CN210737774U

CN210737774U - Connecting node of polygonal beam and end beam in assembled floor system

Info

Publication number: CN210737774U
Application number: CN201920775893.5U
Authority: CN
Inventors: 杨迪钢; 程娟
Original assignee: Yangdi Steel Shanghai Prefabricated Construction Co ltd
Current assignee: Yangdi Steel Shanghai Prefabricated Construction Co ltd
Priority date: 2019-05-27
Filing date: 2019-05-27
Publication date: 2020-06-12
Anticipated expiration: 2029-05-27

Abstract

The utility model discloses a connected node of multilateral roof beam and end beam in assembled superstructure system, including outside boundary beam, inboard boundary beam and with inboard boundary beam vertically end beam, inboard boundary beam is parallel with the outside boundary beam and sets up side by side, the end beam sets up to two, it has the fracture, two to open on the inboard boundary beam the tip of end beam is installed in the fracture and is connected with inboard boundary beam. The utility model discloses a open the fracture on the boundary beam of inboard, supply the end beam tip to imbed in the fracture to connect end beam and corresponding inboard boundary beam, can realize being connected of end beam and inboard boundary beam, do not destroy the wholeness of outside boundary beam again, guaranteed the bearing capacity at connection position, simultaneously, the setting of fracture can also carry on spacingly to two end beams in the fracture, avoid the end beam to break away from the fracture because deformation in the use, improved the stability of end beam structure.

Description

Connecting node of polygonal beam and end beam in assembled floor system

Technical Field

The utility model relates to a connected node of multilateral roof beam and end beam among assembly type superstructure system belongs to the assembly type structure field.

Background

The building assembled by prefabricated parts on the construction site is called as an assembly building, wherein the assembly building is divided into five types such as a block building, a plate building, a box type building, a framework plate building and a lifting plate and lifting layer building according to the form and construction method of prefabricated parts.

In prefabricated buildings, the floor system is generally composed of edge beams and floor beams erected between the edge beams, and in order to solve the problem of reduced bearing effect of the floor beams due to excessively large span, a single longer floor beam is generally divided into a plurality of floor beam units, and an end beam is additionally arranged between the two floor beam units, so that a stable connecting structure for the end beam and the edge beam is continued, and the end beam can be stably erected between the edge beams.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a polygonal roof beam and end beam's connected node in assembled superstructure system, this connected node not only can realize the stable connection of end beam and boundary beam, can also solve the connection problem of polygonal roof beam and end beam.

In order to achieve the above purpose, the utility model adopts the technical scheme that: including outside boundary beam, inboard boundary beam and with inboard boundary beam vertically end beam, inboard boundary beam is parallel with outside boundary beam and sets up side by side, the end beam sets up to two, it has the fracture, two to open on the inboard boundary beam the tip of end beam is installed in the fracture and is connected with inboard boundary beam.

The further improved scheme in the technical scheme is as follows:

1. in the above scheme, two end beams are arranged at intervals, and a square pipe is arranged between the two end beams at the fracture.

2. In the scheme, a C-shaped block is arranged in the opening of the outer side edge beam, corresponds to the fracture and is connected with the square pipe.

3. In the scheme, the opening of the C-shaped block faces back to one side of the end beam and is connected with the outer side edge beam through the tapping screw.

4. In the above scheme, outside boundary beam and inboard boundary beam are C shaped steel, just the opening of outside boundary beam and inboard boundary beam all is located the one side that is close to the end beam, the end beam is connected with inboard boundary beam through the angle steel that is arranged in inboard boundary beam opening.

5. In the scheme, the height of the angle steel is equal to the width of the opening of the inner side edge beam.

Because of above-mentioned technical scheme's application, compared with the prior art, the utility model have the following advantage:

1. the utility model discloses polygonal roof beam and end beam's connected node in assembled superstructure system, it includes outside boundary beam, inboard boundary beam and with inboard boundary beam vertically end beam, inboard boundary beam is parallel with the outside boundary beam and sets up side by side, the end beam sets up to two, it has the fracture, two to open on the inboard boundary beam the tip of end beam is installed in the fracture and is connected with inboard boundary beam, through opening the fracture on the inboard boundary beam, supplies during end beam tip embedding fracture to connect end beam and corresponding inboard boundary beam, can realize being connected of end beam and inboard boundary beam, do not destroy the wholeness of outside boundary beam again, guaranteed the bearing capacity at connection position, simultaneously, the setting of fracture can also carry on spacingly to two end beams in the fracture, avoids the end beam to break away from the fracture because deformation in the use, has improved the stability of end beam structure.

2. The connecting node of the polygonal beam and the end beam in the assembly type floor system has the advantages that the two end beams are arranged at intervals, the square pipe is arranged between the two end beams at the fracture, and the square pipe is arranged between the two end beams at the fracture, so that the load capacity of the two end beams in the vertical direction can be enhanced while the two end beams are connected; install a C-shaped piece in the opening of its outside boundary beam, this C-shaped piece corresponds and with square union coupling with the fracture, connects the square pipe of end beam through the C-shaped piece in the opening of outside boundary beam, can utilize the outside boundary beam intensity at C-shaped piece reinforcing connection position, can connect end beam and outside boundary beam again, improves the structural strength at butt joint position, and then the stability of reinforcing superstructure system architecture.

Drawings

Fig. 1 is an overall structure schematic diagram of a connection node of a polygonal beam and an end beam in the assembly type floor system of the utility model;

FIG. 2 is a schematic view of the structure of the fracture.

In the following figures: 1. an outboard side rail; 11. c-shaped blocks; 2. an inboard side rail; 3. an end beam; 31. a square tube; 32. angle steel; 4. and (5) breaking.

Detailed Description

Example 1: a connecting node of a multi-edge beam and an end beam in an assembly type floor system is shown in the attached drawing 1-2 and comprises an outer side edge beam 1, an inner side edge beam 2 and an end beam 3 perpendicular to the inner side edge beam 2, wherein the inner side edge beam 2 and the outer side edge beam 1 are parallel and arranged in parallel, the number of the end beams 3 is two, a fracture 4 is formed in the inner side edge beam 2, and the end parts of the two end beams 3 are installed in the fracture 4 and connected with the inner side edge beam 2.

The two end beams 3 are arranged at intervals, and a square pipe 31 is arranged between the two end beams 3 at the fracture 4; a C-shaped block 11 is arranged in the opening of the outer side edge beam 1, and the C-shaped block 11 corresponds to the fracture 4 and is connected with the square pipe 31; the opening of the C-shaped block 11 faces away from the end beam 3 and is connected to the outer side edge beam 1 by a tapping screw.

The outer side edge beam 1 and the inner side edge beam 2 are made of C-shaped steel, the openings of the outer side edge beam 1 and the inner side edge beam 2 are positioned at one side close to the end beam 3, and the end beam 3 is connected with the inner side edge beam 2 through angle steel 32 positioned in the opening of the inner side edge beam 2; the height of the angle steel 32 is equal to the width of the opening of the inner side sill 2.

Example 2: a connecting node of a multi-edge beam and an end beam in an assembly type floor system is shown in the attached drawing 1-2 and comprises an outer side edge beam 1, an inner side edge beam 2 and an end beam 3 perpendicular to the inner side edge beam 2, wherein the inner side edge beam 2 and the outer side edge beam 1 are parallel and arranged in parallel, the number of the end beams 3 is two, a fracture 4 is formed in the inner side edge beam 2, and the end parts of the two end beams 3 are installed in the fracture 4 and connected with the inner side edge beam 2.

When the connecting joint of the polygonal beam and the end beam in the assembled floor system is adopted, the fracture is formed in the inner side edge beam, the end part of the end beam is embedded into the fracture and connected with the end beam and the corresponding inner side edge beam, so that the connection between the end beam and the inner side edge beam can be realized, the integrity of the outer side edge beam is not damaged, the bearing capacity of a connecting part is ensured, meanwhile, the fracture can limit the two end beams in the fracture, the end beams are prevented from being separated from the fracture due to deformation in the using process, and the stability of the end beam structure is improved;

in addition, the square pipe is arranged between the two end beams at the fracture, so that the load capacity of the two end beams in the vertical direction can be enhanced while the two end beams are connected; the C-shaped block in the opening of the outer side boundary beam is connected with the square pipe of the end beam, so that the strength of the outer side boundary beam at the connecting part can be enhanced by the C-shaped block, the end beam and the outer side boundary beam can be connected, the structural strength of the butt joint part is improved, and the stability of the structure of the floor system is enhanced.

The above embodiments are only for illustrating the technical concept and features of the present invention, and the purpose of the embodiments is to enable people skilled in the art to understand the contents of the present invention and to implement the present invention, which cannot limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered by the protection scope of the present invention.

Claims

1. The utility model provides a connected node of multilateral roof beam and end beam in assembled superstructure system which characterized in that: including outside boundary beam (1), inboard boundary beam (2) and with inboard boundary beam (2) vertically end beam (3), inboard boundary beam (2) are parallel with outside boundary beam (1) and set up side by side, end beam (3) set up to two, it has fracture (4), two to open on inboard boundary beam (2) the tip of end beam (3) is installed in fracture (4) and is connected with inboard boundary beam (2).

2. The connecting node of the polygonal beam and the end beam in the fabricated floor system according to claim 1, wherein: the two end beams (3) are arranged at intervals, and a square pipe (31) is arranged between the two end beams (3) at the fracture (4).

3. The connecting node of the polygonal beam and the end beam in the fabricated floor system according to claim 2, wherein: a C-shaped block (11) is installed in an opening of the outer side edge beam (1), and the C-shaped block (11) corresponds to the fracture (4) and is connected with the square pipe (31).

4. The connecting node of the polygonal beam and the end beam in the fabricated floor system according to claim 3, wherein: the opening of the C-shaped block (11) faces back to one side of the end beam (3) and is connected with the outer side edge beam (1) through a tapping screw.

5. The connecting node of the polygonal beam and the end beam in the fabricated floor system according to claim 1, wherein: outside boundary beam (1) and inboard boundary beam (2) are C shaped steel, just the opening of outside boundary beam (1) and inboard boundary beam (2) all is located the one side that is close to end beam (3), end beam (3) are connected with inboard boundary beam (2) through angle steel (32) that are located in inboard boundary beam (2) opening.

6. The connecting node of the polygonal beam and the end beam in the fabricated floor system according to claim 5, wherein: the height of the angle steel (32) is equal to the width of the opening of the inner side edge beam (2).