CN222389515U - Lifting device for processing large-scale metal structural part - Google Patents

Abstract

The utility model relates to the technical field of large-scale metal structural parts, and discloses a lifting device for processing the large-scale metal structural parts, which comprises two supporting plates, wherein four universal wheels are arranged on the bottom surfaces of the two supporting plates, the top surfaces of the four universal wheels are fixedly connected with the bottom surfaces of the two supporting plates, a supporting frame is arranged above the four supporting plates, a clamping mechanism is arranged on the inner side surface of the supporting frame, a lifting mechanism is arranged on the bottom surface of the supporting frame, the clamping mechanism comprises a fixing part and a clamping part, and the lifting mechanism comprises a driving part and a lifting part. The clamping mechanism drives the first worm through the first motor in the fixing part, the first worm wheel is enabled to rotate, the first gear is driven to rotate under the action of the first worm wheel, the first gear drives the first rack to move, the first rack drives the two L-shaped clamping plates to move, clamping is conducted, shaking is avoided during lifting, stable movement and the like are not achieved, and therefore working efficiency is improved.

Description

Lifting device for processing large-scale metal structural part

Technical Field

The utility model relates to the technical field of large-scale metal structural parts, in particular to a lifting device for processing a large-scale metal structural part.

Background

The metal structural member is a combinable standard workpiece made of metal serving as a raw material, and can be assembled quickly by using a simple installation method. At present, after the metal structural part is machined, the machined metal structural part is often required to be assembled and used, but at present, various lifting devices have single functions.

The utility model discloses a lifting device for processing a large-scale metal structural part, which is disclosed as CN214031598U, and comprises a base, wherein a lifting structure is arranged on the base, the lifting structure comprises a connecting part and a supporting part, the connecting part is arranged between the bases, and the supporting part is arranged on the base.

However, there is a disadvantage in that the apparatus cannot be clamped and fixed during use, so that shaking occurs in the road during lifting, causing drop and the like, thereby reducing work efficiency.

Therefore, a lifting device for processing a large-sized metal structural member is provided.

Disclosure of utility model

The utility model aims to provide a lifting device for processing a large-scale metal structural part, which aims to solve the problems in the background technology.

In order to achieve the purpose, the utility model provides the technical scheme that the lifting device for processing the large-scale metal structural part.

Preferably, the device comprises two support plates, four universal wheels are arranged on the bottom surfaces of the two support plates, the top surfaces of the four universal wheels are fixedly connected with the bottom surfaces of the two support plates, a support frame is arranged above the four support plates, a clamping mechanism is arranged on the inner side surface of the support frame, and a lifting mechanism is arranged on the bottom surface of the support frame;

The clamping mechanism comprises a fixing part and a clamping part;

The clamping part is positioned on the bottom surface of the fixing part;

The lifting mechanism comprises a driving part and a lifting part;

The lifting part is positioned on the front side surface of the driving part.

Preferably, the fixing part comprises two fixing plates, the top surface of the fixing part is fixedly connected with the top surface of the inner side of the supporting frame, the inner side surfaces of the two fixing plates are provided with a first motor, the right side surface of the first motor is fixedly connected with the left side surface of the right side fixing plate, the output end surface of the first motor is provided with a first worm, and the right side surface of the first worm is fixedly connected with the output end surface of the first motor and is electrically powered by the first motor.

Preferably, the first worm left surface is connected with the left side fixed plate right side through bearing frame one in a rotating way, and the outer terminal surface of first worm is provided with first worm wheel, first worm wheel top surface is provided with gear post one, and gear post one top surface is connected with the inboard top surface rotation of support frame through bearing frame two, and first worm wheel bottom surface is provided with first gear, first gear top surface is provided with gear post two, gear post two top surfaces and first worm wheel bottom surface fixed connection, and gear post two bottom surfaces and first gear top surface fixed connection drive first gear through first worm wheel.

Preferably, the clamping part comprises two first racks, the inner side surfaces of the first racks are connected with the outer end surface of the first gear in a meshed mode, the repulsive surfaces of the two first racks are arranged on two fixing blocks, the inner side surfaces of the fixing blocks are fixedly connected with the repulsive surfaces of the two first racks, four sliding seats are arranged on the outer sides of the two fixing blocks, two sliding rails are arranged on the inner side surfaces of the four sliding seats, and the inner side surfaces of the four sliding seats are connected with the surfaces of the two sliding rails in a sliding mode and drive clamping through the first racks.

Preferably, four slide bottom surfaces are provided with two L type grip blocks, two L type grip block top surfaces and four slide bottom surface fixed connection, two L type grip block lateral surface is provided with four slide bars, four slide bar medial surface and two L type grip block lateral surface fixed connection, through L type grip block centre gripping.

Preferably, the four slide bars run through and extend to the support frame outside, and four slide bar lateral surfaces are provided with the stopper, stopper medial surface and four slide bar lateral surface fixed connection, four slide bar surfaces and support frame inner wall sliding connection, through the firm slip of slide bar.

Preferably, the drive part comprises four vertical plates, four vertical plate bottom surfaces are fixedly connected with two support plate top surfaces, two U-shaped plates are arranged on the inner sides of the four vertical plates, two U-shaped plates are fixedly connected with the two support plate top surfaces, two second worm gears are arranged above the U-shaped plates, two second worm gear inner side surfaces are provided with two polished rods, two polished rod surfaces are fixedly connected with two second worm gear inner wall surfaces, and two polished rod outer side surfaces are rotationally connected with the four vertical plate inner side surfaces through bearing seats.

Preferably, the lifting part comprises four second gears, the inner walls of the second gears are fixedly connected with the surfaces of two polished rods, two second worms are arranged on the rear sides of the four second gears, the right sides of the two second worms are rotationally connected with the right sides of the inner sides of the right U-shaped plates through bearing seats, two second motors are arranged on the left sides of the two second worms, the output end faces of the second motors are fixedly connected with the left sides of the two second worms, the bottom faces of the second motors are fixedly connected with the inner sides of the U-shaped plates (512), four second racks are arranged on the outer end faces of the second motors, tooth faces of the four second racks are meshed with the outer end faces of the four second gears, four sliding sleeves are arranged on the outer sides of the four second racks, the inner walls of the four sliding sleeves are in sliding connection with the surfaces of the four second racks, and the top faces of the four second racks are fixedly connected with the bottom faces of the supporting frames and are driven by the second motors.

Compared with the prior art, the lifting device for processing the large-scale metal structural part has the beneficial effects that,

1) The clamping mechanism drives the first worm through the first motor in the fixing part, the first worm wheel is enabled to rotate, the first gear is driven to rotate under the action of the first worm wheel, the first gear drives the first rack to move, the first rack drives the two L-shaped clamping plates to move, and therefore clamping is carried out, shaking is avoided during lifting, stable movement cannot be achieved, and the like, and therefore working efficiency is improved;

2) The second motor in the lifting part is utilized by the lifting mechanism to drive the second worm to rotate, the second worm wheel is driven to rotate when the second worm rotates, the second worm wheel is driven to rotate, the four second gears rotate, the second gears drive to lift, and therefore height adjustment is carried out on different volumes and sizes.

Drawings

FIG. 1 is a schematic perspective view of the structure of the present utility model;

FIG. 2 is a bottom perspective view of the structure of the present utility model;

FIG. 3 is a schematic perspective view of the clamping structure of the present utility model;

FIG. 4 is a top perspective view of the clamping structure of the present utility model;

Fig. 5 is a schematic perspective view of a lifting structure according to the present utility model.

In the figure, a supporting plate 1, a universal wheel 2, a supporting frame 3, a clamping mechanism 4, a fixing part 41, a clamping part 42, a fixing plate 411, a first motor 412, a first worm gear 413, a first worm gear 414, a first gear 415, a first rack 421, a fixed block 422, a 423 sliding seat 424 sliding rails, a 425L-shaped clamping plate 426 sliding rods, a 5 lifting mechanism 51, a driving part 52 lifting part 511 vertical plates 512U-shaped plates 513 second worm gears 514 polished rods 521 second gears 522 second worm gears 523 second motors 524 second racks 525 sliding sleeves 525.

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.

Example 1

Referring to fig. 1-4, the utility model provides a lifting device for processing a large-scale metal structural part, which comprises two support plates 1, wherein four universal wheels 2 are arranged on the bottom surfaces of the two support plates 1, the top surfaces of the four universal wheels 2 are fixedly connected with the bottom surfaces of the two support plates 1, a support frame 3 is arranged above the four support plates 1, a clamping mechanism 4 is arranged on the inner side surface of the support frame 3, and a lifting mechanism 5 is arranged on the bottom surface of the support frame 3;

the clamping mechanism 4 comprises a fixed part 41 and a clamping part 42;

The clamping part 42 is positioned on the bottom surface of the fixing part 41;

the lifting mechanism 5 comprises a driving part 51 and a lifting part 52;

the lifting part 52 is positioned on the front side of the driving part 51.

The fixing portion 41 includes two fixing plates 411 two fixing portions 41 top surface and the inboard top surface fixed connection of support frame 3, two fixing plates 411 medial surface is provided with first motor 412, first motor 412 right flank and right side fixing plate 411 left surface fixed connection, first motor 412 output terminal surface is provided with first worm 413, first worm 413 right flank and first motor 412 output terminal surface fixed connection.

The left side of the first worm 413 is rotationally connected with the right side of the left fixing plate 411 through a first bearing seat, a first worm wheel 414 is arranged on the outer end face of the first worm 413, a first gear column is arranged on the top face of the first worm wheel 414, the top face of the first gear column is rotationally connected with the inner side top face of the support frame 3 through a second bearing seat, the bottom face of the first gear column is fixedly connected with the top face of the first worm wheel 414, a first gear 415 is arranged on the bottom face of the first worm wheel 414, a second gear column is arranged on the top face of the first gear 415, the top face of the second gear column is fixedly connected with the bottom face of the first worm wheel 414, and the bottom face of the second gear column is fixedly connected with the top face of the first gear 415.

The clamping part 42 comprises two first racks 421, two inner sides of the first racks 421 are connected with outer end faces of the first gears 415 in a meshed mode, repulsive faces of the two first racks 421 are arranged on two fixing blocks 422, inner sides of the fixing blocks 422 are fixedly connected with repulsive faces of the two first racks 421, four sliding seats 423 are arranged on outer sides of the two fixing blocks 422, two sliding rails 424 are arranged on inner sides of the four sliding seats 423, and inner sides of the four sliding seats 423 are in sliding connection with surfaces of the two sliding rails 424.

Four slide 423 bottom surface is provided with two L type grip blocks 425, two L type grip blocks 425 top surface and four slide 423 bottom surface fixed connection, two L type grip blocks 425 lateral surface is provided with four slide bars 426, four slide bar 426 medial surface and two L type grip blocks 425 lateral surface fixed connection.

The four sliding rods 426 penetrate and extend to the outer side of the supporting frame 3, limiting blocks are arranged on the outer side faces of the four sliding rods 426, the inner side faces of the limiting blocks are fixedly connected with the outer side faces of the four sliding rods 426, and the surfaces of the four sliding rods 426 are in sliding connection with the inner wall of the supporting frame 3

Further, in this embodiment, by using the first motor 412 in the fixing portion 41 in the clamping mechanism 4, when the first motor 412 rotates, the first worm gear 414 is driven to rotate when the first worm gear 414 rotates, so as to drive the first rack 421 to move when the first worm gear 415 rotates, so that the first rack 421 drives the two L-shaped clamping plates 425 to slide on the surface of the slide rail 424 under the action of the slide seat 423, so that the two L-shaped clamping plates 425 move, and the two slide bars 426 slide stably;

Further, in this embodiment, the clamping mechanism 4 drives the first worm 413 through the first motor 412 in the fixing portion 41 by using the first motor 412, and drives the first worm wheel 414 to rotate through 413, and drives the first gear 415 to rotate under the action of the first worm wheel 414, so that the first gear 415 drives the first rack 421 to move, and the first rack 421 drives the two L-shaped clamping plates 425 to move, so as to clamp, thereby avoiding shaking during lifting, being unable to stably move, and improving working efficiency;

example two

Referring to fig. 1, 2 and 5, on the basis of the first embodiment, it is further obtained that the driving portion 51 includes four risers 511, the bottom surfaces of the four risers 511 are fixedly connected with the top surfaces of the two support plates 1, two U-shaped plates 512 are disposed inside the four risers 511, the bottom surfaces of the two U-shaped plates 512 are fixedly connected with the top surfaces of the two support plates 1, two second worm wheels 513 are disposed above the two U-shaped plates 512, two polish rods 514 are disposed on the inner side surfaces of the two second worm wheels 513, the surfaces of the two polish rods 514 are fixedly connected with the inner walls of the two second worm wheels 513, and the outer side surfaces of the two polish rods 514 are rotatably connected with the inner side surfaces of the four risers 511 through bearing seats three.

The lifting part 52 comprises four second gears 521, the inner walls of the four second gears 521 are fixedly connected with the surfaces of the two polished rods 514, two second worms 522 are arranged at the rear sides of the four second gears 521, the right sides of the two second worms 522 are rotatably connected with the right sides of the inner sides of the right U-shaped plates 512 through bearing seats, two second motors 523 are arranged at the left sides of the two second worms 522, the output end surfaces of the two second motors 523 are fixedly connected with the left sides of the two second worms 522, the bottom surfaces of the two second motors 523 are fixedly connected with the inner sides of the two U-shaped plates (512), four second racks 524 are arranged at the outer end surfaces of the two second motors 523, tooth surfaces of the four second racks 524 are meshed with the outer end surfaces of the four second gears 521, four sliding sleeves 525 are arranged at the outer sides of the four sliding sleeves 524, the inner walls of the four sliding sleeves are slidably connected with the surfaces of the four second racks 524, and the top surfaces of the four second racks 524 are fixedly connected with the bottom surfaces of the supporting frame 3.

Further, in this embodiment, the lifting mechanism 5 drives the second worm 522 to rotate under the action of the second motor 523 by using the second motor 523 in the driving portion 51, so that the second worm wheel 513 rotates, and the second worm wheel 513 drives the polished rod 514 to rotate, so that the polished rod 514 drives the second gear 521 to rotate, and the second gear 521 drives the second rack 524 to perform lifting movement;

Further, in this embodiment, the lifting mechanism 5 uses the second motor 523 in the lifting portion 52 to make the second motor 523 drive the second worm 522 to rotate, and when the second worm 522 rotates, the second worm wheel 513 is driven to rotate, so that the second worm wheel 513 rotates, and the four second gears 521 rotate, so that the second gears 521 drive to lift, thereby performing height adjustment on different volumes and sizes.

When in use, an operator puts the support frame 3 below the support frame through the lifting mechanism 5, the second motor 523 in the driving part 51 is utilized to drive the second worm 522 to rotate under the action of the second motor 523, the second worm wheel 513 is enabled to drive the polished rod 514 to rotate, the polished rod 514 is enabled to drive the second gear 521 to rotate, the second gear 521 is enabled to drive the second rack 524 to lift and move, so that height adjustment is performed, then the clamping mechanism 4 is utilized to utilize the first motor 412 in the fixing part 41, the first worm wheel 414 is driven to rotate when the first worm wheel 414 rotates through the first motor 412, the first rack 421 is driven to move when the first worm wheel 414 rotates, the first rack 421 is driven to slide under the action of the sliding seat 423 on the surface of the sliding rail 424 through the first rack 421, the two L-shaped clamping plates 425 are enabled to move, and the two 426 are enabled to slide firmly.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. The lifting device for processing the large-scale metal structural part comprises two supporting plates (1) and is characterized in that four universal wheels (2) are arranged on the bottom surfaces of the two supporting plates (1), the top surfaces of the four universal wheels (2) are fixedly connected with the bottom surfaces of the two supporting plates (1), a supporting frame (3) is arranged above the four supporting plates (1), a clamping mechanism (4) is arranged on the inner side surface of the supporting frame (3), and a lifting mechanism (5) is arranged on the bottom surface of the supporting frame (3);

The clamping mechanism (4) comprises a fixing part (41) and a clamping part (42);

the clamping part (42) is positioned on the bottom surface of the fixing part (41);

The lifting mechanism (5) comprises a driving part (51) and a lifting part (52);

the lifting part (52) is positioned on the front side surface of the driving part (51);

The fixing parts (41) comprise two fixing plates (411), the top surfaces of the two fixing parts (41) are fixedly connected with the top surface of the inner side of the supporting frame (3), the inner side surfaces of the two fixing plates (411) are provided with first motors (412), the right side surfaces of the first motors (412) are fixedly connected with the left side surfaces of the right side fixing plates (411), the output end surfaces of the first motors (412) are provided with first worms (413), and the right side surfaces of the first worms (413) are fixedly connected with the output end surfaces of the first motors (412);

the left side face of the first worm (413) is rotationally connected with the right side face of the left side fixing plate (411) through a first bearing seat, a first worm wheel (414) is arranged on the outer end face of the first worm (413), a first gear column is arranged on the top face of the first worm wheel (414), the top face of the first gear column is rotationally connected with the top face of the inner side of the support frame (3) through a second bearing seat, the bottom face of the first gear column is fixedly connected with the top face of the first worm wheel (414), a first gear (415) is arranged on the bottom face of the first worm wheel (414), a second gear column is arranged on the top face of the first gear (415), the top face of the second gear column is fixedly connected with the bottom face of the first worm wheel (414), and the bottom face of the second gear column is fixedly connected with the top face of the first gear (415);

clamping part (42) are including two first racks (421), two first racks (421) medial surface is connected with first gear (415) outer terminal surface meshing, and two first racks (421) repel the face setting in two fixed blocks (422), two fixed block (422) medial surface and two first racks (421) repel face fixed connection, two fixed block (422) outside is provided with four slide (423), and four slide (423) medial surface is provided with two slide rail (424), four slide (423) medial surface and two slide rail (424) surface sliding connection.

2. The lifting device for machining of large-scale metal structural parts according to claim 1, wherein two L-shaped clamping plates (425) are arranged on the bottom surfaces of the four sliding seats (423), the top surfaces of the two L-shaped clamping plates (425) are fixedly connected with the bottom surfaces of the four sliding seats (423), four sliding rods (426) are arranged on the outer side surfaces of the two L-shaped clamping plates (425), and the inner side surfaces of the four sliding rods (426) are fixedly connected with the outer side surfaces of the two L-shaped clamping plates (425).

3. The lifting device for machining large-scale metal structural parts of claim 2, wherein four sliding rods (426) penetrate through and extend to the outer side of the supporting frame (3), limiting blocks are arranged on the outer side faces of the four sliding rods (426), the inner side faces of the limiting blocks are fixedly connected with the outer side faces of the four sliding rods (426), and the surfaces of the four sliding rods (426) are in sliding connection with the inner wall of the supporting frame (3).

4. The lifting device for machining large-scale metal structural parts is characterized in that the driving part (51) comprises four vertical plates (511), the bottom surfaces of the four vertical plates (511) are fixedly connected with the top surfaces of the two supporting plates (1), two U-shaped plates (512) are arranged on the inner sides of the four vertical plates (511), the bottom surfaces of the two U-shaped plates (512) are fixedly connected with the top surfaces of the two supporting plates (1), two second worm wheels (513) are arranged above the two U-shaped plates (512), two polished rods (514) are arranged on the inner side surfaces of the two second worm wheels (513), the surfaces of the two polished rods (514) are fixedly connected with the inner side surfaces of the two vertical plates (511) through bearing seats.

5. The lifting device for machining large-scale metal structural parts according to claim 4, wherein the lifting part (52) comprises four second gears (521), the inner walls of the four second gears (521) are fixedly connected with the inner side surfaces of two polished rods (514), two second worms (522) are arranged on the rear sides of the four second gears (521), the right side surfaces of the two second worms (522) are rotatably connected with the inner side right side surfaces of right-side U-shaped plates (512) through bearing seats, two second motors (523) are arranged on the left side surfaces of the two second worms (522), the output end surfaces of the two second motors (523) are fixedly connected with the left side surfaces of the two second worms (522), the bottom surfaces of the two second motors (523) are fixedly connected with the inner side surfaces of the two U-shaped plates (512), four tooth surfaces of the second racks (524) are meshed with the outer end surfaces of the four second gears (521), and four second tooth surfaces (524) are fixedly connected with the outer side surfaces of the four tooth racks (525) of the four sliding sleeves (525), and the outer side surfaces of the four sliding sleeves (525) are fixedly connected with the inner side surfaces of the four sliding sleeves (525).