CN217053747U - Assembled crossbeam connected node - Google Patents

Abstract

The utility model discloses an assembled crossbeam connected node, it is formed with one on the first connecting plate and can imbeds protruding portion in the recess district arches to first connecting plate one side the opposite side of protruding portion is formed with a depressed area that can supply to arch portion embedding, at least one mounting hole district has on the first connecting plate, have on the mainboard with the mounting hole that the mounting hole district corresponds is listed as, and every mounting hole is listed as and is arranged along perpendicular to mainboard length direction interval by a plurality of first mounting holes and forms, has seted up a plurality of in every mounting hole district and arranges for the second mounting hole of multirow, and every row at least 1 second mounting hole corresponds 1 first mounting hole, is located the crisscross setting of second mounting hole of adjacent row in the length direction of mainboard. The utility model discloses can guarantee that the crossbeam that many end to end in the house frame that the assembly formed keeps accurate collineation and does not take place the skew, improve overall structure's mechanical properties and stability.

Description

Assembled crossbeam connected node

Technical Field

The utility model relates to a building material technical field especially relates to assembled crossbeam connected node.

Background

The green building is a building capable of achieving the purposes of energy conservation and emission reduction, saves resources, protects the environment, reduces pollution, provides healthy, applicable and efficient use space for people in the whole life cycle, and realizes harmonious symbiosis between people and nature to the maximum extent.

With the innovative demand of the building market, construction and construction develop towards the directions of high efficiency, rapidness, quality and the like, and the assembly type building is a new building form, and the assembly type building refers to a building which is formed by transferring a large amount of field operation work in the traditional construction 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.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an assembly type crossbeam connected node, this assembly type crossbeam connected node can guarantee that the crossbeam that many end to end in the house frame that the assembly formed keeps accurate collineation and does not take place the skew, improves overall structure's mechanical properties and stability.

In order to achieve the above purpose, the utility model adopts the technical scheme that: an assembled beam connection node for connecting a first beam and a second beam, comprising: the first connecting plate is connected with a main plate of the first beam body, the second connecting plate is connected with the second beam body, a plurality of arch parts distributed along the length direction of the main plate are formed on the main plate, a groove area is formed on the other side of the arch part protruding to one side of the main plate, a protruding part capable of being embedded into the groove area is formed on the first connecting plate, a concave area capable of being embedded by the arch part is formed on the other side of the protruding part protruding to one side of the first connecting plate, and the first connecting plate with the arch part embedded into the concave area can move along the length direction of the main plate;

the first connecting plate is provided with at least one mounting hole area, the main board is provided with mounting hole rows corresponding to the mounting hole areas, each mounting hole row is formed by arranging a plurality of first mounting holes at intervals along the length direction of the main board, a plurality of second mounting holes which are arranged in multiple rows are arranged in each mounting hole area, at least 1 second mounting hole in each row corresponds to 1 first mounting hole, and the second mounting holes in adjacent rows are arranged in the length direction of the main board in a staggered mode.

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

1. in the above scheme, the areas on the two sides of the protruding portion and the first connecting plate are provided with at least one mounting hole area.

2. In the above scheme, any two rows of the second mounting holes are arranged in a staggered manner in the length direction of the main board.

3. In the above scheme, a plurality of the arch parts are continuously distributed along the length direction of the main board, and the adjacent arch parts are protruded towards the opposite direction.

4. In the above aspect, the protrusion is located in the middle area of the first connection plate.

5. In the above scheme, the boss is attached to the bottom surface of the groove in the groove area, and the areas of the first connecting plate on two sides of the boss are respectively attached to the main plate surface.

6. In the above scheme, the arching portion is attached to the bottom surface of the inner wall of the depressed area, and the areas of the main board on two sides of the arching portion are attached to the first connecting board surface.

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

the utility model discloses assembled crossbeam connected node, it has both improved the structural performance of roof beam body itself, and when realizing the quick assembly connection of roof beam body, improves the stability of connection structure through the mutual cooperation of the arch sunken between the part; further, through the cooperation of a pair of between first mounting hole and the second mounting hole, can adjust the position that the second roof beam body is connected to first roof beam body on first roof beam body length direction to guarantee all to keep the vertical state between the first roof beam body at second roof beam body and both ends, can also guarantee that many end to end's second crossbeam keeps accurate collineation and does not take place the skew in the house frame, improve overall structure's mechanical properties and stability.

Drawings

Fig. 1 is an overall structural schematic diagram of the assembled beam connecting node of the present invention;

FIG. 2 is an enlarged view of the point A of FIG. 1 according to the present invention;

FIG. 3 is a sectional perspective view of the assembled beam connection node of the present invention;

fig. 4 is a schematic structural diagram of an embodiment of a first connecting plate according to the present invention;

fig. 5 is a schematic structural diagram of another embodiment of the first connecting plate according to the present invention.

In the above drawings: 100. a first beam body; 101. a main board; 200. a second beam body; 1. a first connecting plate; 2. a second connecting plate; 3. an arching portion; 4. a groove region; 5. a boss portion; 6. a recessed region; 7. a first mounting hole; 8. and a second mounting hole.

Detailed Description

Example 1: a fabricated girder connecting node for connecting a first girder 100 and a second girder 200, comprising: the first connecting plate 1 is connected with a main plate 101 of a first beam body 100, the second connecting plate 2 is connected with a second beam body 200, a plurality of arch parts 3 distributed along the length direction of the main plate 101 are formed on the main plate 101, a groove area 4 is formed on the other side of the arch part 3 protruding to one side of the main plate 101, a convex part 5 capable of being embedded into the groove area 4 is formed on the first connecting plate 1, a concave area 6 capable of being embedded into the arch part 3 is formed on the other side of the convex part 5 arched to one side of the first connecting plate 1, and the first connecting plate 1 with the arch part 3 embedded into the convex part 5 and the first connecting plate 1 with the arch part 3 embedded into the concave area 6 can move along the length direction of the main plate 101;

the first connecting plate 1 is provided with at least one mounting hole area, the main board 101 is provided with mounting hole rows corresponding to the mounting hole areas, each mounting hole row is formed by arranging a plurality of first mounting holes 7 at intervals along the length direction of the main board 101, a plurality of second mounting holes 8 arranged in multiple rows are formed in each mounting hole area, at least 1 second mounting hole 8 in each row corresponds to 1 first mounting hole 7, and the second mounting holes 8 in adjacent rows are arranged in the length direction of the main board 101 in a staggered mode.

The area of the protruding portion 5 and the area of the first connecting plate 1 on both sides of the protruding portion 5 have at least one mounting hole area.

A plurality of the arch parts 3 are continuously distributed along the longitudinal direction of the main plate 101 and the adjacent arch parts 3 are protruded in the opposite direction.

The protrusion 5 is attached to the bottom surface of the groove 4, and the areas of the first connection plate 1 on both sides of the protrusion 5 are attached to the surface of the main plate 101.

The arch portion 3 is attached to the bottom surface of the inner wall of the depression 6, and the areas of the main plate 101 on both sides of the arch portion 3 are attached to the surface of the first connection plate 1.

Example 2: an assembled beam connecting node for connecting a first beam body 100 and a second beam body 200, comprising: a first connection plate 1 connected with a main plate 101 of a first beam 100 and a second connection plate 2 connected with a second beam 200, wherein a plurality of arch parts 3 distributed along the length direction of the main plate 101 are formed on the main plate 101, a groove area 4 is formed on the other side of the arch part 3 protruding to one side of the main plate 101, a convex part 5 capable of being embedded into the groove area 4 is formed on the first connection plate 1, a concave area 6 capable of being embedded into the arch part 3 is formed on the other side of the convex part 5 arched to one side of the first connection plate 1, and the first connection plate 1 with the convex part 5 embedded into the groove area 4 and the first connection plate 1 with the arch part 3 embedded into the concave area 6 can both move along the length direction of the main plate 101;

the first connecting plate 1 is provided with at least one mounting hole area, the main plate 101 is provided with mounting hole rows corresponding to the mounting hole areas, each mounting hole row is formed by arranging a plurality of first mounting holes 7 at intervals along the length direction perpendicular to the main plate 101, a plurality of second mounting holes 8 arranged in multiple rows are formed in each mounting hole area, at least 1 second mounting hole 8 in each row corresponds to 1 first mounting hole 7, and the second mounting holes 8 in adjacent rows are arranged in the length direction of the main plate 101 in a staggered manner.

The area of the protruding portion 5 and the area of the first connecting plate 1 on both sides of the protruding portion 5 have at least one mounting hole area.

Any two rows of the second mounting holes 8 are arranged in a staggered manner in the length direction of the main board 101.

A plurality of the arch parts 3 are continuously distributed along the longitudinal direction of the main plate 101 and the adjacent arch parts 3 are protruded in the opposite direction.

The projection 5 is located in the middle region of the first connection plate 1.

The protrusion 5 is attached to the bottom surface of the groove 4, and the areas of the first connecting plate 1 on both sides of the protrusion 5 are attached to the surface of the main plate 101.

When the assembly type cross beam is used for connecting the nodes, the structural performance of the beam body is improved, and the stability of the connecting structure is improved through the mutual matching of the bulges and the depressions among the components while the rapid assembly and connection of the beam body are realized; further, through the cooperation of a pair of between first mounting hole and the second mounting hole, can adjust the position that the second roof beam body is connected to first roof beam body on first roof beam body length direction to guarantee all to keep the vertical state between the first roof beam body at second roof beam body and both ends, can also guarantee that many end to end's second crossbeam keeps accurate collineation and does not take place the skew in the house frame, improve overall structure's mechanical properties and stability.

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 (7)

1. A fabricated cross beam connection node for connecting a first beam (100) and a second beam (200), comprising: first connecting plate (1) of being connected with mainboard (101) of first roof beam body (100) and second connecting plate (2) of being connected with second roof beam body (200), its characterized in that: the main board (101) is provided with a plurality of arched parts (3) distributed along the length direction of the main board, the other side of the arched part (3) protruding to one side of the main board (101) is provided with a groove area (4), the first connecting board (1) is provided with a convex part (5) capable of being embedded into the groove area (4), the other side of the convex part (5) arched to one side of the first connecting board (1) is provided with a concave area (6) capable of being embedded by the arched part (3), and the first connecting board (1) with the convex part (5) embedded into the groove area (4) and the first connecting board (1) with the arched part (3) embedded into the concave area (6) can move along the length direction of the main board (101);

the first connecting plate (1) is provided with at least one mounting hole area, the main board (101) is provided with mounting hole rows corresponding to the mounting hole areas, each mounting hole row is formed by arranging a plurality of first mounting holes (7) at intervals in the length direction of the main board (101), a plurality of second mounting holes (8) which are arranged in multiple rows are formed in each mounting hole area, at least 1 second mounting hole (8) in each row corresponds to 1 first mounting hole (7), and the second mounting holes (8) in adjacent rows are arranged in a staggered mode in the length direction of the main board (101).

2. The fabricated cross-beam connection node of claim 1, wherein: the area on the bulge (5) and the area of the first connecting plate (1) on two sides of the bulge (5) are provided with at least one mounting hole area.

3. The fabricated cross-beam connecting node of claim 1, wherein: any two rows of second mounting holes (8) are arranged in a staggered mode in the length direction of the main board (101).

4. The fabricated cross-beam connection node of claim 1, wherein: the plurality of the arched parts (3) are continuously distributed along the length direction of the main board (101), and the adjacent arched parts (3) are protruded towards the opposite direction.

5. The fabricated cross-beam connecting node of claim 1, wherein: the projection (5) is located in the middle region of the first connecting plate (1).

6. The fabricated cross-beam connecting node of claim 1, wherein: protruding portion (5) and the tank bottom surface laminating of recess district (4), the region that first connecting plate (1) is located protruding portion (5) both sides is laminated with mainboard (101) face separately.

7. The fabricated cross-beam connecting node of claim 1, wherein: the arched part (3) is attached to the bottom surface of the inner wall of the depressed area (6), and the areas, located on two sides of the arched part (3), of the main board (101) are attached to the surface of the first connecting plate (1).

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