surface of the assembly module is provided with a concave structure, and the cross section of the concave structure is trapezoidal; the opening edges of the trapezoid concave structures are respectively provided with a first protruding part, and the two first protruding parts are arranged in opposite directions, so that the concave structures are in a necking trapezoid shape; a second protruding part is arranged on the first protruding part and faces the inside of the concave structure; when the connecting part is connected with the assembly module, the second protruding part is matched with the second continuous groove. When the assembly modules with the adapting structures are arranged in parallel for assembly, the adapting structures are combined with each other, a space capable of containing the connecting parts is formed between the assembly modules, the space is mutually adapted with the connecting parts, and the connection assembly between the assembly modules is completed.

As an alternative embodiment, the assembly modules for the fabricated building may be specifically column modules, beam modules or wall panel modules, and the column modules, beam modules and/or wall panel modules may be interconnected by the connection members for the fabricated building disclosed in the examples of the present invention; for example, the wall panels may be interconnected to one another to provide a larger area wall panel, the wall panels may be connected to the column for securing the wall panels to the column, the beams may be connected to the wall panels for securing the connection of the two, the column may be connected to the column to provide a stronger composite column, and so on.

Fig. 1 is a schematic perspective view of a connecting component in embodiment 1 of the present disclosure, where the connecting component in fig. 1 includes a component body 1, upper and lower sides of the component body 1 are parallel to each other and disposed on a horizontal plane, and on side edges of two sides, a first continuous groove 10 is respectively disposed, and the groove is disposed along a length direction of the connecting component, the first continuous groove 10 penetrates through two bottom surfaces of the connecting component, and viewed from the bottom surface, the first continuous groove is an open isosceles trapezoid groove, two second continuous grooves 100 are disposed on two waists of the trapezoid groove, and openings of the two second continuous grooves 100 are disposed opposite to each other.

Fig. 2 is a schematic perspective view of a connecting component in embodiment 2 of the present disclosure, in fig. 2, the connecting component includes a component body 1, upper and lower sides of the component body 1 are parallel to each other and disposed on a horizontal plane, and on side edges on both sides, a first continuous groove 10 is respectively disposed along a length direction of the connecting component, and the first continuous groove 10 penetrates through both bottom surfaces of the connecting component; four cavities are arranged in the connecting part, each cavity comprises a first cavity 21 adjacent to the upper surface and the lower surface and a second cavity 22 adjacent to the first continuous groove 10, and the four cavities are separated into four independent spaces by diagonal surfaces corresponding to the upper surface and the lower surface; seen from the bottom surface, as shown in fig. 3, the whole first continuous groove is an open isosceles trapezoid groove, two second continuous grooves 100 are arranged on two waists of the trapezoid groove, and the openings of the two second continuous grooves 100 are opposite; the first cavity 21 is triangular and symmetrically arranged on the upper side and the lower side of the central shaft, and the second cavity 22 is polygonal and symmetrically arranged on the left side and the right side of the central shaft; in fig. 3, the horizontal plane a-B is a plane passing through the shaft center, and the connecting member is symmetrical with respect to the horizontal plane a-B; the portion of the connecting member located above the face a-B may be referred to as a first portion and the portion located below the face a-B may be referred to as a second portion, the first portion being symmetrical with respect to the plane a-B.

Fig. 4 is a schematic cross-sectional view showing the structure of an assembly module capable of being fittingly connected with the connection member disclosed in embodiment 2 of the present invention as disclosed in embodiment 3 of the present invention. As shown in fig. 4, the assembly module is specifically a wall panel member including a wall panel body 3, wall surfaces 32 provided on both left and right sides, and a side surface 30 provided below, the side surface 30 of the wall panel member being provided with a recess structure 31 capable of accommodating a first portion of the connection member of embodiment 2, such as the first portion of the connection member shown in fig. 1; the whole isosceles trapezoid that is of concave structure 31, be provided with first bellying 311 on the open-ended both edges of concave structure 31 respectively, two first bellying 311 that set up in opposite directions make concave structure 31 be the throat trapezoidal, be provided with second bellying 312 on the internal surface of first bellying 312, two second bellying 312 set up in opposite directions the bottom of first continuous concave structure, when connecting piece's first part set up in concave structure 31, second bellying 311 and the continuous recess 100 looks adaptation of second, connecting piece first part is whole with the structural looks adaptation of wallboard part side.

The two wallboard modules shown in fig. 4 are connected with each other by using the connecting component shown in fig. 2, the connection state of which is shown schematically in fig. 5, the wallboard component M2 is adapted to be connected with the first part of the connecting component M1, and the wallboard component M3 is adapted to be connected with the second part of the connecting component M1, so as to obtain the wallboard component assembly shown in fig. 5. For the connection construction between the connecting component and the assembly module, a common construction mode can be adopted, for example, the side faces of the wallboards to be connected can be fixed, and then the connecting component with the shape matched with the cavity is penetrated into the cavity formed by the two side faces.

FIG. 6 is a perspective view of a connecting member of embodiment 5 of the present disclosure, the horizontal plane A-B being a plane passing through the axis of the member body 1, the member body 1 being symmetrical about the horizontal plane A-B; the portion of the connecting member located above the face a-B may be referred to as a first portion and the portion located below the face a-B may be referred to as a second portion, the first portion being symmetrical with respect to the plane a-B.

The connecting component for the fabricated building disclosed by the embodiment of the invention can be used for connecting the component modules of the fabricated building, such as connecting and assembling a beam module, a column module and a wallboard module, and the fabricated module with a structure matched with the structure of the connecting component can be directly connected and assembled by using the connecting component, so that the construction of the fabricated building can be completed without re-construction, and the construction is simple and convenient, and the connection is firm and reliable.

The foregoing description of the embodiments and the disclosure of data are illustrative, and the details and the essence of the technical solution of the present invention are more clear, and it should be understood that these details are not limitations on the spirit and scope of the present invention, and any combination and expansion of the technical features disclosed in the present invention are all within the scope of the present invention.

Claims (6)

1. The connecting component of the assembled building is characterized by comprising a component body (1) which is integrally in a hexagonal prism shape, wherein two opposite side edges of the component body (1) are respectively provided with a first continuous groove (10), and the extending direction of the first continuous groove (10) is consistent with the length direction of the component body (1); -two lateral sides of the component body (1) not adjacent to the first continuous groove (10) are arranged in parallel; the cross section of the first continuous groove (10) is isosceles trapezoid, two second continuous grooves (100) are oppositely arranged on two side surfaces in the first continuous groove (10), and the component body (1) is symmetrically arranged about the maximum diagonal surface passing through the side edges provided with the first continuous groove (10); the first continuous groove (10) is an open groove; the inside of the body (1) is provided with a cavity (2) penetrating through two bottom surfaces of the component body.

2. The connecting element of a building according to claim 1, characterized in that the cavities (2) are a plurality of and independent from each other.

3. The connection part of a building kit according to claim 1, characterized in that the cavities (2) are four.

4. The connection component of a fabricated building of claim 1, wherein the connection component is an integrally formed metal member, wood member, engineering plastic member.

5. A fabricated cage structure comprising the connecting member of any of claims 1-4 and a mounting module comprising a structure adapted to the connecting member of any of claims 1-4.

6. The fabricated cage structure according to claim 5, characterized in that the structure adapted to the connecting part according to any one of claims 1 to 4 is specifically: the side face of the assembly module is provided with a concave structure (31), and the cross section of the concave structure (31) is trapezoid; the opening edges of the trapezoid concave structures (31) are respectively provided with a first protruding part (311), and the two first protruding parts (311) are arranged in opposite directions, so that the concave structures (31) are in a necking trapezoid shape; a second protruding part (312) is arranged on the first protruding part (311), and the second protruding part (312) is arranged towards the inside of the concave structure (31); when the connecting part is connected with the assembly module, the second protruding part (312) is matched with the second continuous groove (100).