CN111817113B

CN111817113B - Multi-strand wire shearing post-processing method

Info

Publication number: CN111817113B
Application number: CN202010742910.2A
Authority: CN
Inventors: 董伟锋; 陈旺
Original assignee: Jiangxi Xingtian Electric Products Co ltd
Current assignee: Jiangxi Xingtian Electric Products Co ltd
Priority date: 2020-07-29
Filing date: 2020-07-29
Publication date: 2021-05-04
Anticipated expiration: 2040-07-29
Also published as: CN111817113A

Abstract

The invention relates to a processing method after shearing of a multi-strand electric wire, which uses a wire end screwing device, wherein the wire end screwing device comprises a base, a wire clamping unit and a screwing unit, wherein the wire clamping unit is arranged on the left side of the upper end of the base, and the screwing unit is arranged on the right side of the upper end of the base; the device assists in manually winding the exposed wire harness after the multi-strand wires are cut, so that the problem that the multi-strand wires cannot be effectively wound by the other hand under the condition that the wires are manually held by one hand is solved; according to the invention, the exposed copper wire is divided into a plurality of strands through the winding posts, so that the problem that the surface of the copper wire is too smooth and the winding operation cannot be completed through twisting is solved; the invention prevents the problem that the copper wire is restored to the original shape due to the memory property thereof by a mode of fixing the copper wire immediately after winding.

Description

Multi-strand wire shearing post-processing method

Technical Field

The invention relates to the technical field of wire processing, in particular to a processing method for a multi-strand wire after being cut.

Background

In the same insulating layer, the conductor is composed of a thicker copper wire (or aluminum wire and other materials) and is called as a single-stranded wire; the conductor is made up of a plurality of relatively fine copper wires, referred to as "strands". The difference between the two is not very much, and mainly, the stranded wire has two advantages. Firstly, skin effect: when current passes through the conductor, the current is concentrated on the conductor to be expressed, and the inner space is wasted. The larger the current, the higher the frequency, and the stronger the skin effect. The multi-strand wire can concentrate current on the surface of each strand of copper wire, so that the waste of conductor space is reduced or even reduced, and the current-carrying capacity is increased, namely the anti-skin effect. Secondly, construction is convenient: the single-stranded wire has too high hardness to adapt to large-angle and repeated bending. Therefore, in an environment with a small space and a large bending angle, such as a secondary circuit of an electric appliance and a distribution box, a softer wire needs to be used.

Often need tailor the stranded wire in the use of stranded wire, but behind the stranded wire desquamation, often stranded copper line can scatter to make the pencil unusually in disorder, can't carry out effectual carding and butt joint, because the stranded stub is many, when a handheld line, can't carry out effectual wire winding operation to the stranded wire through another hand, when carrying out the wire winding processing to the stranded wire through equipment, often can be because the copper line surface is too smooth can't accomplish the wire winding operation through twisting wire.

Disclosure of Invention

The invention aims to provide a processing method after shearing of a multi-strand wire, which has the advantages of wave-type feeding, stirring, crushing, heat dissipation, self-cleaning of a cleaning brush and the like and solves the problems.

A processing method after cutting multi-strand wires uses a wire head tightening device, the wire head tightening device comprises a base, a wire clamping unit and a tightening unit, and the processing method of the multi-strand wires by adopting the wire head tightening device comprises the following steps:

s1, equipment checking: before starting the equipment, carrying out conventional inspection on the equipment by manual work;

s2, loading operation: the stranded wires are clamped and fixed through the wire clamping unit;

s3, winding operation: the tightening unit performs winding processing on the scattered stranded wires;

s4, glue rolling operation: the screwing unit is used for pasting and fixing the wound stranded wires;

the left side of the upper end of the base is provided with a wire clamping unit, and the right side of the upper end of the base is provided with a screwing unit; the wire clamping unit limits the degree of freedom of left-right feeding of the stranded wires, the tightening unit winds the exposed stranded copper wires, and waterproof insulating adhesive tapes are adhered to the wound stranded wires.

The tightening unit comprises a driving motor, a threaded column, a feeding frame, a transmission mechanism, a rotating outer cylinder, a winding inner cylinder, a winding mechanism and a glue coiling mechanism, a feeding groove is formed in the upper end of a base, the driving motor is arranged on the inner wall of the right end of the feeding groove through a motor base, the threaded column is arranged at the left end of the output end of the driving motor, the feeding frame is connected with the feeding groove in a sliding mode, the feeding frame is connected with the threaded column in a threaded connection mode, the rotating outer cylinder is arranged on the inner wall of the feeding frame through a bearing, a motor cavity is formed in the feeding frame, the transmission mechanism is arranged on the inner wall of the left end of the motor cavity, the winding inner cylinder is arranged on the inner wall of the rotating outer cylinder through a bearing, the winding mechanism is arranged at the right end of the winding inner; drive strand wire around rolling up through winding mechanism, driving motor passes through the screw thread post and drives and feed the frame and slowly feed right to the strand wire that spills winds up, changes the rotation of line mechanism drive strand wire, thereby pastes the mode sticky tape at the copper line surface through rolling up gluey mechanism.

The transmission mechanism comprises an auxiliary motor, a transmission belt, a rotating seat, a matching rod, an auxiliary spring and turbine teeth, wherein the auxiliary motor is arranged on the inner wall of the left end of a motor cavity through a motor seat; the auxiliary motor drives the rotating outer barrel to rotate through the transmission belt, the rotating outer barrel drives the winding inner barrel to rotate through the matching rod and the turbine teeth, and therefore the multi-strand wires are wound and screwed down through the winding mechanism.

The winding mechanism comprises a guide ring, a rotating hand wheel, a guide post frame, guide grooves and winding posts, the guide post frame is arranged at the inner end of the rotating outer barrel, the guide ring is arranged at the right end of the guide post frame, the rotating hand wheel is arranged at the right end of the winding inner barrel, the guide grooves are evenly formed in the right end of the guide ring along the axial direction, the winding posts are connected with the guide grooves in a sliding mode, and the winding posts are connected with the inner wall of the right end of the winding inner barrel in a threaded connection mode. Rotate the wire winding inner tube through rotating the hand wheel, the turbine tooth passes through slip mode extrusion cooperation pole for wire winding inner tube and guide pillar frame relative rotation, thereby drive the wire winding post and inwards feed along the guide way, equally divide the copper line that the stranded wire exposes, thereby when making to rotate the urceolus and rotate, the copper line that exposes can obtain fine winding effect.

As a preferred scheme of the invention, the wire clamping unit comprises a wire clamping seat, a wire clamping ring frame, a matching groove, an opening and closing slide block, a sliding column and a wire clamping spring, wherein the left side of the upper end of the base is provided with the wire clamping seat, the upper end of the wire clamping seat is provided with the wire clamping ring frame, the upper end of the wire clamping ring frame is provided with a V-shaped opening, the inner walls of the front end and the rear end of the wire clamping ring frame are symmetrically provided with the matching groove, the opening and closing slide block is connected with the matching groove in a sliding manner, the outer end of the opening and closing slide block is provided with the sliding column, and the wire clamping spring is arranged between the. The wire clamping spring pushes the opening and closing slide block to extrude the stranded wires inwards, and meanwhile, the stranded wires are prevented from feeding rightwards through the friction teeth.

As a preferable scheme of the invention, the upper end of the opening and closing slide block is of an outward and inward inclined structure from top to bottom, and the lower end of the opening and closing slide block is of an arc structure. The upper end of the opening and closing slide block is of an outside-in inclined structure from top to bottom, so that the stranded wires can be conveniently guided into the clamping position.

As a preferable scheme of the invention, the inner wall of the lower end of the wire clamping ring frame is uniformly provided with friction teeth from left to right.

As a preferable scheme of the invention, the rotating seats and the turbine teeth are distributed in a staggered and spaced mode.

As a preferable scheme of the invention, the line rotating mechanism comprises a rotating gear ring, a rotating gear, an incomplete gear, a line clamping ring block and a friction pad, wherein the rotating gear ring is arranged at the left end of the rotating outer cylinder, a rotating groove is formed in the left side of the inner wall of the feeding frame, the rotating gear is arranged on the inner wall of the right end of the rotating groove through a bearing, the rotating gear ring is connected with the rotating gear in a meshing mode, the incomplete gear is arranged at the left end of the rotating gear, the line clamping ring block is arranged on the inner wall of the left end of the rotating groove through the bearing, the incomplete gear is connected with the line clamping ring block in a meshing mode, and the friction pad is arranged on the inner wall of the. The gear ring, the rotary gear and the incomplete gear are matched to drive the wire clamping ring block to rotate intermittently, so that the wire harness fixed by the wire clamping ring block is wound when the wire harness is not moved, and the waterproof adhesive tape is pasted when the wire harness is rotated.

As a preferred scheme of the invention, the glue rolling mechanism comprises a glue rolling frame, a discharge roller and a waterproof adhesive tape, the left end of the feeding frame is provided with the glue rolling frame, the discharge roller is arranged between the inner walls of the left end and the right end of the glue rolling frame through a bearing, and the waterproof adhesive tape is sleeved on the outer wall of the discharge roller.

(III) advantageous effects

1. The device assists in manually winding the exposed wire harness after the multi-strand wires are cut, so that the problem that the multi-strand wires cannot be effectively wound by the other hand under the condition that the wires are manually held by one hand is solved; according to the invention, the exposed copper wire is divided into a plurality of strands through the winding posts, so that the problem that the surface of the copper wire is too smooth and the winding operation cannot be completed through twisting is solved; the invention prevents the problem that the copper wire is restored to the original shape due to the memory property thereof by a mode of fixing the copper wire immediately after winding.

2. According to the invention, the winding inner cylinder is rotated by the arranged rotating hand wheel, the worm gear extrudes the matching rod in a sliding mode, so that the winding inner cylinder and the guide pillar frame relatively rotate, the winding pillar is driven to feed inwards along the guide groove, copper wires exposed by the multi-strand wires are equally divided, and the exposed copper wires can obtain a good winding effect when the outer cylinder rotates.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a process flow diagram of the solid waste treatment method of the power plant of the present invention;

FIG. 2 is a schematic structural view of the present invention;

FIG. 3 is a schematic cross-sectional view taken at section A-A of FIG. 2 in accordance with the present invention;

FIG. 4 is a schematic cross-sectional view taken at section B-B of FIG. 2 in accordance with the present invention;

FIG. 5 is an enlarged view of a portion I of FIG. 2 in accordance with the present invention;

FIG. 6 is an enlarged view of a portion II of FIG. 4 in accordance with the present invention;

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways as defined and covered by the claims.

As shown in fig. 1 to 6, a method for processing a multi-strand wire after cutting, which uses a wire head tightening device comprising a base 1, a wire clamping unit 2 and a tightening unit 3, comprises the following steps:

s2, loading operation: the stranded wires are clamped and fixed through the wire clamping unit 2;

s3, winding operation: the tightening unit 3 performs winding processing on the scattered stranded wires;

s4, glue rolling operation: the screwing unit 3 is used for pasting and fixing the wound stranded wires;

the left side of the upper end of the base 1 is provided with a wire clamping unit 2, and the right side of the upper end of the base 1 is provided with a screwing unit 3;

the tightening unit 3 comprises a driving motor 31, a thread column 32, a feeding frame 33, a transmission mechanism 34, a rotating outer cylinder 35, a winding inner cylinder 36, a winding mechanism 37, a thread rotating mechanism 38 and a glue coiling mechanism 39, wherein the upper end of the base 1 is provided with a feeding groove, the driving motor 31 is arranged on the inner wall of the right end of the feeding groove through a motor base, the left end of the output end of the driving motor 31 is provided with the thread column 32, the feeding frame 33 is connected with the feeding groove in a sliding mode, the feeding frame 33 is connected with the thread column 32 in a threaded connection mode, the rotating outer cylinder 35 is arranged on the inner wall of the feeding frame 33 through a bearing, a motor cavity is arranged in the feeding frame 33, the transmission mechanism 34 is arranged on the inner wall of the left end of the motor cavity, the winding inner cylinder 36 is arranged on the inner wall of the rotating outer cylinder 35 through a bearing, the winding mechanism 37 is arranged at the, the left end of the feeding frame 33 is provided with a rubber rolling mechanism 39; the winding machine 37 drives the stranded wires to wind, the driving motor 31 drives the feeding frame 33 to slowly feed rightwards through the threaded column 32, so that the leaked stranded wires are wound, the wire rotating mechanism 38 drives the stranded wires to rotate, and the mode adhesive tapes are attached to the outer surfaces of the copper wires through the adhesive winding mechanism 39.

The transmission mechanism 34 comprises an auxiliary motor 341, a transmission belt 342, a rotating seat 343, a matching rod 344, an auxiliary spring 345 and turbine teeth 346, the auxiliary motor 341 is arranged on the inner wall of the left end of the motor cavity through the motor seat, the right end of the output end of the auxiliary motor 341 is provided with a belt pulley, the transmission belt 342 is sleeved on the belt pulley and the outer wall of the rotating outer cylinder 35, the rotating seat 343 is uniformly arranged on the inner wall of the rotating outer cylinder 35 along the axial direction, the matching rod 344 is arranged on the inner walls of the left and right ends of the rotating seat 343 through bearings, the auxiliary spring 345 is arranged between the outer end of the matching rod 344 and the inner wall of the rotating outer cylinder 35, and the turbine; the auxiliary motor 341 rotates the rotating outer cylinder 35 through the transmission belt 342, and the rotating outer cylinder 35 rotates the winding inner cylinder 36 through the matching rod 344 and the turbine teeth 346, so as to wind and tighten the multi-strand wires through the winding mechanism 37.

The winding mechanism 37 comprises a guide ring 371, a rotating hand wheel 372, a guide post frame 373, a guide groove 374 and a winding post 375, the guide post frame 373 is arranged at the inner end of the rotating outer cylinder 35, the guide ring 371 is arranged at the right end of the guide post frame 373, the rotating hand wheel 372 is arranged at the right end of the winding inner cylinder 36, the guide groove 374 is uniformly arranged at the right end of the guide ring 371 in the axial direction, the winding post 375 is connected with the guide groove 374 in a sliding mode, and the winding post 375 is connected with the inner wall of the right end of the winding inner cylinder 36 in. The rotating seats 343 and the turbine teeth 346 are distributed in a staggered and spaced arrangement. Rotate the wire winding inner tube 36 through rotating hand wheel 372, turbine tooth 346 is through slip mode extrusion fit pole 344 for wire winding inner tube 36 and guide pillar frame 373 relative rotation, thereby drive wire winding post 375 along the inside feeding of guide way 374, equally divide the copper line that the stranded wire exposes, thereby when making to rotate outer tube 35 and rotate, the copper line that exposes can obtain fine winding effect.

Card line unit 2 include card line seat 21, card line ring frame 22, cooperation groove 23, the slider 24 that opens and shuts, slip post 25 and

card line spring

26, 1 upper end left side of base is provided with card line seat 21, card line seat 21 upper end is provided with card line ring frame 22, V type opening has been seted up to card line ring frame 22 upper end, cooperation groove 23 has been seted up to the symmetry on the both ends inner wall around the card line ring, the slider 24 that opens and shuts is connected with cooperation groove 23 through the slip mode, the slider 24 outer end that opens and shuts is provided with slip post 25, be provided with card line spring 26 between the slider 24 outer end that opens and shuts and the inner wall of cooperation groove 23. The upper end of the opening and closing slide block 24 is of an outward and inward inclined structure from top to bottom, and the lower end of the opening and closing slide block 24 is of an arc structure. The inner wall of the lower end of the wire clamping ring frame 22 is evenly provided with friction teeth from left to right. The wire clamping spring 26 pushes the opening and closing slider 24 to press the stranded wires inward while preventing the stranded wires from being fed rightward by the friction teeth. The upper end of the opening and closing slide block 24 is of an outside-in inclined structure from top to bottom so as to conveniently guide the stranded wires into a clamping position.

The rotating line mechanism 38 comprises a rotating toothed ring 381, a rotating gear 382, an incomplete gear 383, a line clamping ring block 384 and a friction pad 385, wherein the rotating toothed ring 381 is arranged at the left end of the rotating outer cylinder 35, a rotating groove is formed in the left side of the inner wall of the feeding frame 33, the rotating gear 382 is arranged on the inner wall of the right end of the rotating groove through a bearing, the rotating toothed ring 381 is connected with the rotating gear 382 in a meshing mode, the incomplete gear 383 is arranged at the left end of the rotating gear 382, the line clamping ring block 384 is arranged on the inner wall of the left end of the rotating groove through a bearing, the incomplete gear 383 is connected with the line clamping ring block 384 in a meshing mode, and the friction pad 385 is arranged on the inner wall of the. The rotating toothed ring 381, the rotating gear 382 and the incomplete gear 383 are matched to drive the wire clamping ring block 384 to rotate intermittently, so that a wire winding operation is performed when a wire harness fixed by the wire clamping ring block 384 is stationary, and the waterproof adhesive tape 393 is adhered when the wire clamping ring block 384 rotates.

The roll glue mechanism 39 comprises a roll glue frame 391, a discharging roller 392 and a waterproof adhesive tape 393, the left end of the feeding frame 33 is provided with the roll glue frame 391, the discharging roller 392 is arranged between the inner walls of the left end and the right end of the roll glue frame 391 through a bearing, and the waterproof adhesive tape 393 is sleeved on the outer wall of the discharging roller 392.

The working process is as follows: fix the complete part of stranded wire to card line unit 2 through the manual work in, card line unit 2 restricts the degree of freedom that feeds about the stranded wire, pastes the complete part of stranded wire at most through the manual work with waterproof adhesive tape, screws up the stranded copper line that unit 3 will expose and winds the book to drive the stranded wire rotation after the wire winding, thereby at the peripheral winding waterproof adhesive tape 393 of copper line that exposes.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. A multi-strand electric wire shearing post-processing method using a wire end tightening device including a base (1), a wire clamping unit (2), and a tightening unit (3), characterized in that: the method for processing the stranded wires by adopting the wire head tightening equipment comprises the following steps:

s2, loading operation: the stranded wires are clamped and fixed through the wire clamping unit (2);

s3, winding operation: the tightening unit (3) performs winding processing on the scattered stranded wires;

s4, glue rolling operation: the screwing unit (3) is used for pasting and fixing the wound stranded wires;

the left side of the upper end of the base (1) is provided with a wire clamping unit (2), and the right side of the upper end of the base (1) is provided with a screwing unit (3);

the tightening unit (3) comprises a driving motor (31), a thread column (32), a feeding frame (33), a transmission mechanism (34), a rotating outer cylinder (35), a winding inner cylinder (36), a winding mechanism (37), a line rotating mechanism (38) and a glue coiling mechanism (39), wherein a feeding groove is formed in the upper end of the base (1), the driving motor (31) is arranged on the inner wall of the right end of the feeding groove through a motor base, the thread column (32) is arranged at the left end of the output end of the driving motor (31), the feeding frame (33) is connected with the feeding groove in a sliding mode, the feeding frame (33) is connected with the thread column (32) in a threaded connection mode, the rotating outer cylinder (35) is arranged on the inner wall of the feeding frame (33) through a bearing, a motor cavity is formed in the feeding frame (33), the transmission mechanism (34) is arranged on the inner wall of the left end of the motor cavity, the winding inner cylinder (36) is arranged, the winding mechanism (37) is arranged at the right end of the winding inner cylinder (36) through a bearing, the left end of the rotating outer cylinder (35) is provided with a wire rotating mechanism (38), and the left end of the feeding frame (33) is provided with a rubber coiling mechanism (39);

the transmission mechanism (34) comprises an auxiliary motor (341), a transmission belt (342), a rotating seat (343), a matching rod (344), an auxiliary spring (345) and turbine teeth (346), the auxiliary motor (341) is arranged on the inner wall of the left end of a motor cavity through the motor seat, a belt pulley is arranged at the right end of the output end of the auxiliary motor (341), the transmission belt (342) is sleeved on the outer walls of the belt pulley and the rotating outer cylinder (35), the rotating seat (343) is uniformly arranged on the inner wall of the rotating outer cylinder (35) along the axial direction, the matching rod (344) is arranged on the inner walls of the left end and the right end of the rotating seat (343) through bearings, the auxiliary spring (345) is arranged between the outer end of the matching rod (344) and the inner wall of the rotating outer cylinder (35), and the turbine teeth;

the winding mechanism (37) comprises a guide ring (371), a rotating hand wheel (372), a guide post frame (373), a guide groove (374) and winding posts (375), the inner end of the rotating outer cylinder (35) is provided with the guide post frame (373), the right end of the guide post frame (373) is provided with the guide ring (371), the right end of the winding inner cylinder (36) is provided with the rotating hand wheel (372), the right end of the guide ring (371) is uniformly provided with the guide groove (374) along the axial direction, the winding posts (375) are connected with the guide groove (374) in a sliding mode, and the winding posts (375) are connected with the inner wall of the right end of the winding inner cylinder (36) in a.

2. A method of post-shear processing of a multi-strand electrical wire as in claim 1, wherein: card line unit (2) including card line seat (21), card line ring frame (22), cooperation groove (23), the slider (24) that opens and shuts, slip post (25) and card line spring (26), base (1) upper end left side is provided with card line seat (21), card line seat (21) upper end is provided with card line ring frame (22), V type opening has been seted up to card line ring frame (22) upper end, cooperation groove (23) have been seted up to the symmetry on the inner wall of both ends around the card line ring, the slider (24) that opens and shuts is connected with cooperation groove (23) through the slip mode, the slider (24) outer end that opens and shuts is provided with slip post (25), it is provided with card line spring (26) to open and shut between slider (24) outer end and cooperation groove (23) inner wall.

3. A method of post-shear processing of a multi-strand electrical wire as in claim 2, wherein: the upper end of the opening and closing slide block (24) is of an outward and inward inclined structure from top to bottom, and the lower end of the opening and closing slide block (24) is of an arc structure.

4. A method of post-shear processing of a multi-strand electrical wire as in claim 2, wherein: and friction teeth are uniformly arranged on the inner wall of the lower end of the wire clamping ring frame (22) from left to right.

5. A method of post-shear processing of a multi-strand electrical wire as in claim 1, wherein: the rotating seats (343) and the turbine teeth (346) are distributed in a staggered and spaced mode.

6. A method of post-shear processing of a multi-strand electrical wire as in claim 1, wherein: the rotating line mechanism (38) comprises a rotating gear ring (381), a rotating gear (382), an incomplete gear (383), a line clamping ring block (384) and a friction pad (385), wherein the rotating gear ring (381) is arranged at the left end of a rotating outer cylinder (35), a rotating groove is formed in the left side of the inner wall of a feeding frame (33), the rotating gear (382) is arranged on the inner wall of the right end of the rotating groove through a bearing, the rotating gear ring (381) is connected with the rotating gear (382) in a meshing mode, the incomplete gear (383) is arranged at the left end of the rotating gear (382), the line clamping ring block (384) is arranged on the inner wall of the left end of the rotating groove through a bearing, the incomplete gear (383) is connected with the line clamping ring block (384) in a meshing mode, and the friction pad (385) is arranged on the inner wall of the line clamping ring block.

7. A method of post-shear processing of a multi-strand electrical wire as in claim 1, wherein: roll up gluey mechanism (39) including rolling up gluey frame (391), discharge roller (392) and waterproof sticky tape (393), feed frame (33) left end is provided with and rolls up gluey frame (391), is provided with discharge roller (392) through the bearing between the gluey frame (391) left and right ends inner wall, waterproof sticky tape (393) cover is established on discharge roller (392) outer wall.