CN112008392B

CN112008392B - Assembled steel construction crossbeam corrects detection device

Info

Publication number: CN112008392B
Application number: CN202010830381.1A
Authority: CN
Inventors: 徐晶
Original assignee: Zhejiang Geotechnical Survey And Design Institute Co ltd
Current assignee: Zhejiang geotechnical survey and Design Institute Co.,Ltd.
Priority date: 2020-08-18
Filing date: 2020-08-18
Publication date: 2022-02-08
Anticipated expiration: 2040-08-18
Also published as: CN112008392A

Abstract

The invention relates to the technical field of beam correction detection equipment, in particular to an assembly type steel structure beam correction detection device which comprises a driving mechanism I, a driving mechanism II, a bearing mechanism, adjusting mechanisms, clamping mechanisms, positioning mechanisms, moving mechanisms, detection mechanisms and display mechanisms, wherein the two adjusting mechanisms are respectively connected to the front end of the bearing mechanism in a sliding manner, each adjusting mechanism is provided with the driving mechanism I, the two clamping mechanisms are respectively connected to the front ends of the two adjusting mechanisms in a sliding manner, the plurality of positioning mechanisms are respectively connected to the upper end of the bearing mechanism in a sliding manner, the driving mechanism II is fixedly connected to each positioning mechanism, the plurality of moving mechanisms are respectively connected to the plurality of positioning mechanisms in a sliding manner, the lower end of each moving mechanism is respectively connected with the detection mechanism in a sliding manner, the plurality of display mechanisms are respectively arranged at the upper ends of the plurality of moving mechanisms, and the device is suitable for beam correction detection of support columns with different spacing sizes, the positions of a plurality of correction detections can be flexibly adjusted, and the universality of the equipment is improved.

Description

Assembled steel construction crossbeam corrects detection device

Technical Field

The invention relates to the technical field of beam correction detection equipment, in particular to an assembly type steel structure beam correction detection device.

Background

Along with the increase of domestic population, the house demand in the society constantly improves, but traditional house construction method time limit for a project is longer, the main reason lies in that the overlap joint of house construction in-process frame needs longer time, in order to solve this problem, the assembled steel structure is created, the building of house frame can be accomplished fast to the assembled steel structure, the time of house construction is shortened to the very big degree, after steel construction crossbeam settles, need to correct the detection to the crossbeam, but the current assembled steel structure crossbeam corrects detection device and only is suitable for the correction detection of a few kinds of crossbeams, and correct the position that detects and fix, the commonality of device is relatively poor.

Disclosure of Invention

The invention aims to provide an assembly type steel structure beam correction and detection device which can be suitable for beam correction and detection of support columns with different spacing sizes, can perform correction and detection of a plurality of position points at the same time, can flexibly adjust the positions of the plurality of correction and detection, and improves the universality of equipment.

The purpose of the invention is realized by the following technical scheme:

an assembly type steel structure beam correction and detection device comprises a driving mechanism I and a driving mechanism II, and further comprises a bearing mechanism, two adjusting mechanisms, two clamping mechanisms, two position adjusting mechanisms, a moving mechanism, a detection mechanism and a display mechanism, wherein the two adjusting mechanisms are slidably connected to the front end of the bearing mechanism, each adjusting mechanism is provided with the driving mechanism I, the two clamping mechanisms are respectively slidably connected to the front ends of the two adjusting mechanisms, the two clamping mechanisms are respectively in transmission connection with the two driving mechanisms I, the position adjusting mechanisms are provided with a plurality of position adjusting mechanisms, the plurality of position adjusting mechanisms are respectively slidably connected to the upper end of the bearing mechanism, the driving mechanism II is fixedly connected to each position adjusting mechanism, the moving mechanism is provided with a plurality of positions, and the plurality of moving mechanisms are respectively slidably connected to the plurality of position adjusting mechanisms, and the plurality of moving mechanisms are respectively in transmission connection with the plurality of driving mechanisms II, the lower end of each moving mechanism is connected with the detection mechanism in a sliding manner, the plurality of display mechanisms are arranged at the upper ends of the plurality of moving mechanisms respectively, and the plurality of display mechanisms are respectively in transmission connection with the plurality of detection mechanisms.

As a further optimization of the technical scheme, the assembly type steel structure crossbeam correction and detection device comprises a bearing frame, a slide bar, a threaded rod I and a threaded rod II, wherein the slide bar is fixedly connected to the front side of the upper end of the bearing frame, the threaded rod I is fixedly connected to the rear side of the upper end of the bearing frame, the threaded rod II is fixedly connected to the lower end of the bearing frame, two adjusting mechanisms are both slidably connected to the front end of the bearing frame, the two adjusting mechanisms are both in transmission connection with the threaded rod II through thread fit, a plurality of positioning mechanisms are all slidably connected to the upper end of the slide bar, and the plurality of positioning mechanisms are all in transmission connection with the threaded rod I through thread fit.

As a further optimization of the technical scheme, the assembly type steel structure crossbeam correction and detection device comprises adjusting mechanisms, threaded pipes I and slide ways, wherein the threaded pipes I are rotatably connected to the rear ends of the adjusting mechanisms, the four slide ways are arranged on the adjusting mechanisms in a pairwise symmetry manner, the two adjusting mechanisms are both slidably connected to the front end of the bearing frame, the two threaded pipes I are both in transmission connection with the threaded rods II in a threaded fit manner, the two driving mechanisms I are respectively arranged on the rear sides of the adjusting mechanisms, and the rear end of each clamping mechanism is slidably connected into the four slide ways on the same adjusting mechanism.

As a further optimization of the technical scheme, the assembly type steel structure crossbeam correction and detection device comprises a driving mechanism I, a transmission rod and threads, wherein the transmission rod is fixedly connected with an output shaft of the motor I, the transmission rod is symmetrically provided with the two threads with opposite rotation directions, the transmission rod is rotatably connected to the rear end of an adjusting frame, the motor I is fixedly connected to the outer end of the adjusting frame, and the two clamping mechanisms are respectively in matched transmission connection with the two transmission rods through the threads.

As a further optimization of the technical scheme, the invention discloses an assembly type steel structure beam correction and detection device, the clamping mechanism comprises a linkage plate I, a transmission block I, a spring I, a clamping plate I, a linkage plate II, a transmission block II, a spring II and a clamping plate II, the driving block I is fixedly connected to the rear end of the linkage plate I, four springs I are arranged, the four springs I are respectively and fixedly connected to the inner side of the linkage plate I, the clamping plate I is fixedly connected to the inner sides of the four springs I, the transmission block II is fixedly connected to the rear end of the linkage plate II, four springs II are arranged and are respectively fixedly connected at the four corners of the inner side of the linkage plate II, the clamping plate II is fixedly connected with the inner ends of the four springs II, the rear ends of the linkage plate I and the linkage plate II are respectively connected in the four slideways in a sliding manner, and the transmission block I and the transmission block II are respectively in matched transmission connection with two threads with opposite rotation directions on the same transmission rod.

As a further optimization of the technical scheme, the assembly type steel structure crossbeam correction and detection device comprises a positioning mechanism, a threaded pipe ii, a chute, an end plate and a graduated scale, wherein the threaded pipe ii is rotatably connected to the rear end of the positioning mechanism, the chute is arranged at the lower end of the positioning mechanism, the end plate is fixedly connected to the lower end of the positioning mechanism, the graduated scale is fixedly connected to the front end of the positioning mechanism, a plurality of driving mechanisms ii are respectively arranged in the plurality of positioning mechanisms, a plurality of moving mechanisms are respectively slidably connected to the front ends of the plurality of positioning mechanisms, and the chutes are all slidably connected to a slide bar.

As a further optimization of the technical scheme, the assembly type steel structure crossbeam correction detection device provided by the invention comprises a driving mechanism II and a threaded rod III, wherein the threaded rod III is fixedly connected to the lower end of an output shaft of the motor II, a plurality of motors II are respectively and fixedly connected to the upper ends of a plurality of end plates, and a plurality of threaded rods III are respectively in transmission connection with a plurality of moving mechanisms in a thread fit manner.

As a further optimization of the technical scheme, the assembled steel structure crossbeam correction detection device comprises a moving mechanism, a moving plate, a through hole, a gear rack and sliding holes, wherein the moving plate is fixedly connected to the front end of the threaded block, the middle of the moving plate is provided with the through hole, the sliding holes are formed in four corners of the moving plate, the gear rack is arranged at the front end of the through hole, the threaded blocks are respectively and slidably connected into the position adjusting frames, the threaded blocks are respectively and drivingly connected with the threaded rods iii through threaded matching, the detection mechanisms are respectively and slidably connected into the through holes, and the display mechanisms are respectively and fixedly connected onto the gear rack.

As a further optimization of the technical scheme, the detection mechanism comprises a pressing plate, four racks and four sliding rods, the racks are fixedly connected to the middle of the pressing plate, the four sliding rods are respectively and fixedly connected to four corners of the pressing plate, the racks are slidably connected into a through hole, the four sliding rods are respectively and slidably connected into four sliding holes in the same moving plate with the through hole, and the racks are respectively in meshing transmission connection with the display mechanisms.

As a further optimization of the technical solution, the assembled steel structure beam correction and detection device of the present invention comprises a display mechanism, wherein the display mechanism comprises a gear, a pointer and a dial, the pointer is rotatably connected in the dial, the gear and the pointer are fixedly connected, the plurality of gears are respectively and fixedly connected to a plurality of gear racks, the plurality of gears are respectively and drivingly connected with the plurality of racks, and the plurality of dials are respectively and fixedly connected to the left sides of the plurality of gear racks.

The assembled steel structure crossbeam correction and detection device has the beneficial effects that: the beam correction detection device has the advantages that the beam correction detection device can be suitable for the cross beams of support columns with different spacing sizes through two adjusting mechanisms, two driving mechanisms I and two clamping mechanisms, correction detection of a plurality of position points can be simultaneously carried out through a plurality of positioning mechanisms, a plurality of driving mechanisms II, a plurality of moving mechanisms, a plurality of detecting mechanisms and a plurality of display mechanisms, and meanwhile, the positions of a plurality of correction detections can be flexibly adjusted, so that the universality of the device is improved.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic diagram I of the overall structure of an assembly type steel structure beam correction detection device;

FIG. 2 is a schematic diagram II of the overall structure of the present invention;

FIG. 3 is a schematic structural view of the load bearing mechanism of the present invention;

FIG. 4 is a schematic structural view of the adjustment mechanism of the present invention;

FIG. 5 is a schematic structural view of a driving mechanism I of the present invention;

figure 6 is a schematic structural view i of the clamping mechanism of the present invention;

figure 7 is a schematic structural view ii of the clamping mechanism of the present invention;

FIG. 8 is a schematic structural view of the positioning mechanism of the present invention;

FIG. 9 is a schematic structural view of the moving mechanism of the present invention;

FIG. 10 is a schematic view of the structure of the detection mechanism of the present invention;

fig. 11 is a schematic view of the structure of the display mechanism of the present invention.

In the figure: a carrying mechanism 1; a carrier 1-1; 1-2 of a slide bar; 1-3 parts of a threaded rod I; 1-4 parts of a threaded rod II; an adjusting mechanism 2; 2-1 of an adjusting frame; 2-2 parts of a threaded pipe; 2-3 of a slideway; a driving mechanism I3; the motor I3-1; a transmission rod 3-2; 3-3 of threads; a clamping mechanism 4; a linkage plate I4-1; a transmission block I4-2; 4-3 of a spring; 4-4 parts of a splint; 4-5 of a linkage plate II; 4-6 of a transmission block; 4-7 of a spring; 4-8 of a splint; a position adjusting mechanism 5; a positioning frame 5-1; 5-2 of a threaded pipe II; 5-3 of a chute; 5-4 of an end plate; 5-5 of a graduated scale; a driving mechanism II 6; a motor II 6-1; 6-2 parts of a threaded rod III; a moving mechanism 7; a thread block 7-1; moving a plate 7-2; 7-3 of a through hole; gear carrier 7-4; 7-5 of a sliding hole; a detection mechanism 8; 8-1 of a pressing plate; a rack 8-2; a slide bar 8-3; a display mechanism 9; gear 9-1; a pointer 9-2; scale 9-3.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it is to be understood that the terms "center", "length", "width", "thickness", "upper", "lower", "vertical", "horizontal", "top", "bottom", "inner", "outer", "axial", "circumferential", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

In the present invention, unless otherwise expressly specified or limited, the terms "disposed," "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected or detachably connected; may be a mechanical connection; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 11, and an assembly type steel structure beam straightening and detecting device includes a driving mechanism i 3 and a driving mechanism ii 6, and further includes a bearing mechanism 1, two adjusting mechanisms 2, two clamping mechanisms 4, two positioning mechanisms 5, a moving mechanism 7, two detecting mechanisms 8 and a display mechanism 9, where the two adjusting mechanisms 2 are both slidably connected to the front end of the bearing mechanism 1, each adjusting mechanism 2 is provided with a driving mechanism i 3, the two clamping mechanisms 4 are provided, the two clamping mechanisms 4 are respectively slidably connected to the front ends of the two adjusting mechanisms 2, the two clamping mechanisms 4 are respectively in transmission connection with the two driving mechanisms i 3, the positioning mechanisms 5 are provided in plurality, and the positioning mechanisms 5 are all slidably connected to the upper end of the bearing mechanism 1, equal fixedly connected with actuating mechanism II 6 on every positioning mechanism 5, moving mechanism 7 is provided with a plurality ofly, and a plurality of moving mechanism 7 are sliding connection respectively on a plurality of positioning mechanisms 5, and a plurality of moving mechanism 7 are connected with the transmission of a plurality of actuating mechanism II 6 respectively, and the equal sliding connection of lower extreme of every moving mechanism 7 has detection mechanism 8, display mechanism 9 is provided with a plurality ofly, and a plurality of display mechanism 9 set up respectively in the upper end of a plurality of moving mechanism 7, and a plurality of display mechanism 9 are connected with the transmission of a plurality of detection mechanism 8 respectively.

The second embodiment is as follows:

this embodiment will be described with reference to fig. 1 to 11, which further illustrate the first embodiment, the bearing mechanism 1 comprises a bearing frame 1-1, a slide bar 1-2, a threaded rod I1-3 and a threaded rod II 1-4, the slide bar 1-2 is fixedly connected with the front side of the upper end of the bearing frame 1-1, the threaded rod I1-3 is fixedly connected with the rear side of the upper end of the bearing frame 1-1, the threaded rods II 1-4 are fixedly connected to the lower end of the bearing frame 1-1, the two adjusting mechanisms 2 are both connected to the front end of the bearing frame 1-1 in a sliding manner, the two adjusting mechanisms 2 are in transmission connection with the threaded rods II 1-4 through thread matching, the plurality of positioning mechanisms 5 are in sliding connection with the upper ends of the slide bars 1-2, and a plurality of positioning mechanisms 5 are in transmission connection with the threaded rods I1-3 through thread matching.

The third concrete implementation mode:

this embodiment will be described with reference to fig. 1 to 11, and a second embodiment will be further described with reference to this embodiment, the adjusting mechanism 2 comprises an adjusting frame 2-1, a threaded pipe I2-2 and a slideway 2-3, the threaded pipes I2-2 are rotatably connected to the rear ends of the adjusting frames 2-1, the number of the slideways 2-3 is four, the four slideways 2-3 are symmetrically arranged on the adjusting frames 2-1 in pairs, the two adjusting frames 2-1 are connected to the front ends of the bearing frames 1-1 in a sliding mode, the two threaded pipes I2-2 are connected with the threaded rods II 1-4 in a transmission mode through threaded matching, the two driving mechanisms I3 are arranged on the rear sides of the adjusting frames 2-1 respectively, and the rear end of each clamping mechanism 4 is connected to the four slideways 2-3 on the same adjusting frame 2-1 in a sliding mode.

When the device is used, firstly, two threaded pipes I2-2 are respectively rotated, the two threaded pipes I2-2 are respectively in transmission connection with threaded rods II 1-4 through threaded matching, the two threaded pipes I2-2 respectively drive two adjusting frames 2-1 to move at the front ends of the bearing frames 1-1, the middle parts of the two bearing frames 1-1 respectively move to the rear sides of two adjacent supporting columns, and then the two bearing frames 1-1 are respectively attached to the rear sides of the top ends of the two supporting columns.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 11, and the third embodiment is further described in the present embodiment, the driving mechanism i 3 includes a motor i 3-1, a transmission rod 3-2 and threads 3-3, the transmission rod 3-2 is fixedly connected to an output shaft of the motor i 3-1, the transmission rod 3-2 is symmetrically provided with two threads 3-3 with opposite rotation directions, the transmission rod 3-2 is rotatably connected to a rear end of the adjusting frame 2-1, the motor i 3-1 is fixedly connected to an outer end of the adjusting frame 2-1, and the two clamping mechanisms 4 are respectively in transmission connection with the two transmission rods 3-2 through thread fit.

The two motors I3-1 are respectively started, the output shafts of the two motors I3-1 respectively drive the two transmission rods 3-2 to rotate, the two transmission rods 3-2 respectively drive the four threads 3-3 to rotate, and the two threads 3-3 on one transmission rod 3-2 are respectively connected with the corresponding transmission block I4-2 and transmission block II 4-6 through thread matching transmission to drive the transmission block I4-2 and the transmission block II 4-6 to move relatively.

The fifth concrete implementation mode:

the fourth embodiment is described below with reference to fig. 1-11, and is further described, wherein the clamping mechanism 4 comprises a linkage plate i 4-1, a transmission block i 4-2, a spring i 4-3, a clamping plate i 4-4, a linkage plate ii 4-5, a transmission block ii 4-6, a spring ii 4-7 and a clamping plate ii 4-8, the transmission block i 4-2 is fixedly connected to the rear end of the linkage plate i 4-1, the number of the springs i 4-3 is four, the four springs i 4-3 are respectively and fixedly connected to the inner side of the linkage plate i 4-1, the clamping plate i 4-4 is fixedly connected to the inner side of the four springs i 4-3, the transmission block ii 4-6 is fixedly connected to the rear end of the linkage plate ii 4-5, the number of the springs ii 4-7 is four, the four springs II 4-7 are fixedly connected to four corners of the inner side of the linkage plate II 4-5 respectively, the clamping plates II 4-8 are fixedly connected to the inner ends of the four springs II 4-7, the rear ends of the linkage plate I4-1 and the linkage plate II 4-5 are connected into four slideways 2-3 in a sliding mode respectively, and the transmission block I4-2 and the transmission block II 4-6 are in matched transmission connection with two threads 3-3 on the same transmission rod 3-2, wherein the two threads are opposite in rotation direction respectively.

The transmission block I4-2 and the transmission block II 4-6 respectively drive the linkage plate I4-1 and the linkage plate II 4-5 to move relatively, the linkage plate I4-1 drives the four springs I4-3 to move together, the four springs I4-3 drive the clamp plate I4-4 to move, the linkage plate II 4-5 drives the four springs II 4-7 to move, and the four springs II 4-7 drive the clamp plate II 4-8 to move together, so that the two clamp plates I4-4 and the two clamp plates II 4-8 respectively clamp the top ends of the two support columns, and the device is fixed on the top ends of the two support columns.

The sixth specific implementation mode:

this embodiment will be described with reference to fig. 1 to 11, and a second embodiment will be further described with reference to this embodiment, the position adjusting mechanism 5 comprises a position adjusting frame 5-1, a threaded pipe II 5-2, a chute 5-3, an end plate 5-4 and a graduated scale 5-5, the threaded pipe II 5-2 is rotatably connected with the rear end of the positioning frame 5-1, the lower end of the positioning frame 5-1 is provided with a chute 5-3, the end plate 5-4 is fixedly connected to the lower end of the positioning frame 5-1, the graduated scale 5-5 is fixedly connected to the front end of the positioning frame 5-1, the plurality of driving mechanisms II 6 are respectively arranged in the plurality of positioning frames 5-1, the plurality of moving mechanisms 7 are respectively connected to the front ends of the plurality of positioning frames 5-1 in a sliding mode, and the plurality of sliding grooves 5-3 are all connected to the sliding strips 1-2 in a sliding mode.

The plurality of threaded pipes II 5-2 are respectively rotated, the plurality of threaded pipes II 5-2 are connected with the threaded rods I1-3 through thread matching transmission to move on the threaded rods I1-3, the plurality of threaded pipes II 5-2 respectively drive the plurality of positioning frames 5-1 to move together, the plurality of positioning frames 5-1 are respectively moved to the plurality of cross beams of the cross beams to correct and detect positions, and then the plurality of threaded pipes II 5-2 are stopped to rotate.

The seventh embodiment:

the embodiment is described below with reference to fig. 1 to 11, and the sixth embodiment is further described in the present embodiment, where the driving mechanism ii 6 includes a motor ii 6-1 and a threaded rod iii 6-2, the threaded rod iii 6-2 is fixedly connected to a lower end of an output shaft of the motor ii 6-1, the motors ii 6-1 are respectively fixedly connected to upper ends of the end plates 5-4, and the threaded rods iii 6-2 are respectively in transmission connection with the moving mechanisms 7 through thread fit.

The specific implementation mode is eight:

the seventh embodiment is further described with reference to fig. 1 to 11, in which the moving mechanism 7 includes a thread block 7-1, a moving plate 7-2, a through hole 7-3, a gear carrier 7-4 and a sliding hole 7-5, the moving plate 7-2 is fixedly connected to the front end of the thread block 7-1, the middle of the moving plate 7-2 is provided with the through hole 7-3, four corners of the moving plate 7-2 are provided with the sliding holes 7-5, the front end of the through hole 7-3 is provided with the gear carrier 7-4, the thread blocks 7-1 are respectively slidably connected in the positioning frames 5-1, and the thread blocks 7-1 are respectively in transmission connection with the thread rods iii 6-2 through thread fit, the plurality of detection mechanisms 8 are respectively connected in a sliding way in the plurality of through holes 7-3, and the plurality of display mechanisms 9 are respectively fixedly connected on the plurality of gear racks 7-4.

The motors II 6-1 are respectively started, the output shafts of the motors II 6-1 respectively drive the threaded rods III 6-2 to rotate, and the threaded rods III 6-2 are respectively in transmission connection with the threaded blocks 7-1 through thread matching, so that the threaded blocks 7-1 respectively move downwards in the positioning frames 5-1.

The plurality of thread blocks 7-1 drive the plurality of moving plates 7-2 to move downwards respectively, and the plurality of moving plates 7-2 drive the plurality of pressing plates 8-1 to move downwards respectively.

The specific implementation method nine:

the present embodiment is described below with reference to fig. 1 to 11, and the eighth embodiment is further described in the present embodiment, where the detection mechanism 8 includes a pressing plate 8-1, a rack 8-2 and four sliding rods 8-3, the rack 8-2 is fixedly connected to the middle of the pressing plate 8-1, the four sliding rods 8-3 are provided, the four sliding rods 8-3 are respectively and fixedly connected to four corners of the pressing plate 8-1, the rack 8-2 is slidably connected to a certain through hole 7-3, the four sliding rods 8-3 are respectively and slidably connected to four sliding holes 7-5 on the same moving plate 7-2 as the through hole 7-3, and the plurality of racks 8-2 are respectively engaged and drivingly connected to the plurality of display mechanisms 9.

When the plurality of press plates 8-1 are respectively contacted with the upper end of the cross beam, the plurality of press plates 8-1 are limited by the cross beam to stop moving, along with the continuous downward movement of the plurality of moving plates 7-2, the plurality of sliding rods 8-3 respectively move upwards along the plurality of sliding holes 7-5, and simultaneously the plurality of racks 8-2 continuously move upwards along the plurality of through holes 7-3.

The detailed implementation mode is ten:

the present embodiment is described below with reference to fig. 1 to 11, and the present embodiment further describes an embodiment nine, where the display mechanism 9 includes a gear 9-1, a pointer 9-2 and a dial 9-3, the pointer 9-2 is rotatably connected in the dial 9-3, the gear 9-1 and the pointer 9-2 are fixedly connected, a plurality of the gears 9-1 are respectively and fixedly connected to a plurality of gear racks 7-4, a plurality of the gears 9-1 are respectively and meshingly connected to a plurality of gear racks 8-2, and a plurality of the dials 9-3 are respectively and fixedly connected to the left side of the gear racks 7-4.

The plurality of racks 8-2 are connected through meshing transmission to drive the plurality of gears 9-1 to rotate, the plurality of gears 9-1 drive the plurality of pointers 9-2 to rotate on the corresponding plurality of dials 9-3 respectively, when the plurality of moving plates 7-2 move to the lowest ends of the plurality of positioning frames 5-1, longitudinal numerical difference of a plurality of correction detection position points is displayed by contrasting pointer changes of the pointers 9-2 in the dials 9-3, correction detection of the plurality of position points is carried out simultaneously, meanwhile, the positions of the plurality of correction detection points can be adjusted flexibly, and the universality of the equipment is improved.

The invention relates to an assembly type steel structure crossbeam correction and detection device, which has the working principle that:

when the device is used, firstly, two threaded pipes I2-2 are respectively rotated, the two threaded pipes I2-2 are respectively in threaded fit transmission connection with threaded rods II 1-4, the two threaded pipes I2-2 respectively drive two adjusting frames 2-1 to move at the front ends of the bearing frames 1-1, the middle parts of the two bearing frames 1-1 are respectively moved to the rear sides of two adjacent supporting columns, then the two bearing frames 1-1 are respectively attached to the rear sides of the top ends of the two supporting columns, then two motors I3-1 are respectively started, output shafts of the two motors I3-1 respectively drive two transmission rods 3-2 to rotate, the two transmission rods 3-2 respectively drive four threads 3-3 to rotate, and two threads 3-3 on one transmission rod 3-2 are respectively in threaded fit transmission connection with corresponding transmission blocks I4-2 and transmission blocks II 4-6 through threads The driving block I4-2 and the driving block II 4-6 are driven to move relatively, the driving block I4-2 and the driving block II 4-6 respectively drive the linkage plate I4-1 and the linkage plate II 4-5 to move relatively, the linkage plate I4-1 drives the four springs I4-3 to move together, the four springs I4-3 drive the clamp plate I4-4 to move, the linkage plate II 4-5 drives the four springs II 4-7 to move, and the four springs II 4-7 drive the clamp plate II 4-8 to move together, so that the two clamp plates I4-4 and the two clamp plates II 4-8 respectively clamp the top ends of the two supporting columns, and the device is fixed on the top ends of the two supporting columns.

After the operation is finished, the threaded pipes II 5-2 are respectively rotated, the threaded pipes II 5-2 are all connected with the threaded rods I1-3 through thread matching transmission to move on the threaded rods I1-3, the threaded pipes II 5-2 respectively drive the positioning frames 5-1 to move together, and the positioning frames 5-1 are respectively moved to the beam correcting and detecting positions of the beam and then stopped to rotate the threaded pipes II 5-2.

After the operation is finished, the motors II 6-1 are respectively started, the output shafts of the motors II 6-1 respectively drive the threaded rods III 6-2 to rotate, and the threaded rods III 6-2 are respectively in transmission connection with the threaded blocks 7-1 through thread matching, so that the threaded blocks 7-1 respectively move downwards in the positioning frames 5-1.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. The utility model provides a detection device is corrected to assembled steel construction crossbeam, includes actuating mechanism I (3) and actuating mechanism II (6), its characterized in that: the assembled steel structure crossbeam correction and detection device further comprises a bearing mechanism (1), two adjusting mechanisms (2), two clamping mechanisms (4), two positioning mechanisms (5), two moving mechanisms (7), two detection mechanisms (8) and a display mechanism (9), wherein the two adjusting mechanisms (2) are both connected to the front end of the bearing mechanism (1) in a sliding manner, each adjusting mechanism (2) is provided with a driving mechanism I (3), the two clamping mechanisms (4) are respectively connected to the front ends of the two adjusting mechanisms (2) in a sliding manner, the two clamping mechanisms (4) are respectively connected with the two driving mechanisms I (3) in a transmission manner, the positioning mechanisms (5) are provided with a plurality of positioning mechanisms (5), the positioning mechanisms (5) are respectively connected to the upper end of the bearing mechanism (1) in a sliding manner, each positioning mechanism (5) is fixedly connected with a driving mechanism II (6), the moving mechanism (7) is provided with a plurality of, and a plurality of moving mechanism (7) sliding connection respectively are on a plurality of positioning mechanism (5), and a plurality of moving mechanism (7) are connected with a plurality of actuating mechanism II (6) transmission respectively, and the equal sliding connection of lower extreme of every moving mechanism (7) has detection mechanism (8), display mechanism (9) are provided with a plurality ofly, and a plurality of display mechanism (9) set up respectively in the upper end of a plurality of moving mechanism (7), and a plurality of display mechanism (9) are connected with a plurality of detection mechanism (8) transmission respectively.

2. The assembled steel structure beam straightening detection device as claimed in claim 1, wherein: the bearing mechanism (1) comprises a bearing frame (1-1), a slide bar (1-2), a threaded rod I (1-3) and a threaded rod II (1-4), the slide bar (1-2) is fixedly connected to the front side of the upper end of the bearing frame (1-1), the threaded rod I (1-3) is fixedly connected to the rear side of the upper end of the bearing frame (1-1), the threaded rod II (1-4) is fixedly connected to the lower end of the bearing frame (1-1), the two adjusting mechanisms (2) are both connected to the front end of the bearing frame (1-1) in a sliding manner, the two adjusting mechanisms (2) are in transmission connection with the threaded rods II (1-4) through thread matching, the plurality of positioning mechanisms (5) are in sliding connection with the upper ends of the slide bars (1-2), and a plurality of positioning mechanisms (5) are in transmission connection with the threaded rod I (1-3) through thread matching.

3. The assembled steel structure beam straightening detection device as claimed in claim 2, wherein: the adjusting mechanism (2) comprises an adjusting frame (2-1), a threaded pipe I (2-2) and a slideway (2-3), the threaded pipe I (2-2) is rotatably connected to the rear end of the adjusting frame (2-1), four sliding ways (2-3) are arranged, the four sliding ways (2-3) are symmetrically arranged on the adjusting frame (2-1) in pairs, the two adjusting frames (2-1) are connected to the front end of the bearing frame (1-1) in a sliding mode, the two threaded pipes I (2-2) are connected with the threaded rods II (1-4) in a threaded fit transmission mode, the two driving mechanisms I (3) are arranged on the rear side of the adjusting frame (2-1) respectively, and the rear end of each clamping mechanism (4) is connected to the four sliding ways (2-3) on the same adjusting frame (2-1) in a sliding mode.

4. An assembled steel structure beam straightening detection device as claimed in claim 3, wherein: the driving mechanism I (3) comprises a motor I (3-1), a transmission rod (3-2) and threads (3-3), the transmission rod (3-2) is fixedly connected with an output shaft of the motor I (3-1), the transmission rod (3-2) is symmetrically provided with the two threads (3-3) with opposite rotation directions, the transmission rod (3-2) is rotatably connected to the rear end of the adjusting frame (2-1), the motor I (3-1) is fixedly connected to the outer end of the adjusting frame (2-1), and the two clamping mechanisms (4) are respectively in transmission connection with the two transmission rods (3-2) in a thread fit mode.

5. The assembled steel structure beam straightening detection device as claimed in claim 4, wherein: the clamping mechanism (4) comprises a linkage plate I (4-1), a transmission block I (4-2), springs I (4-3), a clamping plate I (4-4), a linkage plate II (4-5), transmission blocks II (4-6), springs II (4-7) and clamping plates II (4-8), wherein the transmission blocks I (4-2) are fixedly connected at the rear end of the linkage plate I (4-1), the number of the springs I (4-3) is four, the four springs I (4-3) are respectively and fixedly connected at the inner side of the linkage plate I (4-1), the clamping plate I (4-4) is fixedly connected at the inner sides of the four springs I (4-3), the transmission blocks II (4-6) are fixedly connected at the rear end of the linkage plate II (4-5), the number of the springs II (4-7) is four, four springs II (4-7) are respectively fixedly connected at four corners of the inner side of the linkage plate II (4-5), the clamping plate II (4-8) is fixedly connected at the inner ends of the four springs II (4-7), the rear ends of the linkage plate I (4-1) and the linkage plate II (4-5) are respectively connected in four slideways (2-3) in a sliding mode, and the transmission block I (4-2) and the transmission block II (4-6) are respectively in matched transmission connection with two threads (3-3) with opposite rotation directions on the same transmission rod (3-2).

6. The assembled steel structure beam straightening detection device as claimed in claim 2, wherein: the position adjusting mechanism (5) comprises a position adjusting frame (5-1), a threaded pipe II (5-2), a sliding chute (5-3), an end plate (5-4) and a graduated scale (5-5), the threaded pipe II (5-2) is rotatably connected to the rear end of the positioning frame (5-1), the lower end of the positioning frame (5-1) is provided with a sliding groove (5-3), the end plate (5-4) is fixedly connected to the upper end of the positioning frame (5-1), the graduated scale (5-5) is fixedly connected to the front end of the positioning frame (5-1), the driving mechanisms II (6) are arranged in the positioning frames (5-1) respectively, the moving mechanisms (7) are connected to the front ends of the positioning frames (5-1) in a sliding mode respectively, and the sliding chutes (5-3) are connected to the sliding strips (1-2) in a sliding mode respectively.

7. The assembled steel structure beam straightening detection device as claimed in claim 6, wherein: the driving mechanism II (6) comprises a motor II (6-1) and a threaded rod III (6-2), the threaded rod III (6-2) is fixedly connected to the lower end of an output shaft of the motor II (6-1), the motors II (6-1) are fixedly connected to the upper ends of the end plates (5-4) respectively, and the threaded rods III (6-2) are connected with the moving mechanisms (7) in a threaded fit transmission mode respectively.

8. The assembled steel structure beam straightening detection device as claimed in claim 7, wherein: the moving mechanism (7) comprises a thread block (7-1), a moving plate (7-2), a through hole (7-3), a gear carrier (7-4) and a sliding hole (7-5), the moving plate (7-2) is fixedly connected to the front end of the thread block (7-1), the middle of the moving plate (7-2) is provided with the through hole (7-3), four corners of the moving plate (7-2) are respectively provided with the sliding hole (7-5), the front end of the through hole (7-3) is provided with the gear carrier (7-4), the thread blocks (7-1) are respectively connected in the positioning frames (5-1) in a sliding manner, and the thread blocks (7-1) are respectively in transmission connection with the threaded rods III (6-2) through thread matching, the detection mechanisms (8) are respectively connected in the through holes (7-3) in a sliding mode, and the display mechanisms (9) are respectively fixedly connected to the gear racks (7-4).

9. The assembled steel structure beam straightening detection device as claimed in claim 8, wherein: the detection mechanism (8) comprises a pressing plate (8-1), racks (8-2) and sliding rods (8-3), the racks (8-2) are fixedly connected to the middle of the pressing plate (8-1), the number of the sliding rods (8-3) is four, the four sliding rods (8-3) are respectively and fixedly connected to four corners of the pressing plate (8-1), the racks (8-2) are slidably connected into a certain through hole (7-3), the four sliding rods (8-3) are respectively and slidably connected into four sliding holes (7-5) in the same moving plate (7-2) with the through hole (7-3), and the racks (8-2) are respectively in meshing transmission connection with the display mechanisms (9).

10. The assembled steel structure beam straightening detection device as claimed in claim 9, wherein: the display mechanism (9) comprises gears (9-1), pointers (9-2) and dials (9-3), the pointers (9-2) are rotatably connected in the dials (9-3), the gears (9-1) and the pointers (9-2) are fixedly connected with a plurality of gears (9-1) respectively and fixedly connected to a plurality of gear carriers (7-4), the gears (9-1) are respectively engaged and in transmission connection with a plurality of racks (8-2), and the dials (9-3) are respectively and fixedly connected to the left sides of the gear carriers (7-4).