CN112010121A - Cable laying system with adjustable rolling radius for power engineering - Google Patents

Abstract

The invention discloses a winding radius adjustable cable laying system for an electric power project, which comprises a first transverse plate and wheels, wherein a plurality of wheels are fixedly connected below the first transverse plate, and a collecting device is arranged above the first transverse plate. This cable laying system for power engineering, through the riser, mutually support between running roller and the cable isotructure, can remove this device to the place that needs laid the cable through the wheel, thereby the labour has been practiced thrift, through first motor, mutually support between second helical gear running roller and the cable isotructure, can drive the second helical gear through first motor and rotate, the second helical gear drives first helical gear and rotates, first helical gear drives the running roller and rotates, thereby can carry out the unwrapping wire work of cable, through arc tooth board, first connecting rod, mutually support between second connecting rod and the lantern ring isotructure, can make the cable carry out even winding, the going on of cable laying work has been made things convenient for.

Description

Cable laying system with adjustable rolling radius for power engineering

Technical Field

The invention relates to the technical field of power engineering, in particular to a winding radius adjustable cable laying system for power engineering.

Background

Electric power engineering, i.e. engineering related to the production, transmission and distribution of electric energy, also broadly includes engineering of applying electricity as power and energy in various fields, as a form of energy, electric energy has many advantages of easy conversion, convenient transportation, easy control, convenient use, cleanness, economy and the like, since the 80 th 19 th century, electric power has gradually replaced a steam engine which is the technical basis of 18 th century industrial revolution, and has become the technical basis of human material culture and mental culture in modern society, usually, electric power is transmitted and transported through a pad, which needs to be laid with cables, most of the prior art is transported by manually dragging cables, thus increasing labor and aggravating cable wear, and most of the prior art stacks cables together, thus being very troublesome in collection and use, in addition, the internal material of the existing cable is generally aluminum and copper, and if the cable is excessively bent during rolling, the quality of the cable is affected.

Disclosure of Invention

The invention aims to provide a cable laying system with an adjustable rolling radius for electric power engineering, which aims to solve the problems that most of the cable laying systems in the prior art are transported by manually dragging the cable, so that the labor is increased, and the cable abrasion is aggravated.

In order to achieve the purpose, the invention provides the following technical scheme: a cable laying system with an adjustable rolling radius for power engineering comprises a first transverse plate and wheels, wherein a plurality of wheels are fixedly connected below the first transverse plate, and a collecting device is arranged above the first transverse plate;

the collecting device comprises a vertical plate, a roller, a first gear, a first helical gear, a second helical gear, a first motor, a second transverse plate and a cable;

the lower surfaces of the left vertical plate and the right vertical plate are fixedly connected with a first transverse plate, a roller is rotatably connected inside the lower portion of the inner side of each vertical plate, each roller comprises a pair of connecting plates and a connecting shaft arranged between the connecting plates, arc-shaped holes are annularly formed in the surfaces of the connecting plates, screw holes are formed in the tops of the arc-shaped holes, an arc-shaped plate is clamped in the arc-shaped holes, a fixed block is arranged at the top of the right side of the arc-shaped plate, bolts are transversely arranged in the fixed blocks, and the bolts correspond to the screw holes in position;

the utility model discloses a cable of running roller, including the roller of running roller, first gear, first helical gear, second helical gear, first motor, second motor, the roller meshing of running roller is connected with first gear, first gear rotates with the riser through the pivot and links to each other, the outer wall winding of running roller is connected with the cable, the right side roller rigid coupling of running roller has first helical gear, the below meshing of first helical gear is connected with the second helical gear, the lower surface rigid coupling of second helical gear has first motor, the outer wall rigid coupling of first motor has the second diaphragm, the left side and the riser of second diaphragm are.

Preferably, the midpoint of the output shaft of the first motor and the midpoint of the second bevel gear are on the same vertical line.

Preferably, a clamping device is installed below the inner side of the vertical plate;

the clamping device comprises a wire coil, a first T-shaped clamping plate, an L-shaped plate, a second T-shaped clamping plate and a spring;

the right side of drum links to each other with the riser is fixed, the cotton rope rigid coupling of drum has first T shape splint, the L shaped plate is installed to the outer wall of first T shape splint, the through-hole department inner wall of L shaped plate and the outer wall clearance fit of first T shape splint, the lower surface and the first diaphragm of L shaped plate are fixed to be linked to each other, the right side of first T shape splint is equipped with second T shape splint, the lower surface and the first diaphragm of second T shape splint are fixed to be linked to each other, the inboard of first T shape splint and second T shape splint closely laminate with the outer wall of cable, the spring is installed to the left side outer wall of first T shape splint, the left and right sides of spring links to each other with first T shape splint and L shaped plate are fixed respectively.

Preferably, a moving device is installed above the inner side of the vertical plate;

the moving device comprises an arc-shaped tooth plate, a first connecting rod, a second motor, a second gear, a second connecting rod, a sleeve ring and a third transverse plate;

the left side of arc tooth dental lamina is fixed continuous with the riser, the preceding terminal surface of arc tooth dental lamina has first connecting rod through round pin axle swing joint, the round pin axle department of first connecting rod rotates through the belt and is connected with the second motor, the left side of second motor links to each other with the riser is fixed, the right side of first connecting rod has second gear and second connecting rod through round pin axle swing joint, second gear and arc tooth dental lamina intermeshing, the right side of second connecting rod has the lantern ring through round pin axle swing joint, the below outer wall of the lantern ring is laminated with the outer wall of cable mutually, the rear end face slip joint of the lantern ring has the third diaphragm, the third diaphragm links to each other with the riser is fixed.

Preferably, the meshing ratio of the second gear to the arc-shaped tooth plate is 1: 1.

preferably, the lantern ring and the third transverse plate form a sliding structure.

The application of the cable laying system with the adjustable rolling radius for the power engineering specifically comprises the following steps:

s1, firstly, an operator penetrates one end of the cable through the lantern ring and fixes the end on the roller, the wire coil is rotated, the first T-shaped clamping plate is driven to move through a wire rope on the wire coil, the first T-shaped clamping plate drives the spring to stretch, the cable is installed at the second T-shaped clamping plate, the wire coil is loosened, and the first T-shaped clamping plate applies pressure to the cable through the elastic performance of the spring.

S2, switching on an external power supply of the first motor, starting the first motor, driving the second bevel gear to rotate through an output shaft of the first motor, and driving the roller to rotate through the first bevel gear.

S3, switch on the external power supply of second motor, start the second motor, the output shaft that makes the second motor drives first connecting rod through the belt and rotates, first connecting rod drives the second gear and rotates, make the second gear remove through arc tooth dental lamina, the second gear drives the lantern ring through the second connecting rod and removes, make the lantern ring drive cable remove, when the lantern ring removes to the left side, control second motor reversal, thereby make the lantern ring reset.

Compared with the prior art, the invention has the beneficial effects that:

this cable laying system for power engineering through mutually supporting between first diaphragm, wheel, riser, running roller and the cable isotructure, can remove this device to the place that need lay the cable through the wheel, will receive the cable of line through the running roller and carry out the unwrapping wire to the labour has been practiced thrift.

This cable laying system for power engineering, through mutually supporting between first motor, first helical gear, second helical gear running roller and the cable isotructure, can drive the second helical gear through first motor and rotate, and the second helical gear drives first helical gear and rotates, and first helical gear drives the running roller and rotates to can carry out the unwrapping wire work of cable.

This cable laying system for power engineering through setting up arc hole and arc, can adjust the radius of running roller rolling inner circle, avoids the cable excessively to bend and damages, and then influences the quality of cable, enlarges cable laying's application scope.

This cable laying system for power engineering, through arc tooth dental lamina, first connecting rod, second motor, second gear, mutually supporting between second connecting rod and the lantern ring isotructure, can make the second motor drive first connecting rod and rotate, first connecting rod drives the second connecting rod through the second gear and removes, the second connecting rod drives the cable through the lantern ring and removes to can make the cable carry out even winding, made things convenient for going on of cable laying work.

This cable laying system for power engineering, the cotton rope on the drum drives first T clamp plate and removes, make first T clamp plate drive the spring and stretch, install the cable in second T clamp plate department, loosen the drum, make first T clamp plate exert pressure to the cable through the elasticity performance of spring, the external power supply of first motor is put through, start first motor, the output shaft through first motor drives the second helical gear and rotates, the second helical gear drives the running roller through first helical gear and rotates, thereby the purpose of collecting the cable has been reached.

This cable laying system for power engineering, the output shaft through the second motor passes through the belt and drives first connecting rod and rotate, first connecting rod drives the second gear and rotates, make the second gear remove through arc tooth dental lamina, the second gear drives the lantern ring through the second connecting rod and removes, make the lantern ring drive the cable and remove, when the lantern ring removes to the left side, control second motor reversal, thereby make the lantern ring reset, just so reached and made the even winding purpose of cable, the cable laying has been made things convenient for.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the first bevel gear, the second bevel gear and the first motor of FIG. 1;

FIG. 3 is a schematic view of the roller, first gear and riser of FIG. 1;

FIG. 4 is a schematic view of the first T-clamp, collar and cable shown in FIG. 1;

FIG. 5 is a schematic view of the collar, the second link, and the third cross plate of FIG. 1;

fig. 6 is a schematic structural diagram of the arc-shaped tooth plate, the second gear and the second motor in fig. 1.

FIG. 7 is a schematic view of the structure of the roller shown in FIG. 1;

FIG. 8 is a schematic structural view of a connecting plate according to the present invention;

FIG. 9 is a schematic structural view of an arcuate plate of the present invention;

in the figure: 1. the device comprises a first transverse plate, 2, a wheel, 3, a collecting device, 301, a vertical plate, 302, a roller, 3021, a connecting plate, 3022, a screw hole, 3023, an arc hole, 3024, a connecting shaft, 3025, an arc plate, 3026, a fixing block, 3027, a bolt, 303, a first gear, 304, a first helical gear, 305, a second helical gear, 306, a first motor, 307, a second transverse plate, 308, a cable, 4, a clamping device, 401, a wire coil, 402, a first T-shaped clamp plate, 403, an L-shaped plate, 404, a second T-shaped clamp plate, 405, a spring, 5, a moving device, 501, an arc tooth plate, 502, a first connecting rod, 503, a second motor, 504, a second gear, 505, a second connecting rod, 506, a collar, 507, and a third transverse plate.

Detailed Description

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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-9, the present invention provides a technical solution:

example 1

A cable laying system capable of adjusting rolling radius for an electric power engineering comprises a first transverse plate 1 and wheels 2, wherein 4 wheels 2 are fixedly connected below the first transverse plate 1, a collecting device 3 is installed above the first transverse plate 1, the collecting device 3 comprises a vertical plate 301, rollers 302, a first gear 303, a first bevel gear 304, a second bevel gear 305, a first motor 306, a second transverse plate 307 and a cable 308, the lower surfaces of a left vertical plate 301 and a right vertical plate 301 are fixedly connected with the first transverse plate 1, a through hole is formed in the lower portion of the left vertical plate 301, the rollers 302 are rotatably connected with the inner portion of the lower portion of the inner side of the vertical plate 301, each roller 302 comprises a pair of connecting plates 3021 and a connecting shaft 3024 arranged between the connecting plates 3021, an arc hole 3023 is annularly formed in the surface of each connecting plate 3021, screw holes 3022 are formed in the tops of the arc holes 3023, an arc 3025 is arranged in the arc holes 3023 in a clamping manner, a fixing block 3026 is arranged on the, a bolt 3027 is transversely arranged in the fixed block 3026, and the bolt 3027 corresponds to the screw hole 3022; in order to prevent the cable from being bent excessively, the radius of the winding inner ring is adjusted, in specific implementation, the arc-shaped plate 3025 is clamped in the arc-shaped hole 3023 of the connecting plate 3021, and meanwhile, the bolt 3027 is fixed in the screw hole 3022, so that the winding radius can be increased, and the quality of the cable is prevented from being influenced by excessive bending of the cable;

the roller shaft of the roller 302 is provided with a transverse thread, the roller shaft of the roller 302 is meshed and connected with a first gear 303, the roller 302 can drive the first gear 303 to rotate, the roller 302 can be driven to rotate more stably through the first gear 303, the first gear 303 is rotationally connected with a vertical plate 301 through a rotating shaft, the outer wall of the roller 302 is wound and connected with a cable 308, the right roller shaft of the roller 302 is fixedly connected with a first bevel gear 304, the first bevel gear 304 can drive the roller 302 to rotate, the lower part of the first bevel gear 304 is meshed and connected with a second bevel gear 305, the second bevel gear 305 can drive the first bevel gear 304 to rotate, the lower surface of the second bevel gear 305 is fixedly connected with a first motor 306, the model of the first motor 306 is BLD-09, the output shaft of the second motor 306 can drive the second bevel gear 305 to rotate, the outer wall of the first motor 306 is fixedly connected with a second transverse plate 307, the left side of the second transverse plate, the midpoint of the output shaft of the first motor 306 is on the same vertical line as the midpoint of the second bevel gear 305.

Example 2

As an optional case, referring to fig. 1, 3 and 4, in the cable laying system for power engineering, a clamping device 4 is installed below the inner side of a vertical plate 301, the clamping device 4 includes a wire coil 401, a first T-shaped clamp plate 402, an L-shaped plate 403, a second T-shaped clamp plate 404 and a spring 405, the right side of the wire coil 401 is fixedly connected with the vertical plate 301, the wire of the wire coil 401 is fixedly connected with the first T-shaped clamp plate 402, the wire of the wire coil 401 is in clearance fit with the inner wall of the through hole of the vertical plate 301, the outer wall of the first T-shaped clamp plate 402 is provided with the L-shaped plate 403, a through hole is formed inside the L-shaped plate 403, the inner wall of the through hole of the L-shaped plate 403 is in clearance fit with the outer wall of the first T-shaped clamp plate 402, the lower surface of the L-shaped plate 403 is fixedly connected with a first cross plate 1, the right side of the first T-shaped clamp plate 402 is provided with the second T-shaped clamp plate 404, the lower surface of the second, the cable 308 can be wound better by applying pressure to the cable 308 through the first T-shaped clamp plate 402 and the second T-shaped clamp plate 404, the left outer wall of the first T-shaped clamp plate 402 is provided with a spring 405, the left and right sides of the spring 405 are fixedly connected with the first T-shaped clamp plate 402 and the L-shaped plate 403 respectively, and the collar 405 is in a stretching state when the first T-shaped clamp plate 402 moves to the left.

The scheme in this embodiment can be selectively combined with the scheme in other embodiments.

Example 3

As an optional situation, referring to fig. 1, 5 and 6, in the cable laying system for electric power engineering, a moving device 5 is installed above the inner side of a vertical plate 301, the moving device 5 includes an arc-shaped tooth plate 501, a first connecting rod 502, a second motor 503, a second gear 504, a second connecting rod 505, a collar 506 and a third transverse plate 507, the left side of the arc-shaped tooth plate 501 is fixedly connected with the vertical plate 301, the front end surface of the arc-shaped tooth plate 501 is movably connected with the first connecting rod 502 through a pin shaft, the first connecting rod 502 is hinged with the arc-shaped tooth plate 501, the pin shaft of the first connecting rod 502 is rotatably connected with the second motor 503 through a belt, the model of the second motor 503 is 3GB555, the output shaft of the second motor 503 can drive the first connecting rod 502 to rotate through a belt, the left side of the second motor 503 is fixedly connected with the vertical plate 301, the right side of the first connecting rod 502 is movably connected with the second gear 504 and the second connecting rod, second gear 504 can drive second connecting rod 505 and remove, second gear 504 and arc tooth plate 501 intermeshing, second gear 504 can remove in arc tooth plate 501's tooth department, there is lantern ring 506 on the right side of second connecting rod 505 through round pin axle swing joint, second connecting rod 505 can drive lantern ring 506 and remove, the rear end face processing of lantern ring 506 has the slider, the below outer wall of lantern ring 506 is laminated with the outer wall of cable 308 mutually, the rear end face sliding clamping of lantern ring 506 has third diaphragm 507, the preceding terminal surface processing of third diaphragm 507 has the spout, the slider of lantern ring 506 can remove in the spout department of third diaphragm 507, third diaphragm 507 and riser 301 are fixed continuous, the meshing ratio of second gear 504 and arc tooth plate 501 is 1: 1, the collar 506 and the third cross plate 507 form a sliding structure.

The scheme in this embodiment can be selectively combined with the scheme in other embodiments.

Example 4

When an operator needs to use the electric power engineering cable laying system, firstly, the operator penetrates one end of a cable 308 through a lantern ring 506 and fixes the cable on a roller 302, a wire coil 401 is rotated, a wire rope on the wire coil 401 drives a first T-shaped clamping plate 402 to move, the first T-shaped clamping plate 402 drives a spring 405 to stretch, the cable 308 is installed at a second T-shaped clamping plate 404, the wire coil 401 is loosened, the first T-shaped clamping plate 402 applies pressure to the cable 308 through the elastic performance of the spring 405, an external power supply of a first motor 306 is switched on, the first motor 306 is started, an output shaft of the first motor 306 drives a second helical gear 305 to rotate, the second helical gear 305 drives the roller 302 to rotate through the first helical gear 304, the purpose of collecting the cable 308 is achieved, and the external power supply of a second motor 503 is switched on, start second motor 503, make the output shaft of second motor 503 drive first connecting rod 502 through the belt and rotate, first connecting rod 502 drives second gear 504 and rotates, make second gear 504 move through arc tooth dental lamina 501, second gear 504 drives lantern ring 506 through second connecting rod 505 and moves, make lantern ring 506 drive cable 308 and move, when lantern ring 506 moves to the left side, control second motor 503 reversal, thereby make lantern ring 506 reset, so just reached and made the even winding purpose of cable 308, the cable laying has been made things convenient for.

The scheme in this embodiment can be selectively combined with the scheme in other embodiments. .

In the description of the present invention, it is to be understood that the terms "coaxial", "bottom", "one end", "top", "middle", "other end", "upper", "one side", "top", "inner", "front", "center", "both ends", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of 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 "mounted," "disposed," "connected," "secured," "screwed" and the like are to be construed broadly, e.g., as meaning fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; the terms may be directly connected or indirectly connected through an intermediate, and may be communication between two elements or interaction relationship between two elements, unless otherwise specifically limited, and the specific meaning of the terms in the present invention will be understood by those skilled in the art according to specific situations.

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

Claims (7)

1. The utility model provides an adjustable rolling radial cable laying system for electric power engineering, includes first diaphragm (1) and wheel (2), the below rigid coupling of first diaphragm (1) has a plurality of wheels (2), its characterized in that: a collecting device (3) is arranged above the first transverse plate (1);

the collecting device (3) comprises a vertical plate (301), a roller (302), a first gear (303), a first bevel gear (304), a second bevel gear (305), a first motor (306), a second transverse plate (307) and a cable (308);

the lower surface of the left vertical plate (301) and the lower surface of the right vertical plate (301) are fixedly connected with a first transverse plate (1), a roller (302) is rotatably connected to the inner lower portion of the inner side of the vertical plate (301), the roller (302) comprises a pair of connecting plates (3021) and a connecting shaft (3024) arranged between the connecting plates (3021), arc-shaped holes (3023) are annularly formed in the surface of each connecting plate (3021), screw holes (3022) are formed in the tops of the arc-shaped holes (3023), an arc-shaped plate (3025) is clamped in each arc-shaped hole (3023), a fixing block (3026) is arranged at the top of the right side of each arc-shaped plate (3025), a bolt (3027) is transversely arranged in each fixing block (3026), and the bolt (3027) corresponds to the screw;

the roller meshing of running roller (302) is connected with first gear (303), first gear (303) rotate with riser (301) through the pivot and link to each other, the outer wall winding of running roller (302) is connected with cable (308), the right side roller rigid coupling of running roller (302) has first helical gear (304), the below meshing of first helical gear (304) is connected with second helical gear (305), the lower surface rigid coupling of second helical gear (305) has first motor (306), the outer wall rigid coupling of first motor (306) has second diaphragm (307), the left side and riser (301) fixed connection of second diaphragm (307).

2. An adjustable take-up radius cable laying system for power engineering according to claim 1, wherein: the middle point of the output shaft of the first motor (306) and the middle point of the second bevel gear (305) are on the same vertical line.

3. An adjustable take-up radius cable laying system for power engineering according to claim 1, wherein: a clamping device (4) is arranged below the inner side of the vertical plate (301);

the clamping device (4) comprises a wire coil (401), a first T-shaped clamping plate (402), an L-shaped plate (403), a second T-shaped clamping plate (404) and a spring (405);

the right side of the wire coil (401) is fixedly connected with a vertical plate (301), a first T-shaped clamping plate (402) is fixedly connected with a wire rope of the wire coil (401), an L-shaped plate (403) is arranged on the outer wall of the first T-shaped clamping plate (402), the inner wall of the through hole of the L-shaped plate (403) is in clearance fit with the outer wall of the first T-shaped clamping plate (402), the lower surface of the L-shaped plate (403) is fixedly connected with a first transverse plate (1), a second T-shaped clamping plate (404) is arranged on the right side of the first T-shaped clamping plate (402), the lower surface of the second T-shaped clamping plate (404) is fixedly connected with a first transverse plate (1), the inner sides of the first T-shaped clamping plate (402) and the second T-shaped clamping plate (404) are tightly attached to the outer wall of the cable (308), a spring (405) is arranged on the outer wall of the left side of the first T-shaped clamping plate (402), the left side and the right side of the spring (405) are respectively fixedly connected with the first T-shaped clamping plate (402) and the L-shaped plate (403).

4. An adjustable take-up radius cable laying system for power engineering according to claim 1, wherein: a moving device (5) is arranged above the inner side of the vertical plate (301);

the moving device (5) comprises an arc-shaped tooth plate (501), a first connecting rod (502), a second motor (503), a second gear (504), a second connecting rod (505), a sleeve ring (506) and a third transverse plate (507);

the left side of the arc-shaped tooth plate (501) is fixedly connected with a vertical plate (301), the front end surface of the arc-shaped tooth plate (501) is movably connected with a first connecting rod (502) through a pin shaft, a second motor (503) is rotationally connected at the pin shaft of the first connecting rod (502) through a belt, the left side of the second motor (503) is fixedly connected with the vertical plate (301), the right side of the first connecting rod (502) is movably connected with a second gear (504) and a second connecting rod (505) through a pin shaft, the second gear (504) is meshed with the arc-shaped tooth plate (501), the right side of the second connecting rod (505) is movably connected with a lantern ring (506) through a pin shaft, the lower outer wall of the collar (506) is attached to the outer wall of the cable (308), the rear end face of the lantern ring (506) is connected with a third transverse plate (507) in a sliding and clamping mode, and the third transverse plate (507) is fixedly connected with the vertical plate (301).

5. An adjustable take-up radius cable laying system for power engineering according to claim 4, wherein: the meshing ratio of the second gear (504) to the arc-shaped tooth plate (501) is 1: 1.

6. an adjustable take-up radius cable laying system for power engineering according to claim 4, wherein: the lantern ring (506) and the third transverse plate (507) form a sliding structure.

7. Use of an adjustable take-up radius cable laying system for power engineering according to claims 1-6, characterized in that: the method specifically comprises the following steps:

s1, firstly, an operator passes one end of the cable 308 through the collar 506 and fixes the end on the roller 302, rotates the wire coil 401, drives the first T-shaped clamping plate 402 to move through the wire on the wire coil 401, so that the first T-shaped clamping plate 402 drives the spring 405 to stretch, installs the cable 308 at the second T-shaped clamping plate 404, releases the wire coil 401, and makes the first T-shaped clamping plate 402 apply pressure to the cable 308 through the elastic performance of the spring 405.

S2, turning on an external power supply of the first motor 306, starting the first motor 306, driving the second bevel gear 305 to rotate through an output shaft of the first motor 306, and driving the roller 302 to rotate through the first bevel gear 304 by the second bevel gear 305.

S3, an external power supply of the second motor 503 is connected, the second motor 503 is started, an output shaft of the second motor 503 drives the first connecting rod 502 to rotate through a belt, the first connecting rod 502 drives the second gear 504 to rotate, the second gear 504 moves through the arc tooth plate 501, the second gear 504 drives the lantern ring 506 to move through the second connecting rod 505, the lantern ring 506 drives the cable 308 to move, and when the lantern ring 506 moves to the left side, the second motor 503 is controlled to rotate reversely, so that the lantern ring 506 is reset.

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