CN216974280U

CN216974280U - Spandrel girder reinforcing apparatus suitable for building structure design

Info

Publication number: CN216974280U
Application number: CN202220061666.8U
Authority: CN
Inventors: 王宇
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-01-11
Filing date: 2022-01-11
Publication date: 2022-07-15
Anticipated expiration: 2032-01-11

Abstract

The utility model provides a bearing beam reinforcing device suitable for building structure design, relates to the technical field of building construction, and aims to solve the problems that the existing bearing beam reinforcing device suitable for building structure design is large in size, not uniform in supporting stress, not convenient and fast to mount and dismount, incapable of realizing integral auxiliary hoisting, and poor in anti-seismic performance; the lifting installation part is fixedly connected with a driving extrusion device; the driving extrusion device is fixedly connected with a cross beam supporting device; two sides of the bottom of the cross beam supporting device are respectively connected with a balance stress part in a sliding way; sliding connection has two roof pressure devices that float on the crossbeam strutting arrangement, through setting up the crossbeam strutting arrangement that drive extrusion device cooperation set up, can be convenient for more the installation, and the space occupies lowly, and different roof beam height suitability is better, through setting up the lift installation department, can realize the regulation support dynamics of freedom, the drive extrusion device of setting.

Description

Spandrel girder reinforcing apparatus suitable for building structure design

Technical Field

The utility model belongs to the technical field of building construction, and particularly relates to a bearing beam reinforcing device suitable for building structure design.

Background

In actual building construction process, it is especially important to the spandrel girder reinforcement work, because relate to standards such as building construction safety, the spandrel girder reinforcing apparatus who is applicable to building structure design that a section is good at this time just seems very important, current spandrel girder reinforcing apparatus who is applicable to building structure design, and is bulky, the suitability is poor, occupies a large amount of spaces, supports the atress simultaneously and evenly very easily causes secondary damage to the spandrel girder inadequately, and it is convenient inadequately to install and dismantle, can't realize whole supplementary hoist and mount, and anti-seismic performance is poor.

Therefore, in view of the above, research and improvement are made on the existing structure and defects, and a reinforcing device for a load-bearing beam suitable for the design of a building structure is provided, so as to achieve the purpose of higher practical value.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problems, the utility model provides a bearing beam reinforcing device suitable for building structure design, and aims to solve the problems that the existing bearing beam reinforcing device suitable for building structure design is large in size, not uniform in supporting stress, not convenient and fast to mount and dismount, incapable of realizing integral auxiliary hoisting and poor in anti-seismic performance.

The utility model is suitable for the purpose and the effect of a bearing beam reinforcing device designed by a building structure, and is achieved by the following specific technical means:

the bearing beam reinforcing device suitable for the building structure design comprises a lifting installation part; the lifting installation part is fixedly connected with a driving extrusion device; the driving extrusion device is fixedly connected with a cross beam supporting device; two sides of the bottom of the cross beam supporting device are respectively connected with a balance stress part in a sliding way; the beam supporting device is connected with two floating jacking devices in a sliding way; four adjustable hoisting parts are fixedly connected to the beam supporting device; the lift installation department includes: the lifting installation base is provided with six installation parts at the bottom; the driving sleeve is provided with threads; the driving sleeve is rotationally connected to the lifting installation base; a rotating handle is arranged on the driving sleeve; the driving pressing device includes: pushing the extrusion block, wherein the two sides of the pushing extrusion block are of inclined surface structures; the pushing and extruding block is fixedly connected to the driving screw rod.

Further, the adjustable hoisting part comprises: the fixed shaft seat is fixedly connected to the cross beam support frame; the sliding shaft is connected to the fixed shaft seat in a sliding manner; the bottom of the sliding shaft is provided with threads; the adjusting nut is in threaded connection with the sliding shaft; the support spring is sleeved on the sliding shaft; the supporting spring is positioned above the adjusting nut; the connecting plate is fixedly connected to the sliding shaft; the connecting plate is provided with a through hole.

Further, the lift installation department still includes: and the driving screw rod is in threaded connection with the driving sleeve.

Further, the beam support device includes: the beam support frame is fixedly connected to the two sliding telescopic shafts; the two elastic plates are respectively and fixedly connected to the inner side of the cross beam supporting frame; the installation sliding sleeve, the installation sliding sleeve is equipped with two, and two installation sliding sleeves are fixed connection respectively in crossbeam support frame bottom.

Further, the driving extrusion device further comprises: two sliding telescopic shafts are arranged and are respectively connected to the pushing and extruding block in a sliding manner; the two sliding telescopic shafts are respectively sleeved with a spring, and the springs are positioned above the pushing and extruding block.

Further, the floating top pressure device comprises: the two floating extrusion columns are connected to the cross beam support frame in a sliding manner; the bottoms of the two floating extrusion columns are of a hemispherical structure; the bottoms of the two floating extrusion columns are respectively attached to the two extrusion inclined planes; the floating plates are arranged in two numbers and are respectively and fixedly connected to the floating extrusion columns.

Further, the balance force receiving portion includes: the side surfaces of the driving sliding blocks are of inclined plane structures, the number of the driving sliding blocks is two, and the two driving sliding blocks are respectively connected to the bottoms of the cross beam supporting frames in a sliding mode; the side surfaces of the two driving slide blocks are respectively attached to the two sides of the pushing extrusion block; the two extrusion plates are fixedly connected to the side face of the driving sliding block respectively, and extrusion inclined planes are arranged on the side faces of the extrusion plates.

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

1. the utility model can be more conveniently installed by arranging the crossbeam supporting device matched with the driving extrusion device, has smaller volume, lower space occupation and better applicability to different beam heights, can realize free adjustment of supporting force by arranging the lifting installation part, can be more conveniently attached to the bottom of the bearing beam by adopting a mode of sleeving a spring on the sliding telescopic shaft by the arranged driving extrusion device, provides better stress, ensures the maximum stress area, has simple structure and low manufacturing cost by arranging the elastic plate in the arranged crossbeam supporting frame, is more practical, can enable the elastic plate to be attached to two sides of the crossbeam by inserting the crossbeam supporting frame into the bearing beam, provides better installation stability, can quickly drive the lifting height of the pushing extrusion block on the arranged driving screw rod by rotating the driving sleeve, simple structure is stable, adopts the drive sleeve, and the altitude mixture control scope is bigger.

2. The utility model can effectively improve the uniformity of supporting stress by arranging the balance stress part and the floating jacking device, can effectively avoid local cracks and fractures of the bearing beam caused by overlarge local jacking pressure of the bearing beam, can effectively improve the integral bearing and supporting effect of the cross beam supporting frame by arranging the adjustable hoisting part, can realize pressure dispersion and improve the structural strength of a building, can extrude two driving slide blocks by pushing the extruding block in the process of driving the extruding block to ascend by rotating the driving sleeve, realizes that two extruding plates respectively extrude the floating extruding column, further realizes that the floating plate is driven to ascend and extrude, has simple and stable structure, can effectively improve the uniformity of the integral stress, can effectively avoid the occurrence of steel fatigue of the cross beam supporting frame in long-term use, can directly connect the connecting plate with the shed roof through the expansion bolt, can rotate adjusting nut and come extrusion supporting spring to realize adjusting hoist and mount support dynamics, use more nimble, the installation of being convenient for more, whole intensity that can effectual improvement bearing beam, it is better to consolidate the effect.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view of the upper structure of the present invention.

Fig. 3 is a sectional view of the internal structure of the present invention.

Fig. 4 is a schematic view of the lifting installation part of the present invention.

Fig. 5 is a schematic structural view of the driving extrusion device of the utility model.

Fig. 6 is a schematic structural view of the cross beam support apparatus of the present invention.

Fig. 7 is a schematic structural view of the floating roof pressure device of the present invention.

Fig. 8 is a schematic structural view of the adjustable lifting part of the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a lifting installation part;

101. lifting and mounting a base; 1011. a mounting member; 102. a drive sleeve; 103. driving the screw rod;

2. driving the extrusion device;

201. pushing the extrusion block; 202. sliding the telescopic shaft;

3. a beam support means;

301. a beam support frame; 302. an elastic plate; 303. installing a sliding sleeve;

4. a balance stress part;

401. driving the slide block; 402. a compression plate; 4021. extruding the inclined plane;

5. a floating jacking device;

501. floating the extrusion column; 502. a floating plate;

6. an adjustable hoisting part;

601. fixing the shaft seat; 602. a sliding shaft; 603. adjusting the nut; 604. a support spring; 605. a connecting plate.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the utility model but are not intended to limit the scope of the utility model.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and to simplify the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in a specific case to those of ordinary skill in the art.

Example (b):

as shown in figures 1 to 8:

the utility model provides a spandrel girder reinforcing device suitable for building structure design, which comprises a lifting installation part 1; the lifting installation part 1 is fixedly connected with a driving extrusion device 2; the driving extrusion device 12 is fixedly connected with a beam supporting device 3; two sides of the bottom of the cross beam supporting device 3 are respectively connected with a balance stress part 4 in a sliding way; the beam supporting device 3 is connected with two floating jacking devices 5 in a sliding way; four adjustable hoisting parts 6 are fixedly connected to the beam supporting device 3; the lift installation part 1 includes: the lifting installation base 101 is provided with six installation pieces 1011 at the bottom of the lifting installation base 101; a driving sleeve 102, wherein the driving sleeve 102 is provided with threads; the driving sleeve 102 is rotatably connected to the lifting installation base 101; a rotating handle is arranged on the driving sleeve 102; the driving pressing device 2 includes: the extrusion block 201 is pushed in, and two sides of the extrusion block 201 are in an inclined plane structure; the pushing and extruding block 201 is fixedly connected to the driving screw rod 103.

As shown in fig. 4 to 6, the lifting and lowering mounting part 1 further includes: the driving screw rod 103, the driving screw rod 103 is connected to the driving sleeve 102 in a threaded manner; the driving extrusion device 2 further comprises: two sliding telescopic shafts 202 are arranged, and the two sliding telescopic shafts 202 are respectively connected to the pushing extrusion block 201 in a sliding manner; the two sliding telescopic shafts 202 are respectively sleeved with a spring, and the springs are positioned above the pushing extrusion block 201; the beam support device 3 includes: the beam support frame 301, the beam support frame 301 is fixedly connected to the two sliding telescopic shafts 202; two elastic plates 302 are arranged, and the two elastic plates 302 are respectively and fixedly connected to the inner side of the cross beam support frame 301; two mounting sliding sleeves 303 are arranged, and the two mounting sliding sleeves 303 are respectively and fixedly connected to the bottom of the cross beam supporting frame 301; the installation can be more convenient by arranging the cross beam supporting device 3 matched with the driving extrusion device 2, the volume is smaller, the space occupation is lower, the applicability of different beam heights is better, the free adjustment of the supporting force can be realized by arranging the lifting installation part 1, the arranged driving extrusion device 2 can be more convenient to attach the cross beam supporting frame 301 to the bottom of the bearing beam by adopting a mode of sleeving a spring on the sliding telescopic shaft 202, better stress is provided, the maximum stress area is ensured, the structure is simple, the manufacturing cost is low and the use is more practical, the cross beam supporting frame 301 is inserted into the bearing beam, the elastic plate 302 can be attached to the two sides of the cross beam, the better installation stability is provided, the lifting height of the pushing extrusion block 201 on the driving lead screw 103 can be quickly driven by rotating the driving sleeve 102, the structure is simple and stable, and the height adjusting range is wider by adopting the driving sleeve 102.

As shown in fig. 6 to 8, the balanced force-receiving portion 4 includes: the side surfaces of the driving sliding blocks 401 are inclined surfaces, the number of the driving sliding blocks 401 is two, and the two driving sliding blocks 401 are respectively connected to the bottoms of the beam supporting frames 301 in a sliding mode; the side surfaces of the two driving sliding blocks 401 are respectively attached to the two sides of the pushing and extruding block 201; the number of the extrusion plates 402 is two, the two extrusion plates 402 are fixedly connected to the side surfaces of the driving sliding block 401 respectively, and the side surfaces of the extrusion plates 402 are provided with extrusion inclined surfaces 4021; the floating jacking device 5 comprises: two floating extrusion columns 501 are arranged, and the two floating extrusion columns 501 are connected to the cross beam support frame 301 in a sliding manner; the bottoms of the two floating extrusion columns 501 are of a hemispherical structure; the bottoms of the two floating extrusion columns 501 are respectively attached to the two extrusion inclined planes 4021; two floating plates 502 are arranged, and the two floating plates 502 are respectively and fixedly connected to the floating extrusion column 501; adjustable hoist and mount portion 6 includes: the fixed shaft seat 601 is fixedly connected to the cross beam support frame 301; the sliding shaft 602, the sliding shaft 602 is connected to the fixed shaft seat 601 in a sliding manner; the bottom of the sliding shaft 602 is provided with threads; an adjusting nut 603, wherein the adjusting nut 603 is in threaded connection with the sliding shaft 602; a support spring 604, wherein the support spring 604 is sleeved on the sliding shaft 602; the support spring 604 is located above the adjustment nut 603; the connecting plate 605 is fixedly connected to the sliding shaft 602; the connecting plate 605 is provided with through holes, the uniformity of supporting stress can be effectively improved by arranging the balance stress part 4 and the floating jacking device 5, the local cracks and fractures of the bearing beam caused by overlarge local jacking pressure of the bearing beam can be effectively avoided, the integral bearing and supporting effect of the cross beam supporting frame 301 can be effectively improved by arranging the adjustable hoisting part 6, the pressure dispersion and the building structure strength can be realized, the two driving sliding blocks 401 can be extruded by the pushing extrusion block 201 in the process of driving the pushing extrusion block 201 to rise by rotating the driving sleeve 102, the floating extrusion columns 501 are respectively extruded by the two extrusion plates 402, the floating plate 502 is driven to rise and extrude, the structure is simple and stable, the integral stress uniformity can be effectively improved, and the spaciousness of steel fatigue of the cross beam supporting frame 301 caused by long-term use can be effectively avoided, can be directly pass through expansion bolts with connecting plate 605 and shed roof and be connected, can rotate adjusting nut 603 and come extrusion supporting spring 604 and realize adjusting the hoist and mount dynamics of supporting, use more in a flexible way, the installation of being convenient for more, whole intensity that can effectual improvement bearing beam, the reinforcement effect is better.

The specific use mode and function of the embodiment are as follows:

in the utility model, firstly, the beam support frame 301 is inserted into the bearing beam, so that the elastic plate 302 can be attached to two sides of the beam, better installation stability is provided, the connecting plate 605 can be directly connected with the shed roof through the expansion bolt, the adjusting nut 603 can be rotated to extrude the supporting spring 604 to realize adjustment of hoisting support strength, the lifting installation base 101 is installed on the ground through the bolt, the lifting height of the pushing extrusion block 201 on the driving screw rod 103 can be quickly driven and arranged by rotating the driving sleeve 102, the two driving slide blocks 401 can be extruded through the pushing extrusion block 201 in the process of driving the pushing extrusion block 201 to lift height by rotating the driving sleeve 102, so that the two extrusion plates 402 are driven to respectively extrude the floating extrusion column 501, the floating plate 502 is driven to lift and extrude, uniform stress is shared, and the practicability and the building structural strength are improved, and finally finishing the using process of the bearing beam reinforcing device.

The utility model is not described in detail, but is well known to those skilled in the art.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the utility model in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the utility model and the practical application, and to enable others of ordinary skill in the art to understand the utility model for various embodiments with various modifications as are suited to the particular use contemplated.

Claims

1. Spandrel girder reinforcing apparatus suitable for building structure design, its characterized in that: comprises a lifting installation part (1); the lifting installation part (1) is fixedly connected with a driving extrusion device (2); the driving extrusion device (2) is fixedly connected with a cross beam supporting device (3); two sides of the bottom of the cross beam supporting device (3) are respectively connected with a balance stress part (4) in a sliding way; the beam supporting device (3) is connected with two floating jacking devices (5) in a sliding way; four adjustable hoisting parts (6) are fixedly connected to the beam supporting device (3); the lift installation department (1) includes: the lifting installation base (101), six installation parts (1011) are arranged at the bottom of the lifting installation base (101); the driving sleeve (102), the driving sleeve (102) is provided with screw threads; the driving sleeve (102) is rotationally connected to the lifting installation base (101); a rotating handle is arranged on the driving sleeve (102); the drive extrusion device (2) comprises: the pushing extrusion block (201), and both sides of the pushing extrusion block (201) are of inclined surface structures; the pushing and extruding block (201) is fixedly connected to the driving screw rod (103).

2. A spandrel girder reinforcing apparatus adapted for use in architectural structural design according to claim 1, wherein: lift installation department (1) still includes: and the driving screw rod (103), and the driving screw rod (103) is in threaded connection with the driving sleeve (102).

3. A spandrel girder reinforcing apparatus adapted for use in building structural design according to claim 1, wherein: the drive extrusion device (2) further comprises: two sliding telescopic shafts (202) are arranged, and the two sliding telescopic shafts (202) are respectively connected to the pushing extrusion block (201) in a sliding manner; the two sliding telescopic shafts (202) are respectively sleeved with a spring, and the springs are positioned above the pushing and extruding block (201).

4. A spandrel girder reinforcing apparatus adapted for use in building structural design according to claim 3, wherein: the beam support device (3) comprises: the beam support frame (301), the beam support frame (301) is fixedly connected to the two sliding telescopic shafts (202); two elastic plates (302) are arranged, and the two elastic plates (302) are respectively and fixedly connected to the inner side of the cross beam supporting frame (301); the mounting sliding sleeves (303) are arranged, the number of the mounting sliding sleeves (303) is two, and the two mounting sliding sleeves (303) are respectively and fixedly connected to the bottom of the cross beam supporting frame (301).

5. A spandrel girder reinforcing apparatus adapted for use in building structural design according to claim 1, wherein: the balance force receiving portion (4) includes: the side surface of each driving sliding block (401) is of an inclined surface structure, two driving sliding blocks (401) are arranged, and the two driving sliding blocks (401) are respectively connected to the bottom of the cross beam supporting frame (301) in a sliding mode; the side surfaces of the two driving sliding blocks (401) are respectively attached to the two sides of the pushing and extruding block (201); two extrusion plates (402) are arranged, the two extrusion plates (402) are respectively and fixedly connected to the side face of the driving sliding block (401), and the side face of each extrusion plate (402) is provided with an extrusion inclined face (4021).

6. A spandrel girder reinforcing apparatus adapted for use in building structure design according to claim 4, wherein: the floating jacking device (5) comprises: the two floating extrusion columns (501) are arranged, and the two floating extrusion columns (501) are connected to the cross beam support frame (301) in a sliding manner; the bottoms of the two floating extrusion columns (501) are of a hemispherical structure; the bottoms of the two floating extrusion columns (501) are respectively attached to the two extrusion inclined planes (4021); two floating plates (502) are arranged, and the two floating plates (502) are respectively and fixedly connected to the floating extrusion column (501).

7. A spandrel girder reinforcing apparatus adapted for use in building structure design according to claim 4, wherein: the adjustable hoisting part (6) comprises: the fixed shaft seat (601), the fixed shaft seat (601) is fixedly connected to the cross beam support frame (301); the sliding shaft (602), the sliding shaft (602) is connected to the fixed shaft seat (601) in a sliding way; the bottom of the sliding shaft (602) is provided with threads; the adjusting nut (603), the adjusting nut (603) is connected to the sliding shaft (602) in a threaded manner; the supporting spring (604), the supporting spring (604) is fitted over the sliding shaft (602); the supporting spring (604) is positioned above the adjusting nut (603); the connecting plate (605), the connecting plate (605) is fixedly connected on the sliding shaft (602); the connecting plate (605) is provided with a through hole.