CN221696730U - Dynamic equipment mounting platform capable of reducing labor intensity - Google Patents

Abstract

A platform for installing a moving equipment with reduced labor intensity comprises a bottom plate and a slider, the slider is provided with a moving equipment installing structure with reduced labor intensity, the moving equipment installing structure with reduced labor intensity comprises a first shell, the inner wall of the first shell is fixedly connected to a first motor through a bracket, the second cross bar is fixedly connected to the inner wall of the first shell, the upper end of the straight rod is movably connected to a clamping plate through a pin shaft, the two clamping plates respectively penetrate the first shell and are slidably connected to a slideway processed on the first shell, through the cooperation of the moving equipment installing structure with reduced labor intensity and a soft pad, the first motor starts to drive the threaded rod to rotate, the rotation of the threaded rod drives the threaded seat to move downward, and at the same time drives the first cross bar to move downward, driving the connecting rods on both sides to swing relative to each other, and the workpiece is clamped and fixed by the soft pads on both sides, avoiding the use of manual clamping and fixing of the position of the workpiece, thereby reducing manual labor.

Description

A platform for installing moving equipment with reduced labor intensity

Technical Field

The utility model relates to the technical field of equipment installation platforms, in particular to a moving equipment installation platform with reduced labor intensity.

Background Art

Reducing labor intensity Rapid maintenance of mobile equipment installation platforms is a common demand in large ports, transportation hubs, substations and other places, and rapid maintenance depends on maintenance equipment.

For example, the authorization announcement number "CN213446112U" is named a high-stability equipment installation platform. The high-stability equipment installation platform in the utility model can provide a stable equipment installation platform for maintenance personnel to install maintenance equipment, and the equipment installation platform has a shock-absorbing structure, which can still maintain high stability in an unstable environment; at the same time, a portable level detector is provided on the equipment installation platform, which can be used to observe the level and can be taken down for use, thereby improving the work efficiency of maintenance personnel. However, when the high-stability equipment installation platform is used to install and process the workpiece, it is necessary to first fix the position of the workpiece before performing subsequent production installation and processing work. The equipment uses manual clamping to fix the position of the workpiece, which increases the labor force. At the same time, when the high-stability equipment installation platform is used for installation work, it is also necessary to adjust the installation and processing position of the workpiece. The equipment uses the screw to rotate to drive the equipment to adjust the installation and processing position. Since the weight carried on the screw is large, the screw will become loose due to long-term connection, affecting the subsequent installation and processing work.

Summary of the invention

The utility model aims to solve the problems existing in the prior art that the device utilizes manual labor to clamp and fix the position of the workpiece, which increases the manual labor and the heavy weight borne on the lead screw may cause the lead screw to loosen due to long-term connection, thus affecting subsequent installation and processing work. The utility model provides a dynamic equipment installation platform that reduces labor intensity, avoids the use of manual labor to clamp and fix the position of the workpiece, reduces manual labor and avoids the use of the lead screw to adjust the installation and processing position, which will not affect subsequent installation and processing work.

The utility model adopts a technical solution to solve its technical problems: this labor-intensity reducing dynamic equipment installation platform comprises a bottom plate and a slider, the slider is provided with a labor-intensity reducing dynamic equipment installation structure, the labor-intensity reducing dynamic equipment installation structure comprises a first shell, the inner wall of the first shell is fixedly connected to a first motor through a bracket, the output shaft of the first motor is fixedly connected to a threaded rod through a reducer, the surface of the threaded rod is meshed and connected with the inner wall of the threaded seat, the upper end of the threaded seat is rotatably connected to the lower surface of the first cross bar through a bearing, both sides of the first cross bar are movably connected to the connecting rod through a pin shaft, the connecting rod is movably connected to the surface of the straight rod through a pin shaft, the lower end of the straight rod is movably connected to the second cross bar through a pin shaft, the second cross bar is fixedly connected to the inner wall of the first shell, the upper end of the straight rod is movably connected to a splint through a pin shaft, and the two splints respectively penetrate the first shell and are slidably connected to a slideway processed on the first shell.

For further improvement, the lower surface of the first shell is fixedly connected to the upper surface of the slider, and the lower surface of the slider is slidably connected to a slideway processed on the upper surface of the top plate.

For further improvement, an adjustment structure is provided on the bottom plate, and the adjustment structure includes a second shell, the inner wall of the second shell is fixedly connected to the second motor through a bracket, the output shaft of the second motor is fixedly connected to a gear through a reducer, the gear is meshingly connected to the rack, the surface of the rack is fixedly connected to a first limit rod, the first limit rod is slidably connected to a slideway processed on the inner wall of the second shell, the lower end of the rack is fixedly connected to a vertical plate, the slide groove processed on the vertical plate is slidably connected to the cylinder protruding from the long rod, the surface of the long rod is fixedly connected to a second limit rod, the second limit rod is slidably connected to the slideway processed on the inner wall of the second shell, and the long rod passes through the second shell and is socketed with the second shell.

For further improvement, the lower surface of the second shell is fixedly connected to the upper surface of the base plate, and the upper surface of the first shell is fixedly connected to a workbench.

For further improvement, one end of the long rod is fixedly connected to a square plate, and the surface of the square plate is fixedly connected to the surface of the slider.

For further improvement, both surfaces of the two clamping plates are fixedly connected with soft pads, and the lower surface of the top plate is fixedly connected with the upper surface of the bottom plate.

The beneficial effects of the utility model are as follows: the utility model reduces the labor intensity by cooperating with the equipment installation structure and the soft pad. The first motor starts to drive the threaded rod to rotate, and the rotation of the threaded rod drives the threaded seat to move downward, and at the same time drives the first cross bar to move downward, drives the connecting rods on both sides to swing relatively, and at the same time drives the straight rods on both sides to swing relatively on the second cross bars on both sides, drives the clamping plates on both sides to slide relatively on the slideways processed on the first shell, and clamps the workpiece by the soft pads on both sides, avoids the use of manual clamping to fix the position of the workpiece, and reduces the labor force;

Through the cooperation of the adjustment structure and the slider, the second motor starts and drives the gear to rotate. The rotation of the gear drives the rack to move downward, and at the same time drives the first limit rod to slide downward on the slide processed on the inner wall of the second shell, drives the vertical plate to move downward, and drives the long rod to move left in the second shell through the slide groove processed on the vertical plate, and at the same time drives the second limit rod to slide left on the slide processed on the inner wall of the second shell. The long rod moves to the left and drives the square plate to move to the left, drives the slider to slide to the left on the slide processed on the upper surface of the top plate, and drives the workpiece to move to the left, adjusts the installation and processing position, avoids using the lead screw to adjust the installation and processing position, and will not affect the subsequent installation and processing work.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a schematic diagram of the structure of the utility model;

FIG2 is a front cross-sectional view of FIG1 ;

FIG3 is a front cross-sectional view of the installation structure of the moving equipment with reduced labor intensity in FIG1 ;

FIG4 is a front cross-sectional view of the adjustment structure in FIG1 ;

FIG. 5 is a schematic diagram of part A in FIG. 2 .

Explanation of the accompanying drawings: 1. Base plate, 2. Adjustment structure, 201. Second shell, 202. First limit rod, 203. Second motor, 204. Gear, 205. Long rod, 206. Vertical plate, 207. Second limit rod, 208. Rack, 3. Square plate, 4. Structure for reducing labor intensity of moving equipment installation, 401. First shell, 402. First cross bar, 403. Connecting rod, 404. Clamp, 405. Straight rod, 406. Second cross bar, 407. Threaded rod, 408. First motor, 409. Threaded seat, 5. Slider, 6. Top plate, 7. Cushion, 8. Workbench.

DETAILED DESCRIPTION

The utility model is further described below in conjunction with the accompanying drawings:

Referring to Figures 1-5: In this embodiment,

A labor intensity reducing moving equipment installation platform comprises a bottom plate 1 and a slider 5, a labor intensity reducing moving equipment installation structure 4 is arranged on the slider 5, and the labor intensity reducing moving equipment installation structure 4 comprises a first shell 401, the inner wall of the first shell 401 is fixedly connected with a first motor 408 through a bracket, the first motor 408 can meet the working needs according to actual needs, the output shaft of the first motor 408 is fixedly connected with a threaded rod 407 through a reducer, the first motor 408 can drive the threaded rod 407 to rotate when started, the surface of the threaded rod 407 is meshed with the inner wall of a threaded seat 409, the rotation of the threaded rod 407 can drive the threaded seat 409 to move up and down, the upper end of the threaded seat 409 is rotatably connected with the lower surface of the first cross bar 402 through a bearing, and the up and down movement of the threaded seat 409 can drive the first cross bar 402 to rotate. A cross bar 402 moves up and down, and both sides of the first cross bar 402 are movably connected to the connecting rod 403 through a pin shaft. The up and down movement of the first cross bar 402 can drive the connecting rods 403 on both sides to swing. The connecting rod 403 is movably connected to the surface of the straight rod 405 through the pin shaft. The lower end of the straight rod 405 is movably connected to the second cross bar 406 through the pin shaft. The swing of the connecting rod 403 can drive the straight rod 405 to swing left and right on the second cross bar 406. The second cross bar 406 is fixedly connected to the inner wall of the first shell 401, and the upper end of the straight rod 405 is movably connected to the splint 404 through the pin shaft. The two splints 404 respectively penetrate the first shell 401 and are slidably connected to the slideway processed on the first shell 401. The left and right swing of the straight rod 405 can drive the splint 404 to slide left and right on the slideway processed on the first shell 401.

Referring to Figures 1-2 and 4:

An adjustment structure 2 is provided on the bottom plate 1, and the adjustment structure 2 includes a second shell 201, and the inner wall of the second shell 201 is fixedly connected to a second motor 203 through a bracket. The second motor 203 can meet the working needs according to actual needs. The output shaft of the second motor 203 is fixedly connected to a gear 204 through a reducer. When the second motor 203 is started, the gear 204 can be driven to rotate. The gear 204 is meshed and connected with a rack 208. The rotation of the gear 204 can drive the rack 208 to move up and down. A first limiting rod 202 is fixedly connected to the surface of the rack 208. The first limiting rod 202 is slidably connected to a slideway processed on the inner wall of the second shell 201. The rack 208 can drive the first limiting rod 202 to move up and down. It slides up and down on the slideway processed on the inner wall of the second shell 201, and the lower end of the rack 208 is fixedly connected to the vertical plate 206. The up and down movement of the rack 208 can drive the vertical plate 206 to move up and down. The slide groove processed on the vertical plate 206 is slidably connected to the protruding cylinder on the long rod 205. The up and down movement of the vertical plate 206 can drive the long rod 205 to move left and right. A second limiting rod 207 is fixedly connected to the surface of the long rod 205, and the second limiting rod 207 is slidably connected to the slideway processed on the inner wall of the second shell 201. The left and right movement of the long rod 205 can drive the second limiting rod 207 to slide left and right on the slideway processed on the inner wall of the second shell 201, and the long rod 205 penetrates the second shell 201 and is socketed with the second shell 201.

Referring to Figures 1-2 and 5:

The lower surface of the first shell 401 is fixedly connected to the upper surface of the slider 5 to fix the position of the first shell 401. The lower surface of the slider 5 is slidably connected to the slideway processed on the upper surface of the top plate 6. The slider 5 can slide left and right on the slideway processed on the upper surface of the top plate 6. The lower surface of the second shell 201 is fixedly connected to the upper surface of the bottom plate 1 to fix the position of the second shell 201. The upper surface of the first shell 401 is fixedly connected with a workbench 8. One end of the long rod 205 is fixedly connected to the square plate 3. The left and right movement of the long rod 205 can drive the square plate 3 to move left and right. The surface of the square plate 3 is fixedly connected to the surface of the slider 5. The surfaces of the two clamping plates 404 are fixedly connected with soft pads 7. The lower surface of the top plate 6 is fixedly connected to the upper surface of the bottom plate 1 to fix the position of the top plate 6.

Working principle:

When using a dynamic equipment installation platform that reduces labor intensity, the workpiece that needs to be installed and processed is placed on the workbench 8, and then the external power supply of the first motor 408 is turned on. The first motor 408 starts to drive the threaded rod 407 to rotate, and the rotation of the threaded rod 407 drives the threaded seat 409 to move downward, and at the same time drives the first cross bar 402 to move downward, driving the connecting rods 403 on both sides to swing relative to each other, and at the same time drives the straight rods 405 on both sides to swing relative to each other on the second cross bars 406 on both sides, respectively, and drives the clamps 404 on both sides to slide relatively on the slides processed on the first shell 401, and the workpiece is clamped and fixed by the soft pads 7 on both sides, reducing manual labor, and then the external power supply of the second motor 203 is turned on, and the second motor 203 is turned on. The machine 203 is started and drives the gear 204 to rotate. The rotation of the gear 204 drives the rack 208 to move downward, and at the same time drives the first limiting rod 202 to slide downward on the slide processed on the inner wall of the second shell 201, drives the vertical plate 206 to move downward, and drives the long rod 205 to move left in the second shell 201 through the slide groove processed on the vertical plate 206, and at the same time drives the second limiting rod 207 to slide left on the slide processed on the inner wall of the second shell 201. The long rod 205 moves to the left and drives the square plate 3 to move to the left, drives the slider 5 to slide to the left on the slide processed on the upper surface of the top plate 6, and drives the workpiece to move to the left, adjusts the installation and processing position, and completes the workpiece installation, clamping and adjustment work of the dynamic equipment installation platform with reduced labor intensity.

Although the present invention has been shown and described with reference to the preferred embodiments, it will be understood by those skilled in the art that various changes in form and details may be made therein within the scope of the claims.

Claims (6)

1. The utility model provides a reduce intensity of labour and move equipment mounting platform, includes bottom plate (1) and slider (5), characterized by: be equipped with on slider (5) and reduce intensity of labour and move equipment mounting structure (4), reduce intensity of labour and move equipment mounting structure (4) and include first shell (401), first shell (401) inner wall is through support fixedly connected with first motor (408), first motor (408) output shaft is through reduction gear fixedly connected with threaded rod (407), threaded rod (407) surface and screw seat (409) inner wall meshing are connected, screw seat (409) upper end is through bearing and first horizontal pole (402) lower surface rotation connection, the both sides of first horizontal pole (402) are all through round pin axle and connecting rod (403) swing joint, connecting rod (403) are through round pin axle and straight-bar (405) surface swing joint, straight-bar (405) lower extreme is through round pin axle and second horizontal pole (406) swing joint, second horizontal pole (406) and first shell (401) inner wall fixedly connected with, straight-bar (405) upper end is through round pin axle and splint (404) swing joint, two splint (404) run through slide processing on first shell (401) and first shell (401) respectively.

2. The labor-reducing mobile device mounting platform of claim 1, wherein: the lower surface of the first shell (401) is fixedly connected with the upper surface of the sliding block (5), and the lower surface of the sliding block (5) is in sliding connection with a slideway machined on the upper surface of the top plate (6).

3. The labor-reducing mobile device mounting platform of claim 1, wherein: be equipped with regulation structure (2) on bottom plate (1), regulation structure (2) include second shell (201), second shell (201) inner wall is through support fixedly connected with second motor (203), second motor (203) output shaft is through reduction gear fixedly connected with gear (204), gear (204) are connected with rack (208) meshing, rack (208) fixed surface is connected with first gag lever post (202), slide sliding connection of first gag lever post (202) and second shell (201) inner wall processing, rack (208) lower extreme fixedly connected with riser (206), protruding cylinder sliding connection on spout and stock (205) of processing on riser (206), stock (205) fixed surface is connected with second gag lever post (207), second gag lever post (207) are cup jointed with second shell (201) inner wall processing's slide sliding connection, stock (205) run through second shell (201) and second shell (201) mutually.

4. A labor intensity reducing mobile device mounting platform according to claim 3, wherein: the lower surface of the second shell (201) is fixedly connected with the upper surface of the bottom plate (1), and the upper surface of the first shell (401) is fixedly connected with a workbench (8).

5. A labor intensity reducing mobile device mounting platform according to claim 3, wherein: one end of the long rod (205) is fixedly connected with a square plate (3), and the surface of the square plate (3) is fixedly connected with the surface of the sliding block (5).

6. The labor-reducing mobile equipment mounting platform of claim 2, wherein: the surfaces of the two clamping plates (404) are fixedly connected with soft cushions (7), and the lower surface of the top plate (6) is fixedly connected with the upper surface of the bottom plate (1).