CN118187268A - Assembled building longitudinal and transverse beam connecting part - Google Patents

Abstract

The invention discloses an assembled building longitudinal and transverse beam connecting part, which relates to the technical field of longitudinal and transverse beam connecting parts, and comprises longitudinal beams, beam sleeves, transverse beams and longitudinal beam connecting parts, and further comprises: the outer frame is fixedly arranged outside the beam sleeve, the outer frame is movably connected with a mounting seat, the mounting seat is provided with a first position and a second position, the mounting seat is positioned at the upper part of the outer frame in the first position, the mounting seat inclines towards the center of the longitudinal beam, and the mounting seat is embedded into the lower part of the outer frame in the second position; the functional rod supports the mounting seat when in the first position; the invention relates to a lifting device of a beam, which comprises an elliptical shaft, wherein the elliptical shaft is rotationally connected in a mounting seat.

Description

Assembled building longitudinal and transverse beam connecting part

Technical Field

The invention relates to the technical field of longitudinal and transverse beam connecting pieces, in particular to an assembled building longitudinal and transverse beam connecting piece.

Background

The frame of prefabricated building mainly comprises longeron, crossbeam, superimposed sheet, and the longeron is used for supporting in vertical direction, and the crossbeam generally level sets up, connects through the connecting piece between crossbeam and the longeron, and superimposed sheet lays on the frame that longeron, crossbeam put up.

At present, the steps of building are to build a plurality of longitudinal beams firstly, and to lift the cross beam to assemble the longitudinal beams by a crane, but when the cross beam is hung in the air, the moving track of the cross beam is not easy to control, and the cross beam needs to consume a long time to adjust when assembled between two longitudinal beams, so that the cross beam can be smoothly embedded into a connecting piece, and therefore, the cross beam is disclosed as follows: CN116575574A is a connecting component assembled in a steel structure house building, which is characterized in that a reversible clamping seat is arranged on a longitudinal beam, a cross beam is obliquely hoisted during hoisting, one lower end of the cross beam is embedded into the clamping seat, then the cross beam is gradually released, the lower end of the cross beam is unchanged in height after being supported by the clamping seat, the higher end of the cross beam continuously descends, the cross beam is finally placed into a horizontal state, the other end of the cross beam can be smoothly clamped into the clamping seat arranged on an adjacent longitudinal beam, the assembly difficulty of the cross beam is reduced, the stability of a hoisted object in the air can be best ensured by the well-known horizontal hoisting, in the above patent, although the assembly efficiency is improved, the cross beam is hoisted and conveyed in an oblique hoisting mode, even if corresponding bundling treatment is performed, the oblique hoisting cannot be avoided, the dangerous coefficient is large, and the slipping phenomenon is easy to occur.

Disclosure of Invention

The invention aims to provide an assembled building longitudinal and transverse beam connecting component which solves the defects in the prior art.

In order to achieve the above object, the present invention provides the following technical solutions: the utility model provides an assembled building longitudinal and transverse beam connecting piece, includes longeron, beam sleeve, crossbeam and longeron connecting piece, still includes:

The outer frame is fixedly arranged outside the beam sleeve, the outer frame is movably connected with a mounting seat, the mounting seat is provided with a first position and a second position, the mounting seat is positioned at the upper part of the outer frame in the first position, the mounting seat inclines towards the center of the longitudinal beam, and the mounting seat 6 is embedded into the lower part of the outer frame 201 in the second position;

The functional rod supports the mounting seat when in a first position;

The elliptical shaft is rotationally connected in the mounting seat;

In the stroke of switching the mounting seat from the first position to the second position, the cross beam extrudes the mounting seat, the mounting seat is turned to be in a vertical state and is downwards displaced to be embedded into the lower part of the outer frame, and the functional rod forces the elliptical shaft to passively rotate by 90 degrees to extrude the end part of the cross beam.

Preferably, the longitudinal beam connecting piece comprises an embedded bolt, a connecting seat and an embedded fin, wherein the embedded bolt is embedded in the upper portion of the longitudinal beam, the embedded fin is embedded in the lower portion of the longitudinal beam, the connecting seat is arranged on the lower portion of the embedded fin, and the embedded bolt penetrates through the connecting seat and is locked when the longitudinal beam is assembled.

Preferably, in the first position, the upper portion of the mounting seat is located above the embedded bolt.

Preferably, the functional rod is fixedly arranged at the lower part of the outer frame, the mounting seat is provided with a yielding hole, and the elliptical shaft is provided with a jacking groove.

Preferably, the abdication hole penetrates to the lower part of the mounting seat, and in the second position, the functional rod is inserted into the abdication hole.

Preferably, the functional lever is located on the downward movement path of the jacking groove.

Preferably, an endpoint L and an endpoint W are arranged on the elliptical axis, the size of the endpoint L from the center of a circle is larger than that of the endpoint W from the center of a circle, and the endpoint L protrudes to the outside of the mounting seat at the second position.

Preferably, a triangular block is arranged at the lower part of the outer frame, and in the second position, the triangular block is abutted against the lower part of the mounting seat.

Preferably, the outer frame is provided with a sliding groove, the lower part of the mounting seat is provided with a rotating shaft, and the rotating shaft is slidably connected in the sliding groove.

Preferably, the clamping assembly further comprises clamping plates and tension bolts, the clamping plates are respectively clamped on two sides of the longitudinal beam, the upper parts of the clamping plates are abutted against the beam sleeve, and the tension bolts penetrate through the clamping plates at the same time.

In the technical scheme, the mounting seat is obliquely arranged at the upper part of the longitudinal beam, and the mounting seat is used for guiding the transverse beam when the transverse beam is mounted, so that the transverse beam can be rapidly mounted, and when the mounting seat moves downwards, the elliptic shaft passively turns over by 90 degrees, and the turned elliptic shaft can be abutted against the end part of the transverse beam to compress the transverse beam, so that the stability of the transverse beam is improved.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings required for the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments described in the present application, and other drawings may be obtained according to these drawings for a person having ordinary skill in the art.

FIG. 1 is a schematic diagram of an assembled longitudinal beam and transverse beam of an assembled building longitudinal and transverse beam connecting component;

FIG. 2 is a schematic view of the overall structure of a mounting base of a cross beam connecting member of an assembled building in a first position;

FIG. 3 is a schematic view of the structure of the assembled building longitudinal and transverse beam connecting component of the invention after the mounting seat is turned over;

FIG. 4 is an enlarged schematic view of the structure of the cross beam connecting member of the fabricated building of the present invention at A in FIG. 3;

FIG. 5 is a schematic view of the overall structure of the mounting base of the cross beam connecting member of the fabricated building in a second position;

FIG. 6 is an enlarged schematic view of the structure of the cross beam connecting member of the fabricated building of the present invention at B in FIG. 5;

FIG. 7 is a schematic view of a pair of side members of an assembled building cross beam connecting member of the present invention after splicing;

FIG. 8 is an enlarged schematic view of the structure of the cross beam connecting member of the fabricated building of the present invention at C in FIG. 7;

FIG. 9 is a schematic illustration of a stringer attachment of an assembled building longitudinal and lateral beam attachment member of the present invention;

FIG. 10 is a schematic view of the structure of the mounting base of the cross beam connecting member of the fabricated building in a downstroke;

FIG. 11 is a schematic view of the structure of the functional rod and oval roller of the assembled building longitudinal and transverse beam connecting member of the present invention with the mounting base in the second position;

FIG. 12 is a schematic view of the structure of the function lever and the yielding hole of the mounting base of the connecting member for the longitudinal and transverse beams of the fabricated building in the first position;

FIG. 13 is a schematic view of the assembled cross beam and mounting base assembly of the cross beam connecting component of the fabricated building;

fig. 14 is a schematic view of a beam sleeve structure of an assembled building longitudinal and transverse beam connecting member according to the present invention.

Reference numerals illustrate:

1.A longitudinal beam; 2. a beam sleeve; 201. an outer frame; 202. a chute; 3. a clamping plate; 4. tensioning a bolt; 6. a mounting base; 61. a rotating shaft; 7. an elliptical axis; 8. a function lever; 81. a relief hole; 82. a jacking groove; 9. triangular blocks; 10. a cross beam; 12. embedding bolts; 14. a connecting seat; 141. embedding fins; 21. avoiding chamfering; 22. and (3) moving the plate.

Detailed Description

In order to make the technical scheme of the present invention better understood by those skilled in the art, the present invention will be further described in detail with reference to the accompanying drawings.

Referring to fig. 1 to 14, an embodiment of the present invention provides an assembled building longitudinal and transverse beam connecting component, which includes a longitudinal beam 1, a beam sleeve 2, a cross beam 10 and a longitudinal beam connecting piece, and further includes:

The outer frame 201 is fixedly arranged outside the beam sleeve 2, the outer frame 201 is movably connected with the mounting seat 6, the mounting seat 6 is provided with a first position and a second position, the mounting seat 6 is positioned at the upper part of the outer frame 201, the mounting seat 6 inclines towards the center of the longitudinal beam 1, and the mounting seat 6 is embedded into the lower part of the outer frame 201 in the second position;

A function lever 8, the function lever 8 supporting the mount 6 in the first position;

The elliptical shaft 7 is rotatably connected in the mounting seat 6;

wherein, during the assembly, the crossbeam 10 extrudes the mount pad 6, and the mount pad 6 is turned over to vertical state and embedded in frame 201 lower part after the downward displacement, and simultaneously, the function pole 8 forces oval axle 7 to passively rotate 90 degrees in order to extrude the tip of crossbeam 10.

The longitudinal beams 1 are arranged along the vertical direction, the two longitudinal beams 1 are required to be spliced through longitudinal beam connecting pieces, the beam sleeve 2 is fixedly sleeved on the upper parts of the longitudinal beams 1, the outer side face of the beam sleeve 2 is provided with an outer frame 201, the outer frame 201 is at least provided with a pair of outer frames 201 and the beam sleeve 2 are fixedly connected, the mounting seat 6 can displace on the beam sleeve 2, before the transverse beam 10 is spliced, the mounting seat 6 is positioned at a first position, please refer to fig. 2, at the moment, the mounting seat 6 is positioned on the upper part of the outer frame 201, the front mounting seat 6 inclines towards the central position of the longitudinal beam 1, thus, when the transverse beam 10 is hoisted, the mounting seat 6 can form an inclined gradient, the transverse beam 10 is guided by the mounting seat 6, the transverse beam 10 moves towards the position between a pair of longitudinal beams 1 in the gradual falling process, the shape of the mounting seat 6 is L-shaped, when the transverse beam 10 is extruded to the lower part of the mounting seat 6, the angle of the mounting seat 6 can be overturned under the extrusion action, and the mounting seat 6 can be overturned as shown in figure 3, at the moment, the lower part of the mounting seat 6 is propped against the lower part of the cross beam 10, the upper part of the mounting seat 6 is propped against the end part of the cross beam 10, under the guide action of the mounting seat 6, the cross beam 10 can be smoothly embedded between the two longitudinal beams 1, the gap between the cross beam 10 and the longitudinal beams 1 and the length adaptation degree of the cross beam 10 are better because the mounting seat 6 positioned at the two ends are synchronously overturned, the mounting error is reduced, the mounting seat 6 can be lowered to the lower part of the outer frame 201 along with the continuous lowering of the cross beam 10, the functional rod 8 can be inserted into the mounting seat 6 in the process of lowering the mounting seat 6, the elliptical shaft 7 is rotationally connected with the mounting seat 6, the functional rod 8 can drive the elliptical shaft 7 to rotate by 90 degrees in the passive rotation of the elliptical shaft 7, the long axis of the elliptical shaft 7 is overturned from the inside the mounting seat 6, the elliptical shaft 7 protrudes out of the mounting seat 6, and the elliptical shaft 7 is abutted against the end part of the cross beam 10 and the outside of the beam sleeve 2, so that horizontal pressure is generated on the cross beam 10 and can react on the longitudinal beam 1, thus ensuring that the connection between the beam sleeve 2 and the longitudinal beam 1 is tighter, and improving the bearing capacity of the beam sleeve 2.

Referring to fig. 7 and 9, the stringer connecting member includes an embedded bolt 12, a connecting seat 14 and an embedded fin 141, the embedded bolt 12 is embedded in the upper portion of the stringer 1, the embedded fin 141 is embedded in the lower portion of the stringer 1, the connecting seat 14 is installed in the lower portion of the embedded fin 141, and when a pair of stringers 1 are assembled, the embedded bolt 12 penetrates through the connecting seat 14 and is locked.

Through setting up embedded bolt 12 in the one end of longeron 1, the screw thread end of embedded bolt 12 extends to the outside of longeron 1, sets up embedded fin 141 at the other end of longeron 1, and the tip fixed mounting connecting seat 14 of embedded fin 141 when vertical assembly is carried out to a pair of longeron 1, and connecting seat 14 cup joints the tip at embedded bolt 12 to through tightening the nut, make fixed mounting be in the same place between embedded bolt 12 and the connecting seat 14.

In the first position, the upper portion of the mounting block 6 is above the embedded bolts 12. As shown in fig. 13, the cross beam 10 is lifted by using lifting equipment and gradually moves between two longitudinal beams 1, the cross beam 10 contacts the mounting seat 6, the mounting seat 6 guides the cross beam 10, the upper part of the mounting seat 6 is positioned above the embedded bolt 12, the embedded bolt 12 is protected, the weight of the cross beam 10 is large, uncontrollable factors are more in the descending process, once collision with the embedded bolt 12 occurs in the descending process, the embedded bolt 12 is inevitably damaged, the subsequent assembly of the longitudinal beam 1 is affected, the cross beam 10 can be guided when the mounting seat 6 is positioned at the first position, the protection effect is achieved, the cross beam 10 is prevented from colliding with the embedded bolt 12 in the lifting moving process, and the embedded bolt 12 is protected.

In another embodiment of the present invention, the functional rod 8 is fixedly installed at the lower part of the outer frame 201, the mounting seat 6 is provided with a yielding hole 81, and the elliptical shaft 7 is provided with a jacking groove 82.

The relief hole 81 penetrates to the lower portion of the mount 6, and in the second position, the function lever 8 is inserted into the relief hole 81.

The function lever 8 is in the downward path of the lifting groove 82.

Referring to fig. 12, when the mounting seat 6 is in the first position, the mounting seat 6 is in a state of inclining toward the center of the longitudinal beam 1, the lower portion of the functional rod 8 is fixedly mounted on the outer frame 201, the mounting seat 6 is provided with the yielding hole 81, when the mounting seat 6 is in the inclined state in the first position, the yielding hole 81 and the functional rod 8 are not located on the same central line, so that the functional rod 8 can abut against the lower portion of the mounting seat 6, the mounting seat 6 cannot smoothly fall down, further the mounting seat 6 can be kept at the upper portion of the outer frame 201 differently, the mounting seat 6 is suspended at the upper portion of the outer frame 201, the mounting seat 6 can be kept in an inclined state without additional locking, so that the guide of the cross beam 10 can be smoothly performed, the jacking groove 82 is in an offset state on the elliptical axis 7, the mounting seat 6 can be extruded to overturn when the cross beam 10 is mounted, the installation seat 6 is in a state shown in fig. 3, at this time, the upper part of the installation seat 6 is turned to be vertical, the lower part of the installation seat 6 is turned to be horizontal, the upper part of the installation seat 6 is abutted against the end part of the cross beam 10, the lower part of the installation seat 6 is abutted against the lower surface of the cross beam 10, and synchronously, after the installation seat 6 is turned over, the abdication hole 81 is located on the same central line with the functional rod 8, so that the functional rod 8 is inserted into the abdication hole 81 in the continuous descending process of the installation seat 6 of the cross beam 10, the elliptical shaft 7 is driven to move towards the lower part of the outer frame 201 together in the descending process of the installation seat 6, the functional rod 8 is abutted against the jacking groove 82 (refer to fig. 10) along with the deep abdication hole 81 of the functional rod 8, the same elliptical shaft 7 is downwards moved, under the extrusion of the functional rod 8, the elliptical shaft 7 is overturned by 90 degrees, the oval axle 7 will bulge to the outside of mount pad 6, like this, the one end extrusion of oval axle 7 is at the tip of crossbeam 10, the other end extrusion is on beam sleeve 2, through the decline of mount pad 6, the upset of 90 degrees is carried out to drive oval axle 7 when passively, make crossbeam 10 receive the pressure of a horizontal direction, the same, beam sleeve 2 also receives the reaction force of a horizontal direction, make more stable between beam sleeve 2 and the longeron 1, the vertical pressure of crossbeam 10 to mount pad 6 reduces, form a horizontal effort to mount pad 6, frictional force between beam sleeve 2 and longeron 1 increases like this, make the biggest bearing capacity of crossbeam 10 promote.

The elliptical axis 7 is provided with an end point L and an end point W, the size of the end point L from the center of a circle is larger than the size of the end point W from the center of a circle, and in the second position, the end point L protrudes to the outside of the mounting seat 6.

Referring to fig. 10, 11 and 14, the end point L is disposed on the major axis of the elliptical shaft 7, the end point W is disposed on the minor axis of the elliptical shaft 7, when the mounting seat 6 is in the downward movement process, the functional rod 8 is inserted into the yielding hole 81, the functional rod 8 forces the elliptical shaft 7 to rotate 90 degrees under the extrusion of the functional rod 8, the disposed end point L of the elliptical shaft 7 is turned over to the outside of the mounting seat 6, so that the end point L is extruded on the end of the cross beam 10, and the symmetrical other end point L is extruded on the beam sleeve 2, a horizontal thrust is applied to the beam sleeve 2, so that a tendency of displacement toward the direction of the longitudinal beam 1 is generated on one side of the beam sleeve 2, and the friction between the beam sleeve 2 and the longitudinal beam 1 is increased, thus inevitably increasing the stability between the beam sleeve 2 and the longitudinal beam 1.

In still another embodiment of the present invention, the elliptical shaft 7 is made of polyurethane rubber, and after the elliptical shaft 7 is turned over, a pressing force is generated on the cross beam 10, so that the cross beam 10 can be stably fixed in the mounting seat 6 and the outer frame 201, when an earthquake occurs, the cross beam 10 can receive a certain transverse load, the transverse load can generate shearing force, and due to the deformability of the elliptical shaft 7, the cross beam 10 has a certain variable space in the horizontal direction, and the generation of a pull-out condition between the longitudinal beam 1 and the cross beam 10 caused by the transverse load is greatly reduced.

In yet another embodiment of the present invention, the triangular block 9 is disposed at the lower portion of the outer frame 201, and in the second position, the triangular block 9 abuts against the lower portion of the mounting seat 6.

The polylith triangular block 9 neatly arranges in the lower part of frame 201, and when mount pad 6 moved to the second position, the upper surface of triangular block 9 can conflict on mount pad 6, carries out a support to mount pad 6 through triangular block 9, and the pressure that mount pad 6 received can pass through triangular block 9 to be transmitted to frame 201 like this, on transmitting to beam sleeve 2 through frame 201, promotes the bearing capacity of mount pad 6.

The outer frame 201 is provided with a chute 202, the lower part of the mounting seat 6 is provided with a rotating shaft 61, and the rotating shaft 61 is slidably connected in the chute 202. The lower part fixedly connected with pivot 61 at mount pad 6, pivot 61 sliding connection is in spout 202, carries out spacingly to pivot 61 through spout 202 for mount pad 6 can keep a tilt state when the first position, and the upper portion of beam sleeve 2 is provided with keeps away a chamfer 21, keeps away a chamfer 21 and can smoothly give way mount pad 6, makes mount pad 6 can overturn to tilt state.

Still include the centre gripping subassembly, it includes splint 3 and tie bolt 4, and a pair of splint 3 centre gripping respectively in the both sides of longeron 1, and the upper portion of splint 3 is contradicted on beam sleeve 2, and tie bolt 4 runs through a pair of splint 3 simultaneously. The clamping plate 3 can be firmly fixed on the longitudinal beam 1 under the action of the tension bolt 4 and is abutted against the beam sleeve 2 through the upper part of the clamping plate 3, so that the beam sleeve 2 can be sufficiently supported to ensure the stability of the beam sleeve 2 on the bearing cross beam 10.

In a further embodiment of the present invention, the beam sleeve 2 is movable near two sides of the cross beam 10, and the moving plates 22 are slidably connected to two sides of the beam sleeve 2, so that when the beam sleeve 2 is extruded, the moving plates 22 on two sides displace toward the longitudinal beam 1, and the friction between the beam sleeve 2 and the cross beam 10 is increased.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that modifications may be made to the described embodiments in various different ways without departing from the spirit and scope of the invention. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive of the scope of the invention, which is defined by the appended claims.

Claims (10)

1. The utility model provides an assembled building longitudinal and transverse beam connecting piece, includes longeron (1), roof beam cover (2), crossbeam (10) and longeron connecting piece, its characterized in that still includes:

The beam sleeve comprises an outer frame (201), wherein the outer frame (201) is fixedly arranged outside the beam sleeve (2), a mounting seat (6) is movably connected to the outer frame (201), the mounting seat (6) is provided with a first position and a second position, the mounting seat (6) is positioned at the upper part of the outer frame (201) in the first position, the mounting seat (6) inclines towards the center of the longitudinal beam (1), and the mounting seat (6) is embedded into the lower part of the outer frame (201) in the second position;

a functional lever (8), the functional lever (8) supporting the mount (6) in a first position;

the elliptical shaft (7), the elliptical shaft (7) is rotatably connected in the mounting seat (6);

In the process that the mounting seat (6) is switched from the first position to the second position, the cross beam (10) extrudes the mounting seat (6), the mounting seat (6) is turned to be in a vertical state and is embedded into the lower part of the outer frame (201) after being displaced downwards, and the functional rod (8) forces the elliptical shaft (7) to passively rotate by 90 degrees to extrude the end part of the cross beam (10) synchronously.

2. The longitudinal and transverse beam connecting component for the fabricated building according to claim 1, wherein the longitudinal beam connecting component comprises an embedded bolt (12), a connecting seat (14) and an embedded fin (141), the embedded bolt (12) is embedded on the upper portion of the longitudinal beam (1), the embedded fin (141) is embedded on the lower portion of the longitudinal beam (1), the connecting seat (14) is arranged on the lower portion of the embedded fin (141), and the embedded bolt (12) penetrates through the connecting seat (14) and is locked when the pair of longitudinal beams (1) are assembled.

3. A modular building longitudinal and transverse beam connection according to claim 2, characterized in that in the first position the upper part of the mounting seat (6) is above the embedded bolts (12).

4. The connecting component for the longitudinal and transverse beams of the fabricated building according to claim 1, wherein the functional rod (8) is fixedly installed at the lower part of the outer frame (201), a yielding hole (81) is formed in the installation seat (6), and a jacking groove (82) is formed in the elliptical shaft (7).

5. A modular building longitudinal and transverse beam connection according to claim 4, characterized in that the relief hole (81) extends through to the lower part of the mounting seat (6), in the second position the functional rod (8) being inserted into the relief hole (81).

6. A modular building crossbar connection according to claim 5, characterized in that the function bar (8) is in the path of the downward movement of the jacking groove (82).

7. The connecting component for the longitudinal and transverse beams of the fabricated building according to claim 1, wherein the elliptical shaft (7) is provided with an end point L and an end point W, the dimension of the end point L from the center of a circle is larger than the dimension of the end point W from the center of a circle, and in the second position, the end point L protrudes to the outside of the mounting seat (6).

8. A modular building longitudinal and transverse beam connecting member according to claim 1, characterized in that the lower part of the outer frame (201) is provided with triangular blocks (9), and in the second position the triangular blocks (9) are in abutment against the lower part of the mounting base (6).

9. The longitudinal and transverse beam connecting component for the assembled building according to claim 1, wherein the outer frame (201) is provided with a sliding groove (202), the lower part of the mounting seat (6) is provided with a rotating shaft (61), and the rotating shaft (61) is slidably connected in the sliding groove (202).

10. The assembled building longitudinal and transverse beam connecting component according to claim 1, further comprising a clamping assembly, wherein the clamping assembly comprises clamping plates (3) and tension bolts (4), the clamping plates (3) are respectively clamped on two sides of the longitudinal beam (1), the upper parts of the clamping plates (3) are abutted against the beam sleeve (2), and the tension bolts (4) penetrate through the clamping plates (3) at the same time.