CN218861777U - Beam column node installation component - Google Patents

Abstract

The utility model provides a beam column node installation component, wherein a first inserting port and a second inserting port are arranged on a column component to be installed along the front-back direction, and the first inserting port and the second inserting port are arranged at intervals along the up-down direction; the mounting assembly includes: the upper flange mounting plate penetrates through the first inserting port and protrudes out of the column member, and the lower flange mounting plate penetrates through the second inserting port and protrudes out of the column member; and the beam component to be installed is fixedly welded with the upper flange installation plate and the lower flange installation plate. The utility model discloses a beam column node installation component has changed current nodal connection mode, has improved preparation efficiency, has practiced thrift the preparation cycle, and the component is conveniently deposited and is transported simultaneously.

Description

Beam column node installation component

Technical Field

The utility model relates to a building structure engineering technical field especially relates to a beam column node installation component.

Background

At present, the transformation from the traditional building to the industrialized building is greatly promoted in China. Compared with the problems of long construction period, serious environmental pollution, shortage of constructors and the like of the traditional building, the prefabricated steel structure building realizes the shortening of the construction period, the improvement of the construction efficiency and the reduction of the construction cost through the construction modes of factory manufacturing of prefabricated parts and field splicing. The partially-coated steel-concrete structural system is a novel steel-concrete combined structure formed by pouring concrete between H-shaped steel flanges, and the bearing capacity, the rigidity and the ductility of the partially-coated steel-concrete combined structure are superior to those of a pure steel structure or a reinforced concrete structure. Compared with the steel reinforced concrete, the partially-coated steel-concrete structural system has the advantages of high prefabrication degree of components, convenience in node connection, no template and the like. Meanwhile, the problems of fire prevention, corrosion prevention, sound insulation, structural vibration, heat preservation performance, living comfort, durability, secondary decoration and the like of the assembled steel structure house are effectively solved, and the assembled steel structure house becomes an assembled structure system with great development prospect.

When the existing partially-coated steel-concrete composite column (namely a PEC composite column) is manufactured, in order to ensure continuous and reliable stress at the joints, the brackets at the joints of the strong and weak axial beam column need to be welded on the steel ribs in advance. Because there are all brackets on four sides, this results in the component not having a complete plane, can influence the efficiency of concrete placement, component storage and transportation afterwards.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a novel beam column node installation component to make the component conveniently deposit and transport, this installation component is particularly useful for some cladding steel-concrete combination post.

Particularly, the utility model provides a beam column node installation component, a first inserting port and a second inserting port along the front and back direction are arranged on a column component to be installed, and the first inserting port and the second inserting port are arranged at intervals along the up and down direction;

the mounting assembly includes: the upper flange mounting plate penetrates through the first inserting port and protrudes out of the column component, and the lower flange mounting plate penetrates through the second inserting port and protrudes out of the column component;

and the beam component to be installed is welded and fixed with the upper flange installation plate and the lower flange installation plate.

Alternatively, the lower flange mounting plate may have a front-rear length greater than that of the upper flange mounting plate, so that the front-rear length of the portion of the column member from which the lower flange mounting plate protrudes is greater than that of the portion of the column member from which the upper flange mounting plate protrudes.

Optionally, a column stiffening plate is arranged on the surface of the column member facing the beam member and between the first insertion port and the second insertion port, and the column stiffening plate is welded and fixed with the fillet weld of the upper flange mounting plate and the lower flange mounting plate;

the beam member is welded and fixed with the column stiffening plate.

Optionally, the mounting assembly further comprises: and the vertical mounting plate is parallel to the front surface and the rear surface of the column member and is clamped between the upper flange mounting plate and the lower flange mounting plate.

Optionally, the vertical mounting plate is formed at the ends of the upper flange mounting plate and the lower flange mounting plate, so that the upper flange mounting plate, the vertical mounting plate and the lower flange mounting plate form a U-shaped stiffener with a longitudinal section with a forward opening.

Optionally, the U-shaped stiffener is an integrally formed piece.

Optionally, the column member is further provided with a plurality of column mounting holes along the front-rear direction, and the plurality of column mounting holes are formed in the region between the first interface and the second interface;

a plurality of first mounting holes along the fore-and-aft direction are formed in the vertical mounting plate corresponding to the plurality of column mounting holes, and the column mounting holes and the first mounting holes are penetrated by the fixing piece.

Optionally, the mounting assembly further comprises: a T-shaped connector having a first vertical connecting plate parallel to the front and rear surfaces of the column member and a second vertical connecting plate extending away from the column member from a side of the first vertical connecting plate remote from the column member;

the column component is also provided with a plurality of column mounting holes along the front-back direction, and the plurality of column mounting holes are formed in the area between the first inserting port and the second inserting port;

the first vertical connecting plate is clamped between the parts, protruding out of the column members, of the upper flange mounting plate and the lower flange mounting plate, a plurality of second mounting holes are formed in the first vertical connecting plate along the front-back direction corresponding to the column mounting holes, and the fixing piece penetrates through the column mounting holes and the second mounting holes.

Optionally, the beam member includes an upper flange plate, a lower flange plate and a web plate, the upper flange plate and the lower flange plate are arranged in parallel at an interval, the upper end and the lower end of the web plate are respectively fixed with the upper flange plate and the lower flange plate, and a plurality of beam mounting holes along the left-right direction are formed in the area of the web plate close to the column member;

a plurality of third mounting holes along the left and right direction are formed in the second vertical connecting plate corresponding to the plurality of beam mounting holes;

the mounting assembly further includes: the dull and stereotyped connecting piece corresponds a plurality of roof beam mounting holes on the dull and stereotyped connecting piece and offers a plurality of fourth mounting holes along left right direction and corresponds a plurality of third mounting holes and offers a plurality of fifth mounting holes along left right direction, and fourth mounting hole and roof beam mounting hole and fifth mounting hole and third mounting hole are worn to establish respectively to the mounting.

Optionally, the column member is provided with two columns of column mounting holes arranged at intervals in the left-right direction;

the projection of the second vertical connecting plate on the vertical plane is positioned between the two columns of column mounting holes.

The utility model discloses a beam column node installation component is through offering first interface and the second interface along the fore-and-aft direction on treating the erection column component, set up the installation component including top flange mounting panel and bottom flange mounting panel, wear to establish first interface and outstanding in the post component with the top flange mounting panel, wear to establish the second interface and outstanding in the post component with the bottom flange mounting panel, make and treat installation beam component and top flange mounting panel, bottom flange mounting panel welded fastening, current nodal connection mode has been changed, the efficiency of manufacture has been improved, the manufacturing cycle is practiced thrift, the component is conveniently deposited and is transported simultaneously.

The above and other objects, advantages and features of the present invention will become more apparent to those skilled in the art from the following detailed description of specific embodiments thereof taken in conjunction with the accompanying drawings.

Drawings

Some specific embodiments of the invention will be described in detail hereinafter by way of example and not by way of limitation with reference to the accompanying drawings. The same reference numbers in the drawings identify the same or similar elements or components. Those skilled in the art will appreciate that the drawings are not necessarily drawn to scale. In the drawings:

fig. 1 is a schematic structural view of a beam-column node mounting assembly and column member according to an embodiment of the present invention.

Fig. 2 is a schematic structural view of a plurality of column members.

Fig. 3 is a partially enlarged schematic view of the column member of fig. 2.

Fig. 4 is a schematic structural view of a beam-column node mounting assembly and column member according to another embodiment of the present invention.

Fig. 5 is a schematic structural view of the component and beam member of fig. 4.

Fig. 6 is a schematic structural view of a beam-column node mounting assembly and column member according to yet another embodiment of the present invention.

Fig. 7 is a schematic structural view of a beam-column joint mounting assembly and a column member according to yet another embodiment of the present invention.

Fig. 8 is a schematic structural view of the components and beam member of fig. 7.

Fig. 9 is a schematic view of the assembly of fig. 7 and a beam member completed using a flat plate connection.

Detailed Description

Fig. 1 is a schematic structural view of a beam-column node mounting assembly and column member 300 according to an embodiment of the present invention. Fig. 2 is a schematic view of a plurality of column members 300. Fig. 3 is a partially enlarged schematic view of the pillar member 300 of fig. 2. Fig. 4 is a schematic structural view of a beam-column node mounting assembly and column member 300 according to another embodiment of the present invention. Fig. 5 is a schematic structural view of the component and beam member 400 of fig. 4. Fig. 6 is a schematic structural view of a beam-column joint mounting assembly and a column member 300 according to yet another embodiment of the present invention. Fig. 7 is a schematic structural view of a beam-column node mounting assembly and a column member 300 according to yet another embodiment of the present invention. Fig. 8 is a schematic structural view of the member of fig. 7 and a beam member 400. Fig. 9 is a schematic view of the structure of fig. 7 after the assembly with the beam member 400 is completed. Herein, "upper", "lower", "left", "right", "front", "rear", and the like are described with reference to the directions indicated by the double-headed arrows in fig. 3.

As shown in fig. 1 and 3, a first insertion port 301 and a second insertion port 302 are formed in the column member 300 to be installed along the front-back direction, and the first insertion port 301 and the second insertion port 302 are arranged at an interval along the up-down direction. The utility model discloses beam column node installation component includes: the upper flange mounting plate 101 penetrates through the first insertion port 301 and protrudes out of the column member 300, and the lower flange mounting plate 102 penetrates through the second insertion port 302 and protrudes out of the column member 300. The beam member 400 to be installed is welded and fixed to the upper flange mounting plate 101 and the lower flange mounting plate 102. The utility model discloses beam column node installation component is through offering first interface 301 and second interface 302 along the fore-and-aft direction on treating erection column component 300, set up installation component including top flange mounting panel 101 and bottom flange mounting panel 102, wear to establish first interface 301 and outstanding in column component 300 with top flange mounting panel 101, wear to establish second interface 302 and outstanding in column component 300 with bottom flange mounting panel 102, make and treat installation beam component 400 and top flange mounting panel 101, bottom flange mounting panel 102 welded fastening, current node connected mode has been changed, through the weak axle node of back installation bracket formation, when guaranteeing node safe and reliable, simplify PEC combination column's construction of going out of the field, the production efficiency is improved, the production cycle is practiced thrift, the component is conveniently deposited and is transported simultaneously. As shown in fig. 2, since the weak axis joints are eliminated, the column member 300 is not provided with brackets on all sides, so that a plurality of column members 300 can be horizontally stacked, which obviously effectively simplifies the storage and transportation of the column members 300. Typically, the dimensions of upper flange mounting plate 101 are slightly smaller than the dimensions of first socket 301 and the dimensions of lower flange mounting plate 102 are slightly smaller than the dimensions of second socket 302.

In some embodiments, the front-to-back length of the lower flange mounting plate 102 of the beam-column node mounting assembly of the present invention is greater than the front-to-back length of the upper flange mounting plate 101, so that the front-to-back length of the portion of the column member 300 protruding from the lower flange mounting plate 102 is greater than the front-to-back length of the portion of the column member 300 protruding from the upper flange mounting plate 101. The placement of the beam member 400 during installation is facilitated by making the front-to-rear length of the lower flange mounting plate 102 greater than the front-to-rear length of the upper flange mounting plate 101.

As shown in fig. 3 to 5, the column member 300 is provided with a column stiffening plate 304 between the first socket 301 and the second socket 302 on the surface facing the beam member 400, and the column stiffening plate 304 is fixed to the upper flange mounting plate 101 and the lower flange mounting plate 102 by fillet welding; the beam member 400 is welded to the column stiffener plate 304. The column stiffening plate 304 is disposed at the weak axis node of the column member 300, and the beam member 400 is welded and fixed to the column stiffening plate 304, so that the beam member 400 and the column member 300 can be further stably fixed.

As shown in fig. 5 and 8, the girder member 400 includes an upper flange plate 401, a lower flange plate 402, and a web 403, the upper flange plate 401 and the lower flange plate 402 are spaced apart from each other in parallel, and upper and lower ends of the web 403 are fixed to the upper flange plate 401 and the lower flange plate 402, respectively. In fig. 5, an upper flange plate 401 of a beam member 400 is welded and fixed to an upper flange mounting plate 101, a lower flange plate 402 is welded and fixed to a lower flange mounting plate 102, and a web 403 is welded and fixed to a column stiffener 304.

The structure of the beam-column node mounting assembly of the present embodiment may be different considering that the column member 300 may be fixedly installed with the beam member 400 at the front side and/or the rear side thereof. In the embodiment of the mounting assembly shown in fig. 1 and 6, i.e., including the upper flange mounting plate 101 and the lower flange mounting plate 102 separated from each other, it is possible to use for mounting and fixing the column member 300 to the beam member 400 at the front or rear side thereof, and also to use for mounting and fixing the column member 300 to the beam member 400 at both the front and rear sides thereof, particularly the latter. While the other embodiments of the mounting assembly shown in fig. 4 and 7, which include upper and lower flange mounting plates 101 and 102 interconnected by vertical mounting plate 103, may be used only for mounting and securing the column member 300 to the beam member 400 at the front or rear side thereof, in the figures for mounting and securing the column member 300 to the beam member 400 at the front side thereof.

As shown in fig. 4, the utility model discloses beam column node installation component still includes: and a vertical mounting plate 103, the vertical mounting plate 103 being parallel to the front and rear surfaces of the column member 300 and being interposed between the upper flange mounting plate 101 and the lower flange mounting plate 102. Typically, vertical mounting plates 103 are formed at the ends of upper flange mounting plate 101 and lower flange mounting plate 102 such that upper flange mounting plate 101, vertical mounting plate 103, lower flange mounting plate 102 form a U-shaped stiffener 104 that opens forward in longitudinal cross-section. The U-shaped stiffener 104 is preferably an integrally formed piece to further enhance the efficiency of installation of the mounting assembly.

The pillar member 300 is further provided with a plurality of pillar mounting holes 303 along the front-rear direction, and the plurality of pillar mounting holes 303 are provided in the region between the first socket 301 and the second socket 302, as shown in fig. 3. It will be appreciated that when the post element 300 is provided with post stiffener plates 304, the post stiffener plates 304 are also provided with post mounting holes 303.

Referring to fig. 4 and 5, a plurality of first mounting holes 130 are formed in the vertical mounting plate 103 along the front-rear direction corresponding to the plurality of column mounting holes 303, and the fixing member 200 is inserted through the column mounting holes 303 and the first mounting holes 130. The plurality of first mounting holes 130 are formed in the vertical mounting plate 103, so that the U-shaped stiffener 104 can be further stably fixed to the column member 300, and the mounting stability of the lifting beam member 400 and the column member 300 is also facilitated. The fixing member 200 may be a bolt.

Comparing fig. 5 and 8, in fig. 5, the rear end of the web 403 of the beam member 400 exceeds the rear ends of the upper flange plate 401 and the lower flange plate 402 of the beam member 400, at this time, the portion of the web 403 beyond the rear end can be directly clamped between the upper flange mounting plate 101 and the lower flange mounting plate 102, and then the butt joints are respectively welded to complete the installation of the beam member 400; in fig. 8, the rear ends of the webs 403 of the beam member 400 are substantially flush with the rear ends of the upper flange plate 401 and the lower flange plate 402, so that the beam member 400 cannot be effectively welded to the upper flange mounting plate 101 and the lower flange mounting plate 102, and a T-shaped connecting member 105 and a flat plate connecting member 500 may be additionally provided to ensure stable and rapid installation of the beam member 400.

As shown in fig. 6-8, in some embodiments, a beam-column node mounting assembly of an embodiment of the present invention further includes: t-shaped connector 105, T-shaped connector 105 has a first vertical connecting plate 151 and a second vertical connecting plate 152, the first vertical connecting plate 151 being parallel to the front and rear surfaces of the post 300, the second vertical connecting plate 152 extending away from the post 300 from the side of the first vertical connecting plate 151 remote from the post 300.

Referring to fig. 7, the first vertical connecting plate 151 of the t-shaped connecting member 105 is clamped between the portions of the upper flange mounting plate 101 and the lower flange mounting plate 102 protruding from the column member 300, a plurality of second mounting holes 501 are formed in the first vertical connecting plate 151 along the front-rear direction corresponding to the plurality of column mounting holes 303, and the fixing member 200 is inserted through the column mounting holes 303 and the second mounting holes 501. By forming the plurality of second mounting holes 501 in the first vertical connecting plate 151 of the T-shaped connector 105, a stable connection between the T-shaped connector 105 and the pillar member 300 can be ensured. The fixing member 200 may be a bolt.

Referring to fig. 8, a region of the web 403 near the pillar member 300 is opened with a plurality of beam mounting holes 404 in the left-right direction. A plurality of third mounting holes 502 are formed in the second vertical connecting plate 152 along the left-right direction corresponding to the plurality of beam mounting holes 404. The mounting assembly further includes: in the plate connection member 500, a plurality of fourth mounting holes (not shown in the drawings) are formed in the plate connection member 500 along the left-right direction corresponding to the plurality of beam mounting holes 404, and a plurality of fifth mounting holes (not shown in the drawings) are formed in the plate connection member 500 along the left-right direction corresponding to the plurality of third mounting holes 502, and the fixing member 200 is respectively inserted into the fourth mounting holes and the beam mounting holes 404, and the fifth mounting holes and the third mounting holes 502. The web 403 is provided with a plurality of beam mounting holes 404, the second vertical connecting plate 152 of the T-shaped connecting member 105 is provided with a plurality of third mounting holes 502, the flat plate connecting member 500 is provided with a plurality of fourth mounting holes and a plurality of fifth mounting holes, and the flat plate connecting member 500 is used for connecting the T-shaped connecting member 105 and the web 403 respectively, so that the stable connection between the T-shaped connecting member 105 and the beam member 400 can be ensured. The fixing member 200 may be a bolt.

In a preferred embodiment, two columns of column mounting holes 303 are formed in the column member 300 at intervals in the left-right direction; the projection of the second vertical connecting plate 152 on the vertical plane is located between the two columns of post mounting holes 303. By arranging the projection of the second vertical connecting plate 152 to be between two columns of the column mounting holes 303, the auxiliary beam member 400 can be accurately aligned while providing a connecting function.

As shown in fig. 9, the structure of the post member 300 (including the post stiffener 304), the U-shaped stiffener 104, the T-shaped connector 105, the beam member 400, and the plate connector 500 is schematically illustrated after the installation. The upper flange mounting plate 101 of the U-shaped stiffener 104 passes through the first socket 301 and beyond the column stiffener 304 and the lower flange mounting plate 102 passes through the second socket 302 and beyond the column stiffener 304. The T-shaped connecting member 105 is clamped between the excess portions of the upper flange mounting plate 101 and the lower flange mounting plate 102, the first vertical connecting plate 151 abuts against the column stiffening plate 304, and the T-shaped connecting member 105, the column member 300, and the U-shaped stiffening member 104 are fixed by respectively inserting a plurality of bolts through the corresponding second mounting holes 501, the corresponding column mounting holes 303, and the corresponding first mounting holes 130. Thereafter, the upper flange plate 401 of the girder member 400 is aligned and welded with the upper flange mounting plate 101, the lower flange plate 402 is aligned with the lower flange mounting plate 102 and welded, and the web 403 is aligned with the second vertical connection plate 152 of the T-shaped connection member 105. Finally, the flat plate connector 500 covers the end region of the web 403 and the end region of the second vertical connecting plate 152 of the T-shaped connector 105, and a plurality of bolts are respectively inserted into the fourth mounting hole and the beam mounting hole 404, and the fifth mounting hole and the third mounting hole 502, so as to complete the mounting of the beam member 400. It is understood that the web 403 and the second vertical connecting plate 152 of the T-shaped connecting member 105 can be welded together.

Thus, it should be appreciated by those skilled in the art that while a number of exemplary embodiments of the invention have been shown and described in detail herein, many other variations and modifications can be made to the invention consistent with the principles of the invention, which may be directly determined or derived from the disclosure of the present invention, without departing from the spirit and scope of the invention. Accordingly, the scope of the present invention should be understood and interpreted to cover all such other variations or modifications.

Claims (10)

1. A beam column node installation component is characterized in that,

the column component to be installed is provided with a first inserting port and a second inserting port along the front-back direction, and the first inserting port and the second inserting port are arranged at intervals along the up-down direction;

the mounting assembly includes: the upper flange mounting plate penetrates through the first inserting port and protrudes out of the column member, and the lower flange mounting plate penetrates through the second inserting port and protrudes out of the column member;

and the beam component to be installed is fixedly welded with the upper flange installation plate and the lower flange installation plate.

2. The mounting assembly of claim 1,

the front-back length of the lower flange mounting plate is greater than the front-back length of the upper flange mounting plate, so that the front-back length of the part of the column member protruding from the lower flange mounting plate is greater than the front-back length of the part of the column member protruding from the upper flange mounting plate.

3. The mounting assembly of claim 1,

a column stiffening plate is arranged on the surface of the column component, which faces the beam component, between the first inserting port and the second inserting port, and the column stiffening plate is welded and fixed with the upper flange mounting plate and the lower flange mounting plate through corner welds;

and the beam member is welded and fixed with the column stiffening plate.

4. The mounting assembly of claim 1,

the mounting assembly further comprises: the vertical mounting plate, the vertical mounting plate is on a parallel with surface and press from both sides and locate around the post component the upper flange mounting panel with between the lower flange mounting panel.

5. The mounting assembly of claim 4,

the vertical mounting panel is formed in the end of upper flange mounting panel with the bottom flange mounting panel makes the upper flange mounting panel vertical mounting panel the bottom flange mounting panel forms the U type stiffening member that the longitudinal section is the opening forward.

6. The mounting assembly of claim 5,

the U-shaped stiffening member is an integrally formed part.

7. The mounting assembly of claim 5,

the column component is also provided with a plurality of column mounting holes along the front-back direction, and the column mounting holes are formed in the area between the first inserting port and the second inserting port;

a plurality of first mounting holes along the front-back direction are formed in the vertical mounting plate corresponding to the plurality of column mounting holes, and the fixing piece penetrates through the column mounting holes and the first mounting holes.

8. The mounting assembly of claim 1,

the mounting assembly further comprises: a T-shaped connector having a first vertical connecting plate parallel to the front and rear surfaces of the post member and a second vertical connecting plate extending away from the post member from a side of the first vertical connecting plate remote from the post member;

the column component is also provided with a plurality of column mounting holes along the front-back direction, and the column mounting holes are arranged in the area between the first insertion port and the second insertion port;

the first vertical connecting plate is clamped between the parts, protruding out of the column members, of the upper flange mounting plate and the lower flange mounting plate, a plurality of second mounting holes are formed in the first vertical connecting plate corresponding to the column mounting holes in the front-back direction, and the fixing piece penetrates through the column mounting holes and the second mounting holes.

9. The mounting assembly of claim 8,

the beam component comprises an upper flange plate, a lower flange plate and a web plate, the upper flange plate and the lower flange plate are arranged in parallel at intervals, the upper end and the lower end of the web plate are respectively fixed with the upper flange plate and the lower flange plate, and a plurality of beam mounting holes along the left-right direction are formed in the area, close to the column component, of the web plate;

a plurality of third mounting holes are formed in the second vertical connecting plate along the left-right direction corresponding to the plurality of beam mounting holes;

the mounting assembly further comprises: the flat plate connecting piece corresponds on the flat plate connecting piece a plurality of fourth mounting holes along the left and right direction are seted up to a plurality of roof beam mounting holes and correspond a plurality of fifth mounting holes along the left and right direction are seted up to a plurality of third mounting holes, and the mounting is worn to establish respectively the fourth mounting hole with roof beam mounting hole and fifth mounting hole with the third mounting hole.

10. The mounting assembly of claim 8,

the column component is provided with two columns of column mounting holes which are arranged at intervals along the left-right direction;

the projection of the second vertical connecting plate on the vertical surface is positioned between the two columns of the column mounting holes.

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