CN218580878U - Assembled building beam column node structure - Google Patents

Abstract

The utility model discloses an assembly type building beam column node structure, which belongs to the field of building beam column node equipment, and comprises a positioning component, wherein the top end and the bottom end of the positioning component are both provided with a first connecting component, the positioning component is used for clamping and installing two groups of first connecting components so as to realize the quick installation of an upper group of stand columns and a lower group of stand columns, the two side walls of the positioning component are positioned between the two groups of first connecting components, and a second connecting component is arranged between the two groups of first connecting components and is used for installing a cross beam; the locating component four corners just is located two sets ofly be provided with the bracing subassembly between the first connecting assembly, the bracing subassembly is used for strengthening locating component four corners department and supports the stationarity to two sets of first connecting assembly, the utility model discloses can convenience of customers assemble beam column node structure, can make things convenient for beam column node structure and assembly type structure beam column to be connected again, improved the convenience that beam column node structure used.

Description

Assembled building beam column node structure

Technical Field

The utility model relates to a building beam column node equipment field, more specifically say, relate to an assembly type structure beam column node structure.

Background

The fabricated building is a building which is formed by transferring a large amount of field operation work in the traditional building mode to a factory, processing and manufacturing building components and accessories (such as floor slabs, wall plates, stairs, balconies and the like) in the factory, transporting the components and accessories to a building construction site, and assembling and installing the components and the accessories on the site in a reliable connection mode.

However, the structure of the beam-column joint of the existing fabricated building is complex, and workers are inconvenient to install and fix the beam-column joint, so that the use convenience of the beam-column joint structure is reduced, and the beam-column joint structure of the fabricated building is provided for solving the existing problems.

SUMMERY OF THE UTILITY MODEL

1. Technical problem to be solved

To the problem that exists among the prior art, the utility model aims to provide an assembly type structure beam column node structure can convenience of customers assemble beam column node structure, can make things convenient for beam column node structure to be connected with the assembly type structure beam column again, has improved the convenience that beam column node structure used.

2. Technical scheme

In order to solve the above problems, the utility model adopts the following technical proposal.

The top end and the bottom end of the positioning assembly are respectively provided with a first connecting assembly, the positioning assembly is used for clamping and mounting two groups of first connecting assemblies so as to realize quick mounting of an upper group of stand columns and a lower group of stand columns, a second connecting assembly is arranged on two side walls of the positioning assembly and between the two groups of first connecting assemblies, and the second connecting assembly is used for mounting a cross beam;

the positioning assembly is characterized in that two groups of diagonal bracing assemblies are arranged between the first connecting assemblies and are used for strengthening the support stability of the four corners of the positioning assembly to the two groups of first connecting assemblies.

Furthermore, the locating component comprises a locating pipe, a plurality of groups of first tenons are annularly arranged at the top end and the bottom end of the locating pipe, and two groups of first tenons are arranged on two side walls of the locating pipe.

Further, first connecting element includes the flange board, the second tenon that is used for pegging graft first tenon is all offered to flange board inner chamber four corners both sides, the third tenon that is used for pegging graft second coupling assembling is all offered at flange board top surface both sides middle part, the fourth tenon that is used for pegging graft the bracing subassembly is all offered to flange board top surface four corners position.

Further, the inner diameter of the flange plate is the same as that of the positioning pipe.

Further, second coupling assembling includes the pterygoid lamina, pterygoid lamina top and bottom surface one end all are provided with the second tenon that is used for pegging graft third tenon, pterygoid lamina lateral wall surface just keeps away from second tenon one side and has seted up the multiunit connecting hole.

Furthermore, reinforcing plates are fixedly arranged in the middle of the two side walls of the wing plate, and third tenons for inserting the first tenons are arranged in the middle of one ends of the two groups of reinforcing plates.

Further, the bracing subassembly includes the connecting plate, the connecting plate both ends are all fixed and are provided with the fagging, fagging top and bottom middle part all are provided with the fourth tenon that is used for pegging graft fourth tenon.

3. Advantageous effects

Compared with the prior art, the utility model has the advantages of:

this scheme, through locating component, can install two sets of first connecting components, can make two sets of first connecting components carry out the block to second coupling assembling and bracing subassembly again spacing, when the prefabricated building needs to use beam column node structure, at this moment through one of them set of first connecting component, can link to each other with the stand of bottom, thereby can play preliminary installation effect, then with locating component again, second coupling assembling and bracing subassembly are pegged graft on the first connecting component of bottom, then with another first connecting component install on the stand of upper portion, and hoist and mount upper portion stand, make it peg graft on locating component, the first connecting component on upper portion will be pressed to second coupling assembling and bracing subassembly simultaneously, and when the pressure that the first connecting component on upper portion received is when big more, two sets of first connecting components are to locating component this moment, the second connecting component and bracing subassembly centre gripping are tighter, therefore beam column node structure is more stable, through second coupling assembling, can make things convenient for locating component to connect the crossbeam, and then can make things convenient for the assembled building beam column to assemble, simultaneously through the bracing subassembly, can strengthen locating component stability and four sets of first connecting component, the safe node structure of further supporting beam column has improved.

Drawings

Fig. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic view of the positioning assembly of the present invention;

fig. 3 is a schematic structural view of a first connection assembly of the present invention;

fig. 4 is a schematic structural view of a second connecting assembly of the present invention;

fig. 5 is a schematic structural view of the bracing assembly of the present invention.

The numbering in the figures illustrates:

1. a positioning assembly; 101. a positioning tube; 102. a first tenon; 103. a first mortise and tenon; 2. a first connection assembly; 201. a flange plate; 202. a second mortise; 203. a third mortise and tenon; 204. a fourth mortise and tenon; 3. a second connection assembly; 301. a wing plate; 302. a second tenon; 303. a reinforcing plate; 304. a third tenon; 305. connecting holes; 4. a diagonal bracing assembly; 401. a connecting plate; 402. a diagonal bracing plate; 403. and a fourth tenon.

Detailed Description

The technical solution in the embodiment of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiment of the present invention; obviously, the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention based on the embodiments of the present invention.

The embodiment is as follows:

referring to fig. 1, an assembly type building beam column node structure comprises a positioning assembly 1, wherein first connecting assemblies 2 are arranged at the top end and the bottom end of the positioning assembly 1, the positioning assembly 1 is used for clamping and installing two groups of first connecting assemblies 2 so as to quickly install an upper group of upright columns and a lower group of upright columns, second connecting assemblies 3 are arranged on two side walls of the positioning assembly 1 and between the two groups of first connecting assemblies 2, and the second connecting assemblies 3 are used for installing a cross beam;

diagonal bracing assemblies 4 are arranged at four corners of the positioning assembly 1 and between the two groups of first connecting assemblies 2, and the diagonal bracing assemblies 4 are used for enhancing the support stability of the four corners of the positioning assembly 1 to the two groups of first connecting assemblies 2;

through locating component 1, can install two sets of first connecting components 2, can make two sets of first connecting components 2 carry out the block spacing to second coupling assembling 3 and bracing subassembly 4 again, when the prefabricated building need use beam column node structure, at this moment through one of them set of first connecting components 2, can link to each other with the stand of bottom, thereby can play preliminary installation effect, then with locating component 1 again, second coupling assembling 3 and bracing subassembly 4 peg graft on the first connecting components 2 of bottom, then install another first connecting components 2 on the stand of upper portion, and hoist and mount upper portion stand, make it peg graft on locating component 1, first connecting components 2 on upper portion will press second coupling assembling 3 and bracing subassembly 4 simultaneously, and when the pressure that first connecting components 2 on upper portion received is big more, two sets of first connecting components 2 are to locating component 1 this moment, second coupling assembling 3 and bracing subassembly 4 centre gripping are tighter, therefore beam column node structure is more stable, through first coupling assembling component 3, and then make things convenient for locating component 1 to connect the beam, can make things convenient for the assembled building beam column node structure through four sets of first connecting components 1 further the bracing subassembly, the safe angle department of bracing subassembly has improved.

Referring to fig. 2, locating component 1 includes registration arm 101, registration arm 101 top and bottom all encircle and are equipped with the first tenon 102 of multiunit, two sets of first tenons 103 have all been seted up to registration arm 101 both sides wall, through the registration arm 101 in the locating component 1, can play the effect that bears the support, can carry out the installation of pegging graft with two sets of first coupling components 2 through the first tenon 102 of multiunit again, through first tenon 103, can make things convenient for registration arm 101 to carry out the block to second coupling components 3, the stability in use of second coupling components 3 has been improved.

Referring to fig. 2 and 3, the first connecting assembly 2 includes a flange plate 201, second tenons 202 used for inserting the first tenons 102 are all provided at two sides of four corners of an inner cavity of the flange plate 201, third tenons 203 used for inserting the second connecting assemblies 3 are all provided at two sides of the top surface of the flange plate 201, fourth tenons 204 used for inserting the diagonal bracing assemblies 4 are all provided at four corners of the top surface of the flange plate 201, through the flange plate 201 of the first connecting assembly 2, not only can the stand be externally connected, but also a space can be provided for the second tenons 202, so that the first tenons 102 can be clamped on the flange plate 201 and the positioning pipe 101, and the stability of connection between the flange plate and the positioning pipe can be improved, through the third tenons 203 and the fourth tenons 204, the clamping of the second connecting assemblies 3 and the diagonal bracing assemblies 4 can be respectively limited, and further the beam column node structure can be conveniently assembled by a user.

Referring to fig. 2 and 3, the inner diameter of the flange plate 201 is the same as the inner diameter of the positioning pipe 101, so that the stability of the connection between the flange plate 201 and the positioning pipe 101 can be improved.

Referring to fig. 3, fig. 4, second coupling assembling 3 includes pterygoid lamina 301, pterygoid lamina 301 top and bottom surface one end all are provided with the second tenon 302 that is used for pegging graft third tenon 203, pterygoid lamina 301 lateral wall surface just keeps away from second tenon 302 one side and has seted up multiunit connecting hole 305, pterygoid lamina 301 in the second coupling assembling 3, can be through the nimble third tenon 203 department of block on flange plate 201 of second tenon 302, thereby can improve the stability of pterygoid lamina 301 installation, and pterygoid lamina 301 can play again and support two sets of first coupling assembling 2, and then can improve beam column node structure stability in use, through multiunit connecting hole 305, can the external crossbeam of convenience of user, thereby can improve the convenience of crossbeam installation.

Referring to fig. 2 and 4, reinforcing plates 303 are fixedly arranged in the middle of two side walls of the wing plate 301, third tenons 304 for inserting the first tenons 103 are arranged in the middle of one ends of the two groups of reinforcing plates 303, and the middle of the wing plate 301 can be inserted in the middle of the positioning tube 101 through the reinforcing plates 303 in cooperation with the third tenons 304, so that the use stability of the wing plate 301 is further improved.

Referring to fig. 2 and 5, the inclined strut assembly 4 includes a connecting plate 401, inclined strut plates 402 are fixedly arranged at both ends of the connecting plate 401, fourth tenons 403 for inserting the fourth mortise tenon 204 are arranged at the top ends and the bottom ends of the inclined strut plates 402, the connecting plate 401 in the inclined strut assembly 4 can fix the two groups of inclined strut plates 402, so that the two structural stability can be realized, and then the fourth tenons 403 can be inserted into the fourth mortise tenon 204, so that the stability of the inclined strut assembly 4 for supporting the two groups of first connecting assemblies 2 can be improved.

When in use: through the positioning component 1, not only can two groups of first connecting components 2 be installed, but also two groups of first connecting components 2 can be used for clamping and limiting a second connecting component 3 and an inclined strut component 4, when the beam column node structure needs to be used in an assembly type building, at the moment, the first connecting components 2 can be connected with the stand column at the bottom end through one group of the first connecting components 2, so that a primary installation effect can be achieved, then the positioning component 1, the second connecting components 3 and the inclined strut components 4 are inserted into the first connecting components 2 at the bottom end, then the other first connecting component 2 is installed on the stand column at the upper part, and the stand column at the upper part is hoisted and inserted into the positioning component 1, meanwhile, the first connecting components 2 at the upper part can press and hold the second connecting components 3 and the inclined strut components 4, when the pressure on the first connecting components 2 at the upper part is higher, the two groups of the first connecting components 2 clamp the positioning component 1, the second connecting components 3 and the inclined strut components 4 more tightly, so that the beam column node structure is more stable, the first connecting components 3 can be connected through the second connecting components 1, so that the beam column node structure can be conveniently connected, and the beam can be conveniently used in the assembly type building, and the beam structure can be further, and the four groups of the beam column structure can be enhanced;

the positioning pipe 101 in the positioning assembly 1 can play a role in bearing and supporting, and can be inserted and installed with two groups of first connecting assemblies 2 through a plurality of groups of first tenons 102, the positioning pipe 101 can conveniently clamp the second connecting assembly 3 through the first mortise 103, and the use stability of the second connecting assembly 3 is improved;

through the flange plate 201 in the first connecting assembly 2, the column can be externally connected, and a space can be provided for the second tenon 202, so that the flange plate 201 can be clamped with the first tenon 102 on the positioning pipe 101, the connection stability of the flange plate and the positioning pipe can be further improved, and through the third tenon 203 and the fourth tenon 204, the second connecting assembly 3 and the diagonal bracing assembly 4 can be respectively clamped and limited, so that a user can conveniently assemble a beam-column node structure;

through the wing plate 301 in the second connecting assembly 3, the wing plate 301 can be flexibly clamped at the third concave tenon 203 on the flange plate 201 through the second tenon 302, so that the installation stability of the wing plate 301 can be improved, the wing plate 301 can also play a role of supporting two groups of first connecting assemblies 2, the use stability of a beam column node structure can be improved, a user can conveniently and externally connect a cross beam through a plurality of groups of connecting holes 305, the installation convenience of the cross beam can be improved, the middle part of the wing plate 301 can be inserted into the middle part of the positioning tube 101 through the reinforcing plate 303 in cooperation with the third tenon 304, and the use stability of the wing plate 301 is further improved;

through connecting plate 401 in the bracing subassembly 4, can fix two sets of bracing boards 402 to can make the two structural stability, then through fourth tenon 403, can peg graft each other with fourth tenon 204, and then can improve the stability that bracing subassembly 4 supported two sets of first connecting elements 2.

The above is only a preferred embodiment of the present invention; the scope of the present invention is not limited thereto. Any person skilled in the art should also be able to cover the protection scope of the present invention by replacing or changing the technical solution and the modified concept of the present invention within the technical scope of the present invention.

Claims (7)

1. The utility model provides an assembly type structure beam column node structure which characterized in that: the positioning device comprises a positioning component (1), wherein first connecting components (2) are arranged at the top end and the bottom end of the positioning component (1), the positioning component (1) is used for clamping and installing two groups of first connecting components (2) so as to quickly install an upper group of stand columns and a lower group of stand columns, a second connecting component (3) is arranged on two side walls of the positioning component (1) and between the two groups of first connecting components (2), and the second connecting component (3) is used for installing a cross beam;

locating component (1) four corners just is located two sets of be provided with bracing subassembly (4) between first connecting elements (2), bracing subassembly (4) are used for strengthening locating component (1) four corners department and support the stationarity to two sets of first connecting elements (2).

2. The fabricated building beam-column joint structure of claim 1, wherein: the positioning assembly (1) comprises a positioning pipe (101), a plurality of groups of first tenons (102) are arranged at the top end and the bottom end of the positioning pipe (101) in an encircling mode, and two groups of first concave tenons (103) are arranged on two side walls of the positioning pipe (101).

3. The fabricated building beam-column joint structure of claim 2, wherein: first connecting element (2) are including flange board (201), second mortise (202) that are used for pegging graft first tenon (102) are all offered to flange board (201) inner chamber four corners both sides, third mortise (203) that are used for pegging graft second coupling assembling (3) are all offered at flange board (201) top surface both sides middle part, fourth mortise (204) that are used for pegging graft bracing subassembly (4) are all offered to flange board (201) top surface four corners position.

4. A fabricated building beam-column joint structure according to claim 3, wherein: the inner diameter of the flange plate (201) is the same as that of the positioning pipe (101).

5. A fabricated building beam-column joint structure according to claim 3, wherein: second coupling assembling (3) are including pterygoid lamina (301), pterygoid lamina (301) top and bottom surface one end all are provided with second tenon (302) that are used for pegging graft third tenon (203), pterygoid lamina (301) a lateral wall surface just keeps away from second tenon (302) one side and has seted up multiunit connecting hole (305).

6. The fabricated building beam-column joint structure according to claim 5, wherein: reinforcing plates (303) are fixedly arranged in the middle parts of two side walls of the wing plate (301), and third tenons (304) used for being inserted into the first tenons (103) are arranged in the middle parts of one ends of the two groups of reinforcing plates (303).

7. The fabricated building beam-column joint structure according to claim 3, wherein: bracing subassembly (4) are including connecting plate (401), connecting plate (401) both ends all are fixed and are provided with inclined supporting plate (402), inclined supporting plate (402) top and bottom middle part all are provided with fourth tenon (403) that are used for pegging graft fourth tenon (204).

Images