CN219525107U - Vertical pipe withdrawal machine - Google Patents

Abstract

The utility model relates to the technical field of pipe retreating machines, in particular to a vertical pipe retreating machine, which comprises a carrier, wherein a loading shell is arranged above the carrier, a first motor is embedded in the loading shell, the power output end of the first motor is connected with a worm, one side of the worm is provided with a worm wheel, a rotating rod penetrates out of the worm wheel, and a rubber wheel is sleeved on one side of the outer wall of the rotating rod. The loading shell is supported by the supporting frame, the worm is driven to rotate through the operation of the first motor, so that the worm wheel is driven to rotate the rotating rod, the rotating rod drives the rubber wheels to rotate, a plurality of groups of rubber wheels are arranged along the supporting plate, the pipeline is convenient to convey, manual pulling is avoided, the pipeline is damaged when the labor intensity is excessive, the electric push rod is fixed on the supporting plate through the mounting plate, the arc-shaped plate is pushed to be attached to and pressed against the pipeline through the electric push rod, and the influence caused by excessive shaking in the process of conveying and withdrawing the pipeline is avoided.

Description

Vertical pipe withdrawal machine

Technical Field

The utility model relates to the technical field of pipe retreating machines, in particular to a vertical pipe retreating machine.

Background

In some pipeline processing processes, the pipeline needs to be pulled down from the processing table surface so as to be separated from the processing table and enter the next working procedure for processing, so that the pipeline can be transported and driven by the pipeline withdrawing machine.

The automatic heat shrinkage tube withdrawing machine with the publication number of CN205148893U comprises: the device comprises a frame, a main shaft, a concave wheel, a convex wheel, an adjustable pressing device and a motor; the main shaft install in the frame, concave type wheel install in on the main shaft, protruding type wheel is located concave type wheel top is installed in adjustable closing device is last, adjustable closing device install in the frame, the motor with the main shaft transmission is connected. The automatic pipe withdrawing machine for the heat-shrinkable pipe can realize automatic pipe withdrawing, is simple to operate and high in pipe withdrawing speed, and can regulate the pipe withdrawing speed according to the requirement. In addition, the automatic heat-shrinkable tube withdrawing machine can simultaneously withdraw a plurality of heat-shrinkable tubes, saves manpower and material resources and improves the production and processing efficiency of the heat-shrinkable tubes.

In summary, the following technical problems exist in the prior art: when the processing pipeline is transported from the processing table, the labor intensity is high by manual pulling, and meanwhile, the pipeline which is processed is easy to damage, so that the vertical pipe-withdrawing machine is provided.

Disclosure of Invention

The utility model aims to provide a vertical pipe-withdrawing machine, which solves the problems in the prior art.

In order to solve the technical problems, the utility model adopts the following technical scheme:

the utility model provides a vertical pipe machine that moves back, includes the support carrier, the top of support carrier is provided with and loads the shell, and loads the inside of shell and inlay and be equipped with first motor, the power take off end of first motor is connected with the worm, and one side of worm is provided with the worm wheel, the inside of worm wheel wears out there is the dwang, and the outer wall one side cover of dwang is equipped with the rubber wheel, the top of dwang is provided with the backup pad, and the top of backup pad is connected with the mounting panel, the axial of mounting panel inlays and is equipped with electric putter, and electric putter's power take off end is connected with the arc.

Preferably, the rubber wheel forms a rotating structure through the rotating rod and the worm wheel, and the rotating rod is fixedly connected with the worm wheel.

Preferably, the arc plate forms a telescopic structure between the electric push rod and the supporting carrier, and the electric push rod is fixedly connected with the mounting plate.

Preferably, the bottom end of the support carrier is fixed with a rotating block, a supporting frame is sleeved outside the rotating block, a second motor is embedded in the outer wall of the supporting frame, a driving shaft is connected to the power output end of the second motor, a third motor is embedded in the outer wall of the support carrier, a sliding groove is formed in the top end of the support carrier, a bidirectional threaded rod is connected to the power output end of the third motor, and a sliding block is sleeved outside the bidirectional threaded rod.

Preferably, the driving shaft is welded with the rotating block, and the rotating block forms a rotating structure with the second motor through the driving shaft.

Preferably, the bidirectional threaded rod is in threaded connection with the sliding block, and the sliding block is fixedly connected with the loading shell.

Preferably, the loading shell forms a sliding structure through the sliding block and the sliding groove, and the sliding block forms a sliding structure through the sliding groove and the supporting frame.

The above description shows that the technical problems to be solved by the present utility model can be solved by the above technical solutions of the present utility model.

Meanwhile, through the technical scheme, the utility model has at least the following beneficial effects:

the loading shell is supported by the supporting frame, the worm is driven to rotate through the operation of the first motor, so that the worm wheel is driven to rotate the rotating rod, the rotating rod drives the rubber wheels to rotate, a plurality of groups of rubber wheels are arranged along the supporting plate, the pipeline is convenient to convey, manual pulling is avoided, the pipeline is damaged when the labor intensity is excessive, the electric push rod is fixed on the supporting plate through the mounting plate, the arc-shaped plate is pushed to be attached to and pressed against the pipeline through the electric push rod, and the influence caused by excessive shaking in the process of conveying and withdrawing the pipeline is avoided.

The driving shaft is driven to rotate by the second motor, so that the rotating block is driven to conveniently drive the carrying frame to rotate, and the carrying frame is superposed with the supporting frame, so that a vertical form is formed, the carrying frame is convenient to place, and the waste of the area caused by overlarge occupied area in the non-use process is avoided.

According to the utility model, the third motor works to drive the bidirectional threaded rod to rotate, the bidirectional threaded rod penetrates through the sliding block welded at the bottom end of the loading shell, so that the sliding block is conveniently driven to stably slide on the carrier along the sliding groove, the two groups of loading shells are relatively moved, the rubber wheels are conveniently used for clamping the pipeline, and the applicability is improved by adjusting according to the size of the pipeline.

Drawings

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

FIG. 2 is a schematic cross-sectional view of the present utility model;

FIG. 3 is a schematic view of the structure of the driving shaft of the present utility model;

fig. 4 is a schematic view of the structure of the bidirectional threaded rod of the present utility model.

In the figure: 1. a carrier; 2. loading a shell; 3. a first motor; 4. a worm; 5. a worm wheel; 6. a rotating lever; 7. a rubber wheel; 8. a support plate; 9. a mounting plate; 10. an electric push rod; 11. an arc-shaped plate; 12. a rotating block; 13. a support frame; 14. a second motor; 15. a drive shaft; 16. a third motor; 17. a two-way threaded rod; 18. a slide block; 19. and a sliding groove.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Description of the preferred embodiments

As shown in fig. 1, 2 and 3, the present utility model provides a technical solution: the utility model provides a vertical pipe machine that moves back, including holding in the palm carrier 1, the top of holding in the palm carrier 1 is provided with and loads shell 2, the inside of loading shell 2 is inlayed and is equipped with first motor 3, the power take off end of first motor 3 is connected with worm 4, one side of worm 4 is provided with worm wheel 5, the inside of worm wheel 5 wears out and has dwang 6, the outer wall one side cover of dwang 6 is equipped with rubber wheel 7, the top of dwang 6 is provided with backup pad 8, the top of backup pad 8 is connected with mounting panel 9, the axial of mounting panel 9 is inlayed and is equipped with electric putter 10, electric putter 10's power take off end is connected with arc 11, constitute revolution mechanic between dwang 6 and the worm wheel 5 fixed connection, arc 11 constitutes telescopic structure through electric putter 10 and holding in the carrier 1, electric putter 10 and mounting panel 9 fixed connection, it supports through holding in the carrier 1 to load shell 2, work through first motor 3 drive worm 4, thereby drive 5 makes dwang 6 rotate, dwang 6 drive rubber wheel 7 and rotate, set up along 8, be convenient for carry out the pipeline transportation pipeline to push down the pipeline 10, avoid the manual work to pull down the impact on the pipeline 10 to the mounting panel through the mounting panel, avoid the manual work to move back the pipeline to the impact on the arc 10 to the pipeline is greatly and is avoided moving back in the pipeline 10 to the pipeline is moved and is greatly to the pipeline is moved and the pipeline is avoided.

Example two

The scheme in the first embodiment is further described below in conjunction with a specific working manner, and the details are described below:

as shown in fig. 1, fig. 2 and fig. 3, as a preferred embodiment, on the basis of the above manner, further, a rotating block 12 is fixed at the bottom end of the carrier 1, a supporting frame 13 is sleeved outside the rotating block 12, a second motor 14 is embedded in the outer wall of the supporting frame 13, a driving shaft 15 is connected to the power output end of the second motor 14, the driving shaft 15 is welded with the rotating block 12, the rotating block 12 forms a rotating structure with the second motor 14 through the driving shaft 15, and the driving shaft 15 is driven to rotate through the operation of the second motor 14, so that the rotating block 12 is driven to be convenient to drive the carrier 1 to rotate, and is in superposition with the supporting frame 13 to form a vertical form, so that the carrier is convenient to place and the waste of the area caused by overlarge occupied area in the non-use process is avoided.

As shown in fig. 1, fig. 2 and fig. 4, as a preferred embodiment, further, on the basis of the above manner, the outer wall of the carrier 1 is embedded with the third motor 16, the top end of the carrier 1 is provided with the sliding groove 19, the power output end of the third motor 16 is connected with the bidirectional threaded rod 17, the outside of the bidirectional threaded rod 17 is sleeved with the sliding block 18, the bidirectional threaded rod 17 is in threaded connection with the sliding block 18, the sliding block 18 is fixedly connected with the loading shell 2, the loading shell 2 forms a sliding structure with the sliding groove 19 through the sliding block 18, the sliding block 18 forms a sliding structure with the carrier 1 through the sliding groove 19, the bidirectional threaded rod 17 is driven to rotate by the operation of the third motor 16, and penetrates through the sliding block 18 welded at the bottom end of the loading shell 2, so as to be convenient for driving the sliding block 18 to stably slide on the carrier 1 along the sliding groove 19, thereby enabling the two groups of loading shells 2 to relatively move, facilitating the clamping of the pipe 7, and improving the applicability according to the size of the pipe.

From the above, it can be seen that:

the utility model aims at the technical problems that: when the processing pipeline is transported from the processing table, the labor intensity is high due to manual pulling, and meanwhile, the pipeline which is processed is easy to damage; the technical scheme of each embodiment is adopted. Meanwhile, the implementation process of the technical scheme is as follows:

the first motor 3 is embedded in the loading shell 2 above the carrier 1, the worm 4 is driven by the first motor 3 to drive the worm wheel 5 to rotate, the worm wheel 5 drives the rotating rod 6 to rotate, the rubber wheels 7 are sleeved outside the rotating rod 6 to rotate along with the worm wheel 5, multiple groups of rubber wheels 7 are arranged to facilitate driving the pipeline to move to withdraw pipes from the processing table, damage caused by manual dragging is avoided, bearings sleeved at the bottom end of the rotating rod 6 are embedded in the loading shell 2, axial embedded in the supporting plate 8 are sleeved at the top end of the supporting plate, the rotating rod 6 is convenient to stably rotate, the supporting plate 8 is embedded with the electric push rod 10 through the mounting plate 9 fixed by bolts, the arc-shaped plate 11 is driven by the electric push rod 10 to be attached to the pipeline, the pipeline is prevented from shaking up and down to affect transmission, the rotating block 12 at the bottom of the carrier 1 penetrates into the supporting frame 13, the second motor 14 embedded at the outer wall of the supporting frame 13 drives the driving shaft 15 to rotate, the driving shaft 15 penetrates through the rotating block 12 and is fixed, the carrier 1 angle is convenient to be adjusted, the space is convenient to be vertically arranged, the other end of the driving shaft 15 is embedded in the inner wall of the supporting frame 13 through the bolts, the driving shaft 15 is convenient to stably rotate, the third motor 16 embedded at the outer wall of the supporting frame 1 is embedded at the supporting plate 8 through the bolts, the driving shaft 17 is driven by the bolts, the driving shaft 17 penetrates through the threaded rod 17, the supporting shafts 18 is convenient to move along the two-way 18, and the sliding blocks are not connected with the supporting frame 1, and the two-way slide frame 18 is convenient to move along the sliding frame 18, and is suitable for the two-way to move along the sliding frame 1, and can move along the two-way, and can move along the sliding frame 18, and move along the sliding frame and can be conveniently, and move along the sliding frame and move.

Through the arrangement, the utility model can solve the technical problems, and simultaneously realize the following technical effects:

the second motor 14 works to drive the driving shaft 15 to rotate, so that the rotating block 12 is driven to conveniently drive the carrying frame 1 to rotate, and the carrying frame is overlapped with the supporting frame 13 to form a vertical form, so that the carrying frame is convenient to place and the waste of the area caused by overlarge occupied area in the non-use process is avoided;

the utility model drives the bidirectional threaded rod 17 to rotate through the operation of the third motor 16, and the bidirectional threaded rod 17 penetrates through the sliding block 18 welded at the bottom end of the loading shell 2, so that the sliding block 18 is conveniently driven to stably slide on the supporting frame 1 along the sliding groove 19, thereby enabling the two groups of loading shells 2 to relatively move, facilitating the clamping of the pipeline by the rubber wheel 7, and improving the applicability according to the adjustment of the size of the pipeline.

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 (7)

1. The utility model provides a vertical pipe machine that moves back, its characterized in that, including holding in the palm carrier (1), the top of holding in the palm carrier (1) is provided with and loads shell (2), and the inside of loading shell (2) is inlayed and is equipped with first motor (3), the power take off end of first motor (3) is connected with worm (4), and one side of worm (4) is provided with worm wheel (5), the inside of worm wheel (5) is worn out has dwang (6), and the outer wall one side cover of dwang (6) is equipped with rubber wheel (7), the top of dwang (6) is provided with backup pad (8), and the top of backup pad (8) is connected with mounting panel (9), the axial of mounting panel (9) is inlayed and is equipped with electric putter (10), and the power take off end of electric putter (10) is connected with arc (11).

2. The vertical pipe-returning machine according to claim 1, wherein the rubber wheel (7) forms a rotating structure between the rotating rod (6) and the worm wheel (5), and the rotating rod (6) is fixedly connected with the worm wheel (5).

3. The vertical pipe withdrawal machine according to claim 1, characterized in that the arc plate (11) forms a telescopic structure between the electric push rod (10) and the supporting frame (1), and the electric push rod (10) is fixedly connected with the mounting plate (9).

4. The vertical pipe withdrawal machine according to claim 1, characterized in that a rotating block (12) is fixed at the bottom end of the supporting frame (1), a supporting frame (13) is sleeved outside the rotating block (12), a second motor (14) is embedded on the outer wall of the supporting frame (13), a driving shaft (15) is connected with the power output end of the second motor (14), a third motor (16) is embedded on the outer wall of the supporting frame (1), a sliding groove (19) is formed in the top end of the supporting frame (1), a bidirectional threaded rod (17) is connected to the power output end of the third motor (16), and a sliding block (18) is sleeved outside the bidirectional threaded rod (17).

5. A vertical tube drawing machine according to claim 4, characterized in that the drive shaft (15) is welded to the rotating block (12), and that the rotating block (12) is arranged in a rotating configuration between the drive shaft (15) and the second motor (14).

6. A vertical tube drawing machine according to claim 4, characterized in that the bi-directional threaded rod (17) is in threaded connection with the slider (18), and the slider (18) is fixedly connected with the loading shell (2).

7. A vertical tube drawing machine according to claim 4, characterized in that the loading shell (2) forms a sliding structure between the sliding block (18) and the sliding groove (19), and the sliding block (18) forms a sliding structure between the sliding groove (19) and the supporting frame (1).