CN219993232U - Beam body reinforcing structure for building - Google Patents

Abstract

The utility model relates to a beam body reinforcing structure for a building, which comprises a beam unit, a driving unit and two reinforcing units, wherein the beam unit is vertically arranged; the first end of the driving unit is connected with the beam unit; the first ends of the two reinforcing units are respectively connected with the second ends of the driving units, and the second ends of the two reinforcing units are respectively connected with the beam units and are used for supporting and reinforcing the beam units under the action of the driving units. The device has the advantages that the primary installation operation can be achieved through the matched use of the driving unit and the reinforcing unit, so that the subsequent reinforcing operation is facilitated; the reinforcing unit reinforces beam unit right angle department under drive unit's effect, has increased the bearing capacity to through corresponding regulation, the reinforcing operation of the not unidimensional roof beam body right angle department of better adaptation has improved reinforced structure's practicality.

Description

Beam body reinforcing structure for building

Technical Field

The utility model relates to the technical field related to building structures, in particular to a beam body reinforcing structure for a building.

Background

The building structure is a framework structure which is formed by building components such as plates, beams, columns, walls, foundations and the like, has a certain space function and can safely bear various normal loads of a building.

The plates are planar members in the building structure that directly bear the load, have a large planar dimension, but are relatively small in thickness, and belong to the flexural members through which the load is transferred to the beams or walls. Beams are generally linear members which bear loads perpendicular to their longitudinal axes, are support members between the plates and the columns, and are members which are subject to bending, and which bear loads from the plates and transfer them to the columns. Both the columns and the walls are load bearing members in the building structure which bear axial pressure, the columns are linear members which bear loads parallel to the longitudinal axis direction of the columns, the cross section dimension is smaller than the height, the walls mainly bear vertical members which bear loads parallel to the wall direction, the vertical members belong to compression members, the load is transmitted to a foundation, and bending moment and shearing force are born sometimes. The foundation is a structural member of the part below the ground, and transfers the upper structural load transferred from the column, the wall and the like to the foundation

The beam in the building structure is a common beam body for supporting the building, and plays a role in supporting bearing force in the building, so that the beam in the building structure needs to be reinforced to increase the bearing capacity of the beam body. The existing reinforcing structure is simple, the applicability of the reinforcing structure installed at the beam body is poor, the reinforcing structure is inconvenient to install, and the supporting effect on the building structure beam is poor.

At present, no effective solution is proposed for the problems of poor applicability and inconvenient installation of the beam body in the related art.

Disclosure of Invention

The utility model aims at overcoming the defects in the prior art, and provides a beam body reinforcing structure for construction, which aims at solving the problems of poor applicability and inconvenient installation at a beam body in the related art.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

a beam body reinforcing structure for construction, comprising:

the beam unit is vertically arranged;

the first end of the driving unit is connected with the beam unit;

the first ends of the two reinforcing units are respectively connected with the second ends of the driving units, and the second ends of the two reinforcing units are respectively connected with the beam units and are used for supporting and reinforcing the beam units under the action of the driving units.

In some of these embodiments, the beam unit comprises:

a first beam element disposed vertically, the first beam element being connected to a first end of the drive unit;

and the second beam element is perpendicular to the first beam element and is connected with the first end of the driving unit.

In some of these embodiments, the driving unit includes:

a first support element, a first end of which is connected to the beam unit;

the first end of the first rotating element is rotationally connected with the second end of the first supporting element;

the driving element is connected with the second end of the first rotating element and is used for driving the first rotating element to rotate;

the first movable element is rotationally connected with the first rotating element and is used for reciprocating along the axial direction of the first rotating element under the action of the driving element.

In some of these embodiments, the drive unit further comprises:

and the second rotating element is arranged at the end part of the first movable element and is rotationally connected with the reinforcing unit.

In some of these embodiments, the drive unit further comprises:

the first sliding element is connected with the second end of the first supporting element at the first end and is positioned at the side end of the first rotating element, and the first sliding element is connected with the first movable element in a sliding way.

In some of these embodiments, the drive unit further comprises:

and the limiting element is arranged at the second end of the first sliding element and used for preventing the first movable element from being separated.

In some of these embodiments, the reinforcement unit includes:

a second support member, a first end of which is connected to the beam unit;

a second sliding element disposed at a second end of the second support element;

a third sliding element slidably coupled to the second sliding element;

and the first end of the second movable element is connected with the third sliding element, and the second end of the second movable element is connected with the driving unit.

In some of these embodiments, the reinforcement unit further comprises:

and the third rotating element is arranged at the second end of the second movable element and is rotationally connected with the driving unit.

In some of these embodiments, the reinforcement unit further comprises:

the fourth rotating element is arranged at the first end of the second movable element;

a third support element, a first end of which is connected to the third slide element;

and the fifth rotating element is arranged at the second end of the third supporting element and is in rotating connection with the fourth rotating element.

In some of these embodiments, the reinforcement unit further comprises:

and the first end of the moving element is connected with the third sliding element, and the second end of the moving element is connected with the third supporting element.

Compared with the prior art, the utility model has the following technical effects:

according to the beam body reinforcing structure for the building, the driving unit and the reinforcing unit are matched for use, so that preliminary installation operation can be achieved, and subsequent reinforcing operation is facilitated; the reinforcing unit reinforces beam unit right angle department under drive unit's effect, has increased the bearing capacity to through corresponding regulation, the reinforcing operation of the not unidimensional roof beam body right angle department of better adaptation has improved reinforced structure's practicality, has satisfied current user demand.

Drawings

FIG. 1 is a schematic perspective view of a reinforcing structure according to an embodiment of the present utility model;

fig. 2 is a schematic perspective view of a beam unit according to an embodiment of the present utility model;

fig. 3 is a schematic perspective view of a driving unit according to an embodiment of the present utility model;

fig. 4 is a schematic perspective view of a reinforcement unit according to an embodiment of the present utility model;

fig. 5 is an exploded view of a reinforcement unit according to an embodiment of the present utility model;

wherein the reference numerals are as follows: 100. a beam unit; 101. a first beam member; 102. a second beam member;

200. a driving unit; 201. a first support element; 202. a first rotating element; 203. a driving element; 204. a first movable element; 205. a second rotating element; 206. a first sliding element; 207. a limiting element;

300. a reinforcement unit; 301. a second support element; 302. a second sliding element; 303. a third sliding element; 304. a second movable element; 305. a third rotating element; 306. a fourth rotating element; 307. a third support element; 308. a fifth rotating element; 309. and a moving element.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be noted that, without conflict, the embodiments of the present utility model and features of the embodiments may be combined with each other.

The utility model is further described below with reference to the drawings and specific examples, which are not intended to be limiting.

An exemplary embodiment of the present utility model, as shown in fig. 1, a girder reinforcing structure for construction, includes a girder unit 100, a driving unit 200, and two reinforcing units 300. Wherein the beam unit 100 is vertically disposed; the first end of the driving unit 200 is connected to the beam unit 100; the first ends of the two reinforcement units 300 are respectively connected with the second ends of the driving units 200, and the second ends of the two reinforcement units 300 are respectively connected with the beam units 100 for supporting and reinforcing the beam units 100 under the action of the driving units 200.

Specifically, the reinforcement unit 300 is driven by the driving unit 200 to reinforcement and support the beam unit 100.

As shown in fig. 2, the beam unit 100 includes a first beam member 101 and a second beam member 102. Wherein the first beam element 101 is arranged vertically, the first beam element 101 being connected to a first end of the drive unit 200; the second beam member 102 is disposed perpendicular to the first beam member 101, and the second beam member 102 is connected to a first end of the driving unit 200.

The inner side of the first end of the first beam element 101 is connected to the first end of the drive unit 200.

The first beam element 101 is a rectangular column.

In some of these embodiments, the first beam member 101 is made of steel.

In some of these embodiments, the first beam element 101 is a vertical beam.

The bottom end surface of the first end of the second beam member 102 is connected to the top end surface of the first end of the first beam member 101.

The bottom side of the first end of the second beam member 102 is connected to the first end of the drive unit 200.

The second beam member 102 is a rectangular column.

In some of these embodiments, the second beam member 102 is fixedly coupled to the first beam member 101, including but not limited to a bolted connection.

In some of these embodiments, the second beam member 102 is made of steel.

In some of these embodiments, the second beam member 102 is a cross beam.

As shown in fig. 3, the driving unit 200 includes a first supporting member 201, a first rotating member 202, a driving member 203, and a first movable member 204. Wherein a first end of the first support element 201 is connected with the beam unit 100; a first end of the first rotating element 202 is rotatably connected to a second end of the first supporting element 201; the driving element 203 is connected to the second end of the first rotating element 202, and is used for driving the first rotating element 202 to rotate; the first movable member 204 is rotatably connected to the first rotary member 202 for reciprocating movement in the axial direction of the first rotary member 202 under the action of the driving member 203.

Specifically, one side surface of the first support element 201 is fixedly connected to the bottom side surface of the second beam element 102, and one side surface of the first support element 201 is fixedly connected to the inner side surface of the first beam element 101.

The first support element 201 has a triangular cross section.

In some of these embodiments, the first support element 201 is fixedly coupled to the first beam element 101, the second beam element 102, including but not limited to a bolted connection.

In some of these embodiments, the first support element 201 is made of steel.

In some of these embodiments, the first support element 201 is a first mounting plate.

The first rotating element 202 has a cylindrical structure.

The first rotating element 202 and the first supporting element 201 are not separated to rotate. For example, the first rotating member 202 is connected to the first supporting member 201 by a bearing housing contact surface in a T-shaped configuration.

Specifically, the bearing housing includes a base and a bearing. The base is fixedly connected with the first supporting element 201, and the bearing is fixedly connected with the first rotating element 202 and is rotatably connected with the base.

In some embodiments, the first rotating element 202 is made of metal.

In some of these embodiments, the first rotating element 202 is a screw.

The dimensions of the driving element 203 are matched to the dimensions of the first rotating element 202. Generally, the radial dimension of the drive element 203 is greater than the radial dimension of the first rotating element 202.

In some of these embodiments, the drive element 203 is hexagonal in cross-section.

In some of these embodiments, the drive element 203 is fixedly coupled to the first rotational element 202, including but not limited to welding.

In some of these embodiments, the driving element 203 is made of a metal material.

In some of these embodiments, the drive element 203 is a nut.

The first movable element 204 has an H-shaped cross-section. Specifically, the first movable element 204 includes a cross plate, two risers, and a threaded bore. Wherein the cross plate is rotatably connected with the first rotating element 202; the two vertical plates are symmetrically arranged on two sides of the transverse plate and are respectively connected with the two reinforcing units 300; the threaded bore is threadedly coupled to the first rotational element 202.

Specifically, the two risers are disposed perpendicular to the cross plate.

In some embodiments, the first movable element 204 is made of a metal material.

In some of these embodiments, the first movable element 204 is a moving carriage.

Further, the driving unit 200 further includes a second rotating element 205. The second rotating element 205 is disposed at an end of the first movable element 204 and is rotatably connected to the reinforcement unit 300.

Specifically, the second rotating element 205 is provided at the end of the riser.

The second rotating element 205 has a circular cross section.

The second rotating element 205 is sized to match the size of the first movable element 204. Generally, the radial dimension of the second rotating element 205 is smaller than the length/height of the riser of the first mobile element 204; the length of the second rotating element 205 is smaller than the width of the riser of the first movable element 204.

In some of these embodiments, the second rotational element 205 is a first coupling slot.

Further, the drive unit 200 further comprises a first sliding element 206. The first end of the first sliding element 206 is connected to the second end of the first supporting element 201 and is located at a side end of the first rotating element 202, and the first sliding element 206 is slidably connected to the first movable element 204.

The first sliding element 206 has a cylindrical structure.

At least one of the first slide members 206. In the case that the number of the first sliding elements 206 is several, the first sliding elements 206 are symmetrically disposed at two sides of the first rotating element 202.

Generally, a first sliding element 206 is disposed on one side of the first rotating element 202, and a first sliding element 206 is disposed on the other side of the first rotating element 202.

Further, the first movable element 204 further comprises a through hole. Wherein the through hole is disposed through the cross plate and slidably coupled to the first sliding member 206.

The number of through holes matches the number of first slide elements 206. Generally, the number of through holes is equal to the number of first slide elements 206.

In some of these embodiments, the first sliding element 206 is fixedly coupled to the first support element 201, including but not limited to welding.

In some embodiments, the first sliding element 206 is made of a metal material.

In some of these embodiments, the first sliding element 206 is a sliding bar.

Further, the driving unit 200 further comprises a limiting element 207. The limiting element 207 is disposed at the second end of the first sliding element 206, for preventing the first movable element 204 from being separated.

The limiting element 207 has a cylindrical structure.

The dimensions of the stop element 207 are matched to the dimensions of the first slide element 206. Generally, the radial dimension of the stop element 207 is greater than the radial dimension of the first slide element 206.

The number of limit elements 207 matches the number of first slide elements 206. Generally, the number of stop elements 207 is equal to the number of first slide elements 206.

In some of these embodiments, the stop element 207 is fixedly coupled to the first slide element 206, including but not limited to welding.

In some embodiments, the stop element 207 is made of a metal material.

In some of these embodiments, the stop element 207 is a stop plate.

As shown in fig. 4 and 5, the reinforcement unit 300 includes a second support member 301, a second sliding member 302, a third sliding member 303, and a second movable member 304. Wherein a first end of the second support element 301 is connected to the beam unit 100; the second sliding element 302 is disposed at the second end of the second supporting element 301; the third sliding element 303 is slidingly connected to the second sliding element 302; the first end of the second movable element 304 is connected to the third sliding element 303 and the second end of the second movable element 304 is connected to the drive unit 200.

Specifically, the second end of the second movable element 304 is rotatably connected to the second rotary element 205.

The second support member 301 has a rectangular cross section.

In some of these embodiments, the second support element 301 is fixedly connected to the beam unit 100, including but not limited to a bolted connection.

In some of these embodiments, the second support element 301 is made of steel.

In some of these embodiments, the second support element 301 is a second mounting plate.

The second slide element 302 has a convex configuration in cross-section. Specifically, the second slide element 302 includes a first slide slot and a second slide slot. Wherein the first chute is disposed inside the second supporting element 301; the second chute is disposed on the lower surface of the second supporting element 301 and is in communication with the first chute.

The size of the second chute is matched with that of the first chute. Generally, the width and height of the second runner are smaller than the width and height of the first runner.

The dimensions of the second sliding element 302 match those of the second supporting element 301. Generally, the length, width and height of the second sliding element 302 are smaller than the length, width and height of the second supporting element 301.

In some of these embodiments, the second slide element 302 is a chute.

The third sliding element 303 has a convex configuration in cross section. Specifically, the third slide element 303 includes a first slider and a second slider. The first sliding block is in sliding connection with the first sliding groove; the second sliding block is fixedly connected with the first sliding block and is in sliding connection with the second sliding groove.

Specifically, the first slider is fixedly connected with the second slider, including but not limited to welding. For example, the first slider is integrally formed with the second slider.

The dimensions of the third sliding element 303 match those of the second sliding element 302. In general, the width of the third sliding element 303 is equal to the width of the second sliding element 302; the length of the third sliding element 303 is smaller than the length of the second sliding element 302; the third sliding element 303 has a height that is greater than the height of the second sliding element 302.

More specifically, the first slider is matched to the size of the first runner. Generally, the height and width of the first slider are equal to those of the first runner, and the length of the first slider is smaller than that of the first runner.

More specifically, the second slider is matched to the size of the second runner. Generally, the width of the second sliding block is equal to the width of the second sliding groove, the length of the second sliding block is smaller than that of the second sliding groove, and the height of the second sliding block is larger than that of the second sliding groove.

In some embodiments, the third sliding element 303 is made of metal.

In some of these embodiments, the third sliding element 303 is a slider.

The second movable element 304 is rectangular in cross-section.

In some embodiments, the second movable element 304 is made of a metal material.

In some of these embodiments, the second movable element 304 is a linkage.

Further, the reinforcement unit 300 further includes a third rotating member 305. The third rotating element 305 is disposed at the second end of the second movable element 304 and is rotatably connected to the driving unit 200.

Specifically, the third rotating element 305 is disposed through the second movable element 304, and the third rotating element 305 is rotatably connected to the second rotating element 205.

The third rotary element 305 has a cylindrical structure.

In some of these embodiments, the third rotational element 305 is in a non-decoupled rotational connection with the second rotational element 205. For example, the third rotating element 305 is connected to the second rotating element 205 in a T-shaped configuration via the surface that contacts the bearing housing.

Specifically, the bearing housing includes a base and a bearing. The base is fixedly connected to the second rotating element 205, and the bearing is fixedly connected to the third rotating element 305 and is rotatably connected to the base.

In some embodiments, the third rotating element 305 is made of metal.

In some of these embodiments, the third rotational element 305 is a first rotational shaft.

Further, the reinforcement unit 300 further includes a fourth rotating member 306, a third supporting member 307, and a fifth rotating member 308. The fourth rotating element 306 is disposed at the first end of the second movable element 304; a first end of the third support element 307 is connected to the third sliding element 303; the fifth rotating element 308 is disposed at the second end of the third supporting element 307 and is rotatably connected to the fourth rotating element 306.

Specifically, the fourth rotating element 306 is disposed on an end surface of the first end of the second movable element 304.

The fourth rotating element 306 has a cylindrical structure.

In some embodiments, the fourth rotating element 306 is made of metal.

In some embodiments, the fourth rotating element 306 is a second rotating shaft.

The third support element 307 has a U-shaped cross section. Specifically, the third support element 307 comprises a base plate and two support plates. Wherein the bottom plate is fixedly connected with the two support plates; the two support plates are symmetrically arranged on the lower surface of the bottom plate.

In some of these embodiments, the third support element 307 is made of a metal material.

In some of these embodiments, the third support element 307 is a support frame.

The fifth rotating element 308 has a circular cross-section.

In some of these embodiments, the fourth rotating element 306 is in a non-decoupled rotational connection with the fifth rotating element 308. For example, the surfaces of the fourth rotating element 306 and the fifth rotating element 308 that are in contact via the bearing housing are connected in a T-shaped configuration.

Specifically, the bearing housing includes a base and a bearing. The base is fixedly connected to the fifth rotating element 308, and the bearing is fixedly connected to the fourth rotating element 306 and rotatably connected to the base.

The size of the fifth rotating element 308 matches the size of the third supporting element 307. Generally, the radial dimension of the fifth rotating element 308 is smaller than the length/height of the fulcrum of the third supporting element 307; the length of the fifth rotating element 308 is less than the width of the fulcrum of the first movable element 204.

In some of these embodiments, the fifth rotating element 308 is a second connecting slot.

Further, the reinforcement unit 300 further comprises a moving element 309. Wherein a first end of the moving element 309 is connected to the third sliding element 303 and a second end of the moving element 309 is connected to the third supporting element 307.

The moving element 309 is rectangular in cross-section.

In some of these embodiments, the moving element 309 is fixedly connected with the third sliding element 303, the third supporting element 307. Including but not limited to welding.

In some of these embodiments, the moving element 309 is made of a metal material.

In some of these embodiments, the mobile element 309 is a connector plate.

The application method of the utility model is as follows:

(one) installation

Firstly, corresponding reserved holes are formed in a first beam element 101 and a second beam element 102;

next, the first support member 201 and the two second support members 301 are mounted on the first beam member 101 and the two second beam members 102 through the reserved holes. Wherein the first support element 201 is located at a right angle to the assembled first beam element 101 and second beam element 102; one second beam member 102 is located on the first beam member 101, and the other second beam member 102 is located on the corresponding second supporting member 301 (refer to fig. 1);

(II) fixing

Twisting the driving element 203 to drive the first rotating element 202 to rotate on the first supporting element 201, and driving the first movable element 204 to move along the surface of the first sliding element 206 by the first rotating element 202;

when the first movable element 204 moves near the first supporting element 201, the first movable element 204 drives the third sliding element 303 to move along the second sliding element 302 via the second movable element 304, and at this time, the second movable element 304 also generates a corresponding angle change on the first movable element 204 until the second movable element 304 is twisted, so as to adapt to the distance between the included angle sides of the adjacent first beam element 101 and second beam element 102, thereby completing the reinforcement operation on the beam body.

The utility model has the advantages that the primary installation operation can be achieved through the matched use of the first supporting element and the second supporting element, so that the subsequent reinforcement operation is convenient; through the cooperation between first movable element, second movable element and the third sliding element, consolidate first roof beam component and second roof beam component right angle department after the assembly to through corresponding regulation, the reinforcement operation of the different size roof beam body right angle departments of better adaptation.

The foregoing description is only illustrative of the preferred embodiments of the present utility model and is not to be construed as limiting the scope of the utility model, and it will be appreciated by those skilled in the art that equivalent substitutions and obvious variations may be made using the description and illustrations of the present utility model, and are intended to be included within the scope of the present utility model.

Claims (10)

1. A beam body reinforcing structure for construction, comprising:

a beam unit (100), the beam unit (100) being vertically arranged;

a drive unit (200), a first end of the drive unit (200) being connected to the beam unit (100);

and the two reinforcing units (300) are respectively connected with the second ends of the driving units (200) at the first ends of the reinforcing units (300), and the second ends of the reinforcing units (300) are respectively connected with the beam units (100) and are used for supporting and reinforcing the beam units (100) under the action of the driving units (200).

2. The reinforcement structure according to claim 1, characterized in that said beam unit (100) comprises:

a first beam element (101), the first beam element (101) being arranged vertically, the first beam element (101) being connected to a first end of the drive unit (200);

the second beam element (102), the second beam element (102) is perpendicular to the first beam element (101), and the second beam element (102) is connected with the first end of the driving unit (200).

3. The reinforcement structure according to claim 1, characterized in that said driving unit (200) comprises:

-a first support element (201), a first end of the first support element (201) being connected to the beam unit (100);

a first rotating element (202), a first end of the first rotating element (202) being rotatably connected to a second end of the first supporting element (201);

-a driving element (203), the driving element (203) being connected to the second end of the first rotating element (202) for driving the first rotating element (202) in rotation;

the first movable element (204) is rotationally connected with the first rotating element (202) and is used for reciprocating along the axial direction of the first rotating element (202) under the action of the driving element (203).

4. A reinforcing structure according to claim 3, wherein said driving unit (200) further comprises:

and the second rotating element (205) is arranged at the end part of the first movable element (204) and is rotationally connected with the reinforcing unit (300).

5. The reinforcement structure according to claim 3 or 4, wherein said driving unit (200) further comprises:

-a first sliding element (206), a first end of the first sliding element (206) being connected to a second end of the first supporting element (201) and being located at a side end of the first rotating element (202), the first sliding element (206) being slidably connected to the first movable element (204).

6. The reinforcement structure according to claim 5, wherein said driving unit (200) further comprises:

and the limiting element (207) is arranged at the second end of the first sliding element (206) and is used for preventing the first movable element (204) from being separated.

7. The reinforcing structure according to claim 1, wherein the reinforcing unit (300) comprises:

-a second support element (301), a first end of the second support element (301) being connected to the beam unit (100);

-a second sliding element (302), the second sliding element (302) being arranged at a second end of the second supporting element (301);

-a third sliding element (303), said third sliding element (303) being slidingly connected to said second sliding element (302);

-a second movable element (304), a first end of the second movable element (304) being connected to the third sliding element (303), a second end of the second movable element (304) being connected to the drive unit (200).

8. The reinforcement structure according to claim 7, wherein said reinforcement unit (300) further comprises:

and the third rotating element (305) is arranged at the second end of the second movable element (304) and is rotationally connected with the driving unit (200).

9. The reinforcement structure according to claim 7 or 8, wherein said reinforcement unit (300) further comprises:

a fourth rotating element (306), the fourth rotating element (306) being arranged at a first end of the second movable element (304);

-a third support element (307), a first end of the third support element (307) being connected to the third sliding element (303);

and a fifth rotating element (308), wherein the fifth rotating element (308) is arranged at the second end of the third supporting element (307) and is rotationally connected with the fourth rotating element (306).

10. The reinforcement structure according to claim 9, wherein said reinforcement unit (300) further comprises:

-a moving element (309), a first end of the moving element (309) being connected to the third sliding element (303), a second end of the moving element (309) being connected to the third supporting element (307).