CN110224349B - Tape winding assisting machine - Google Patents

Abstract

The invention provides a tape winding assisting machine, which comprises a driven wheel and a cable pressing assembly, wherein the cable pressing assembly is provided with an accommodating channel for accommodating a cable, the driving mechanism comprises a driving wheel matched with the driven wheel, the tape supplying assembly is used for installing a tape, one end of the tape is stuck on the cable, when the driving wheel drives the driven wheel to rotate, the tape supplying assembly can correspondingly rotate along the circumferential direction of the cable, so that the tape is wound on the outer surface of the cable, when the tape winding assisting machine is operated in a narrow construction space to wind the tape along a preset direction, the driven wheel can be driven by the driving wheel, so that the tape can be driven to conveniently and rapidly spirally wind the outer surface of the cable.

Description

Tape winding assisting machine

Technical Field

The invention belongs to the field of cable construction, and particularly relates to an adhesive tape winding assisting machine.

Background

When the electric power worker finishes the connection work of the large-scale cable, the cable is required to be wound with adhesive tapes of different types for a plurality of times according to the technical requirements, and in practice, the work is mostly unfolded in a narrow space such as a sewer.

At present, when related operations are performed, manual winding is adopted, and an experienced operator is required to manually wind the cable with adhesive tape in a narrow construction site where large-scale cable connection is required.

However, the working mode is low in efficiency, high in labor intensity of operators and high in requirements on professional technical quality of the operators, and does not accord with the concept of 'people-oriented and efficiency-oriented' in the current social production.

Disclosure of Invention

The invention aims at solving the problems and aims to provide an adhesive tape winding assisting machine which is matched with operators to wind adhesive tapes on the outer surface of a cable rapidly.

In order to achieve the above purpose, the invention adopts the following technical scheme:

The present invention provides a tape winding machine for winding a tape onto an outer surface of a cable moving in a predetermined direction, having the characteristics of comprising: the cable accommodating mechanism comprises a driven wheel and a cable compacting assembly arranged on the driven wheel; the driving mechanism is provided with a driving wheel matched with the driven wheel, and the driving wheel is used for driving the driven wheel to rotate; the adhesive tape supply assembly is arranged on the driven wheel and is positioned near the cable, and is provided with a damping rotating shaft sleeve for installing adhesive tape, and one end of the adhesive tape is stuck on the cable; wherein, cable hold-down assembly has the passageway that holds that is used for holding the cable, when the action wheel drive is rotated from the driving wheel for the sticky tape supply assembly can carry out corresponding rotation along the circumference of cable, thereby twine the sticky tape on the surface of cable.

The adhesive tape winding assisting machine provided by the invention can also have the following characteristics: wherein, cable compresses tightly the subassembly and contains a plurality of compression units, and a plurality of compression units set up along the circumference of follow driving wheel to form and hold the passageway.

The adhesive tape winding assisting machine provided by the invention can also have the following characteristics: the compression unit comprises a unit shell, and a compression spring, a steel ball positioning plate and a compression steel ball which are positioned in the unit shell, wherein the outer surface of the unit shell is arranged on the driven wheel, the compression spring is provided with a fixed end and a free end, the fixed end is arranged on the inner wall of the unit shell, the free end is abutted with the end face of the steel ball positioning plate, the compression steel ball is rotatably abutted on the steel ball positioning plate, the surface of the compression steel ball is in contact with the outer surface of the cable, and when the cable moves in a preset direction in the accommodating channel, the compression steel ball and the outer surface of the cable generate rolling friction.

The adhesive tape winding assisting machine provided by the invention can also have the following characteristics: the adhesive tape supply assembly further comprises a placing rod, the placing rod is fixedly arranged on the driven wheel, the damping rotating shaft sleeve is sleeved on the placing rod, the damping rotating shaft sleeve can rotate relative to the placing rod, the length direction of the damping rotating shaft sleeve is parallel to the axis of the containing channel, and the adhesive tape is sleeved on the damping rotating shaft sleeve.

The adhesive tape winding assisting machine provided by the invention can also have the following characteristics: wherein, damping pivot cover is the tube-shape, and the surface is formed with protruding at least three claw, and at least three claw is along placing the circumference of pole evenly setting.

The adhesive tape winding assisting machine provided by the invention can also have the following characteristics: the damping rotating shaft sleeve is any one of a plastic damping rotating shaft sleeve, a cold-working die steel damping rotating shaft sleeve and an SK7 steel damping rotating shaft sleeve.

The adhesive tape winding assisting machine provided by the invention can also have the following characteristics: the driven wheel comprises a first half gear and a second half gear, the first half gear and the second half gear are semi-circular, the first half gear is detachably arranged on the second half gear, the driving wheel is a gear meshed with the driven wheel, and the axes of the driving wheel and the driven wheel are parallel.

Effects and effects of the invention

According to the adhesive tape winding assisting machine, the cable containing mechanism comprises the driven wheel and the cable pressing assembly, the cable pressing assembly is provided with the containing channel for containing the cable, the driving mechanism comprises the driving wheel matched with the driven wheel, the adhesive tape supplying assembly is used for installing the adhesive tape, one end of the adhesive tape is adhered to the cable, when the driving wheel drives the driven wheel to rotate, the adhesive tape supplying assembly can correspondingly rotate along the circumferential direction of the cable, so that the adhesive tape is wound on the outer surface of the cable, when the adhesive tape winding assisting machine is operated in a narrow construction space to wind the adhesive tape on the cable along a preset direction, the driven wheel can be driven by the driving wheel, so that the adhesive tape can be driven to conveniently and rapidly spirally wind the outer surface of the cable.

Drawings

FIG. 1 is a schematic perspective view of a tape winder in accordance with an embodiment of the present invention;

FIG. 2 is a schematic diagram of the operation of the tape winding assist machine in accordance with an embodiment of the present invention;

Fig. 3 is a schematic perspective view of a cable housing mechanism in an embodiment of the present invention; and

Fig. 4 is a schematic perspective view of a compacting unit according to an embodiment of the invention.

Detailed Description

In order to make the technical means, creation characteristics, achievement of the purposes and effects of the present invention easy to understand, the following embodiments specifically describe the tape winding machine of the present invention with reference to the accompanying drawings.

FIG. 1 is a schematic perspective view of a tape winder in accordance with an embodiment of the present invention; fig. 2 is a schematic diagram illustrating the operation of the tape winding machine according to the embodiment of the present invention.

As shown in fig. 1 and 2, the tape winding assisting machine 100 of the present embodiment is for winding a tape (not shown in the drawings) onto an outer surface of a cable C moving in a predetermined direction, and includes a housing 10, a cable accommodating mechanism 20, a driving mechanism 30, a driving motor 50, and a tape supply assembly 40.

The housing 10 includes a housing body 11 and a housing handle 12.

The housing body 11 is a metal housing, and the housing handle 12 is an arc handle for an operator to hold. In the present embodiment, the housing handle 12 is located on the surface of the housing body 11.

Fig. 3 is a schematic perspective view of a cable housing mechanism in an embodiment of the present invention;

as shown in fig. 1 and 3, the cable receiving mechanism 20 includes a driven pulley 21 and a cable hold-down assembly 22.

The driven wheel 21 comprises a first half-gear 211 and a second half-gear 212.

The first half gear 211 and the second half gear 212 are each semi-circular in shape, and the first half gear 211 is detachably mounted on the second half gear 212, thereby forming a complete gear.

In this embodiment, the driven wheel 21 is designed with a modulus of 5, a number of teeth of 30 and a tooth thickness of 7.85 mm.

One end face of the first half gear 211 has a connection shaft hole penetrating through the thickness direction, the other end of the first half gear 211 has a coupling protrusion 2111 protruding outward, and the coupling protrusion 2111 has a locking through hole extending in the thickness direction of the first half gear 211.

The second half gear 212 also has a connecting shaft hole penetrating through the thickness direction at one end face, and the second half gear 212 has an inwardly recessed coupling recess 2112 at the other end, and two coaxial locking through holes extending in the thickness direction of the second half gear 212 are formed in the inner wall of the coupling recess 2112.

One end of the first half gear 211 and one end of the second half gear 212 are hinged together through two connection shaft holes by using the connection shaft S2, so that the first half gear 211 and the second half gear 212 can rotate with respect to the connection shaft S1, and further, the other end of the first half gear 211 and the other end of the second half gear 212 can be opened or closed, and when the other end of the first half gear 211 and the other end of the second half gear 212 are opened, one side of the driven wheel 21 forms an opening.

One end of the connecting shaft S2 is provided with a shaft shoulder S3, and the shaft shoulder is movably connected to the inner wall of the shell body 11.

The tooth thickness of two adjacent teeth at the hinge position of the first half gear 211 and the second half gear 212 is half of the tooth thickness of other teeth, so that when the other end of the first half gear 211 and the other end of the second half gear 212 are disconnected, the first half gear 211 and the second half gear 212 can not interfere when the opening angle of the driven wheel 21 is in the range of 0-63 degrees.

When the other end of the first half gear 211 and the other end of the second half gear 212 are closed, the other end of the first half gear 211 and the other end of the second half gear 212 are locked and fixed by the butterfly screw S1 passing through the three locking through holes.

The cable compression assembly 22 comprises a plurality of compression units 221 and has a receiving channel 222 for receiving a cable,

The plurality of pressing units 221 are located inside the first half gear 211 and the second half gear 212, respectively, and are disposed along the circumferential direction of the driven wheel 21, thereby forming the accommodation passage 222.

In the present embodiment, the number of the pressing units 221 is 10, which are fixedly installed inside the first half gear 211 and the second half gear 212, respectively, and when the other end of the first half gear 211 and the other end of the second half gear 212 are closed, the 10 pressing units 221 form a circular receiving passage 222, and the 10 pressing units 221 are symmetrically distributed with the axis of the receiving passage 222 as a symmetry axis.

Fig. 4 is a schematic perspective view of a compacting unit according to an embodiment of the invention.

As shown in fig. 3 and 4, the pressing unit 221 includes a unit housing 2211, and a pressing spring 2212, a steel ball positioning plate 2213 and a pressing steel ball 2214 which are positioned in the unit housing 2211,

An outer surface 2211S of the unit housing 2211 is mounted on an inner side surface of the driven wheel 21,

The hold-down spring 2212 has a fixed end 2212A and a free end 2212B, the fixed end 2212A is mounted on the inner wall of the unit case 2211, and the free end 2212B abuts against the end face of the steel ball positioning plate 2213.

In the present embodiment, the elastic coefficient of the hold-down spring 2212 is preferably 1.1kN/m.

The steel ball positioning plate 2213 is movably connected to the inner wall of the unit housing 2211.

The pressing steel balls 2214 are rotatably embedded on the steel ball positioning plate 2213, and the surface of the pressing steel balls 2214 is contacted with the outer surface of the cable C.

In this embodiment, the diameter of the compression steel ball 2214 is 4-6mm, preferably 5mm.

When the cable C moves in a predetermined direction (direction D shown in fig. 4) with respect to the receiving passage 222, the pressing steel balls 2214 and the outer surface of the cable generate rolling friction.

The drive mechanism 30 has a driving wheel 31 that cooperates with the driven wheel 21.

The driving wheel 31 is a gear meshed with the driven wheel 21, the axes of the driving wheel 31 and the driven wheel 21 are parallel, and the driving wheel 31 is used for driving the driven wheel 21 to rotate.

The driving motor 50 is mounted on the housing body 11.

In this embodiment, the driving wheel 31 is mounted on an output shaft of the driving motor 50 in an interference fit manner, and the driving motor 50 is used for driving the driving wheel 31 to rotate the driven wheel 21.

The tape supply assembly 40 is provided on the driven wheel 21 and located in the vicinity of the cable C, having a placement rod 42 and a damping swivel sleeve 41 for mounting a tape, one end of which is attached to the cable.

The placing rod 42 is fixedly installed on the surface of the driven wheel 21, the damping rotating shaft sleeve 41 is cylindrical and sleeved on the placing rod 42, the damping rotating shaft sleeve 41 can rotate relative to the placing rod 42, and the length direction of the damping rotating shaft sleeve 41 is parallel to the axis of the containing channel 222.

In the present embodiment, the damping swivel sleeve 41 has a cylindrical shape.

The damping swivel sleeve 41 is formed on the outer surface thereof with at least three projecting claws 41A, and the at least three claws 41A are uniformly arranged in the circumferential direction of the placement rod 42. The tape is sleeved on the damping swivel sleeve 42. The damping rotor sleeve 41 is any one of a plastic damping rotor sleeve, a cold work die steel damping rotor sleeve and an SK7 steel damping rotor sleeve.

In this embodiment, the number of the claws 41A is three, each of which protrudes along a predetermined arc, and the protruding end of the claw 41A has a serrated end surface, so that the joint surface between the adhesive tape sleeved on the claw 41A and the claw 41A has a larger friction coefficient.

When the driving pulley 31 drives the driven pulley 21 to rotate, the tape supply assembly 40 is allowed to rotate correspondingly in the circumferential direction of the cable C, thereby winding the tape around the outer surface of the cable C.

The operation of the tape winding machine 100 according to the present embodiment is described below with reference to fig. 2:

First, the needed adhesive tape is sleeved on the damping rotating shaft sleeve 41, and then the damping rotating shaft sleeve 41 is sleeved on the placing rod 42 and fixed on the adhesive tape winding assisting machine 100.

In the second step, the driving motor 50 is started to rotate the driving wheel 31 to the hinge position of the first half gear 211 and the second half gear 212, the driving motor 50 is turned off, the first half gear 211 and the second half gear 212 are turned on, one side of the driven wheel 21 is opened, the cable C is manually placed in the accommodating channel 222, and at this time, one end of the adhesive tape is pressed on the surface of the cable C by the 10 pressing units 221 (note that at this time, the lower half gear needs to be adjusted to the lower half part of the winding machine to be opened). The first half gear 211 and the second half gear 212 are connected with each other through the connecting shaft S2, the first half gear 211 and the housing body 11 are mutually positioned and fixed through the transition fit between the shaft shoulder S3 and the bearing embedded in the housing body 11, and the second half gear 212 and the first half gear 211 are locked and fixed through the butterfly screw S1.

Fourth, the driving motor 50 is started, and the power is transmitted to the driving wheel 31 through the connecting shaft and then transmitted to the driven wheel 21, so that the driven wheel 21 rotates in the direction R in FIG. 4, and the adhesive tape is driven to rotate around the circumference of the cable C.

Fifth, the operator holds the tape-wrapping machine 100 to move in the axial direction of the cable (as shown in the direction D of fig. 4), and the cable C and the tape-wrapping machine 100 are pressed against the steel balls 2214 to generate rolling friction.

Sixth, when the tape is wound, the driving motor 50 is turned off, the tape is cut off from the cable C, the driven wheel 21 is opened, and the tape winding assisting machine 100 is taken down.

Effects and effects of the examples

According to the adhesive tape winding assisting machine, the cable containing mechanism comprises the driven wheel and the cable pressing assembly, the cable pressing assembly is provided with the containing channel for containing the cable, the driving mechanism comprises the driving wheel matched with the driven wheel, the adhesive tape supplying assembly is used for installing the adhesive tape, one end of the adhesive tape is adhered to the cable, when the driving wheel drives the driven wheel to rotate, the adhesive tape supplying assembly can correspondingly rotate along the circumferential direction of the cable, so that the adhesive tape is wound on the outer surface of the cable, when the adhesive tape winding assisting machine is operated in a narrow construction space to wind the adhesive tape on the cable along a preset direction, the driven wheel can be driven by the driving wheel, so that the adhesive tape can be driven to conveniently and rapidly spirally wind the outer surface of the cable.

Because the cable compressing assembly in this embodiment includes a plurality of compressing units, the fixed end of the compressing spring in the compressing unit is mounted on the inner wall of the unit housing, the free end is abutted against the end face of the steel ball positioning plate, the compressing steel balls are rotatably embedded on the steel ball positioning plate, the surface of the compressing steel balls is in contact with the outer surface of the cable, and when the cable moves in the accommodating channel along the preset direction, rolling friction is generated between the compressing steel balls and the outer surface of the cable. The adhesive tape winding assisting machine is suitable for cables with different diameters, the diameter change generated in the adhesive tape winding process of the cable can be correspondingly and self-adjusted, and the compression unit 221 can always keep compressing with the surface of the cable C, so that the universality and universality of the application of the adhesive tape winding assisting machine can be greatly improved, and the resistance which is needed to be overcome by an operator in the process of operating the adhesive tape winding assisting machine is reduced.

Because the adhesive tape supply assembly in this embodiment further includes a placement shaft, the placement shaft is fixedly mounted on the driven wheel, the damping swivel sleeve is sleeved on the placement shaft, and the adhesive tape is sleeved on the damping swivel sleeve. Therefore, in the process of winding the adhesive tape, the friction force generated between the damping rotating shaft sleeve and the placing rod in the rotating process can tighten the adhesive tape, so that the adhesive tape is more stable in the process of winding the adhesive tape, and the winding requirement is met.

Further, since the zigzag end surfaces of the protruding ends of the three raking claws are formed on the surface of the damping swivel sleeve in the present embodiment, the tightening effect of the adhesive tape is made better.

Because the driven wheel in this embodiment includes the first half gear and the second half gear each having a semicircular arc shape, and the first half gear is detachably mounted on the second half gear. The driven wheel can therefore be conveniently opened or closed to facilitate the placement of the cable in the receiving channel.

Further, since the tooth thicknesses of the adjacent two teeth at the hinge of the first half gear 211 and the second half gear 212 in the present embodiment are half of the tooth thicknesses of the other teeth, it is made possible that the first half gear 211 and the second half gear 212 do not interfere when the opening angle of the driven wheel 21 is in the range of 0 ° -63 ° when the other end of the first half gear 211 and the other end of the second half gear 212 are disconnected. And the torque transmission efficiency can reach more than 95%.

The above embodiments are preferred embodiments of the present invention and are not intended to limit the scope of the present invention, and various modifications or variations which may be made by those skilled in the art without the inventive effort within the scope of the appended claims remain within the scope of this patent.

For example, the placement rod in this embodiment is fixedly mounted on the surface of the driven wheel, and in practical application, the placement rod may be integrally formed with the driven wheel or welded on the surface of the driven wheel.

Claims (2)

1. A tape winder for winding tape onto an outer surface of a cable moving in a predetermined direction, comprising:

The cable containing mechanism comprises a driven wheel and a cable pressing assembly arranged on the driven wheel;

The driving mechanism is provided with a driving wheel matched with the driven wheel and used for driving the driven wheel to rotate; and

A tape supply assembly disposed on the driven wheel and located adjacent to the cable, having a damping swivel sleeve for mounting the tape, one end of the tape being attached to the cable;

Wherein the cable gland assembly has a receiving channel for receiving the cable,

When the driving wheel drives the driven wheel to rotate, the adhesive tape supply assembly can correspondingly rotate along the circumferential direction of the cable, so that the adhesive tape is wound on the outer surface of the cable,

The cable pressing assembly includes a plurality of pressing units disposed along a circumferential direction of the driven wheel to form the receiving passage,

The compressing unit comprises a unit shell, a compressing spring, a steel ball locating plate and a compressing steel ball which are positioned in the unit shell,

The outer surface of the unit housing is mounted on the driven wheel,

The compression spring is provided with a fixed end and a free end, the fixed end is arranged on the inner wall of the unit shell, the free end is abutted with the end face of the steel ball positioning plate,

The compression steel balls are rotatably embedded on the steel ball positioning plate, the surfaces of the compression steel balls are contacted with the outer surface of the cable,

When the cable moves in the predetermined direction in the accommodation passage, the pressing steel ball and the outer surface of the cable generate rolling friction,

The tape supply assembly further includes a placement shaft,

The placing shaft is fixedly arranged on the driven wheel, the damping rotating shaft sleeve is sleeved on the placing shaft,

The damping rotating shaft sleeve can rotate relative to the placing shaft, the length direction of the damping rotating shaft sleeve is parallel to the axis of the accommodating channel,

The adhesive tape is sleeved on the damping rotating shaft sleeve,

The damping rotating shaft sleeve is cylindrical, the outer surface of the damping rotating shaft sleeve is provided with at least three convex scraping claws which are uniformly arranged along the circumferential direction of the placing shaft,

The driven wheel comprises a first half gear and a second half gear,

The first half gear and the second half gear are both semi-circular, the first half gear is detachably arranged on the second half gear,

The driving wheel is a gear meshed with the driven wheel, and the axes of the driving wheel and the driven wheel are parallel.

2. The tape winder of claim 1, wherein:

the damping rotating shaft sleeve is any one of a plastic damping rotating shaft sleeve and an SK7 steel damping rotating shaft sleeve.