CN111941051B

CN111941051B - Screw fixing mechanism for high-voltage wire distributing coil

Info

Publication number: CN111941051B
Application number: CN202010863314.XA
Authority: CN
Inventors: 蒋欣
Original assignee: Haining Jindu New Energy Co ltd
Current assignee: Guangdong Ruitai Power Engineering Co ltd
Priority date: 2020-08-25
Filing date: 2020-08-25
Publication date: 2021-07-23
Anticipated expiration: 2040-08-25
Also published as: CN111941051A

Abstract

The invention provides a screw fixing mechanism for a high-voltage wire distributing coil, and belongs to the technical field of machinery. A screw fixing mechanism for a high-voltage wire distributing ring comprises a fixing ring, a second push rod motor, a fixing cylinder, a slide rod, a fixing frame, a third push rod motor, a fourth push rod motor, a fixing plate, a fifth push rod motor, a first expansion plate, a second expansion plate, a first clamping plate and a second clamping plate. The invention has the advantages of automatic fixation of the coil separating screw and high safety.

Description

Screw fixing mechanism for high-voltage wire distributing coil

Technical Field

The invention belongs to the technical field of machinery, and particularly relates to a screw fixing mechanism for a high-voltage wire distributing coil.

Background

High voltage line generally refers to a transmission line carrying voltages above 10kV (including 10 kV). The voltage grades of the high-voltage transmission lines in China are generally divided into: 35kV, 110kV, 220kV, 330kV, 500kV, 750kV and the like.

High-voltage line is in the design process, can be in the same place many electric wire parallel arrangement, and the distance of every electric wire is comparatively near, contact easily between the adjacent electric wire, this kind of condition then need install the separated time circle and all keep apart every electric wire, in order to avoid the emergence of unexpected condition, traditional separated time circle installation then needs the manual work to install, when fixed separated time circle, all fix it on the separated time circle with the screw on need corresponding every electric wire, when tightening the screw, very dangerous, the workman need step on the electric wire, only both ends of electric wire are fixed on adjacent electricity tower, the electric wire is in the state of rocking, then can not work under the great condition of outside wind-force, great reduction the efficiency of arranging of high-voltage line.

Disclosure of Invention

The invention aims to solve the problems in the prior art, provides a screw fixing mechanism for a high-voltage wire distributing coil, and solves the problem of danger of mounting a screw of the distributing coil by workers.

The purpose of the invention can be realized by the following technical scheme:

a screw fixing mechanism for a high-voltage wire distributing ring comprises a fixing ring and is characterized by further comprising a second push rod motor, a fixing barrel, a slide rod, a fixing frame, a third push rod motor, a fourth push rod motor, a fixing plate, a fifth push rod motor, a first expansion plate, a second expansion plate, a first clamping plate and a second clamping plate, wherein the fixing frame is fixed on the fixing ring, the fifth motor is fixed on the fixing frame, the fixing barrel is fixed on the fifth motor, the slide rod is arranged in the fixing barrel in a sliding mode, the second push rod motor is fixed on the fixing barrel, a push rod of the second push rod motor is fixedly connected with the slide rod, the third push rod motor is fixed on the slide rod, the fixing plate is fixed on a push rod of the third push rod motor, a first slide rail and a second slide rail are fixed on the fixing plate, the first expansion plate is fixed on the first slide rail, the first clamping plate is fixed on the second slide rail, the second expansion plate slides and sets up on slide rail one, the second splint slide and set up on slide rail two, and first splint, second splint are located the outside of first expansion plate, second expansion plate, and the length of the length weak point of first expansion plate, second expansion plate and first splint, second splint, fourth push rod motor is fixed on the fixed plate, and the push rod of fourth push rod motor links to each other with the second expansion plate is fixed, the fifth push rod motor is fixed on the fixed plate, and the push rod of fifth push rod motor links to each other with the second splint is fixed.

In the above screw fixing mechanism for the high-voltage wire distributing coil, the screw screwing-in component comprises a sixth push rod motor, a sixth motor, a seventh motor, a rotating frame, a plurality of rotating cylinders and a rotating column, the sixth motor is fixed on the fixing plate, the rotating frame is fixed on an output shaft of the sixth motor, a plurality of rotating discs are circumferentially arrayed and rotatably arranged on the rotating frame, through holes are formed in the rotating discs, the rotating cylinder is slidably arranged in the through holes and is connected with the rotating discs through a plurality of tension springs, the rotating cylinder is internally provided with a hexagonal prism-shaped accommodating channel capable of accommodating screws, a plurality of elastic sheets are fixed in the rotating cylinder, the sixth push rod motor is fixed on the fixed frame, the seventh motor is fixed on the push rod of the sixth push rod motor, the rotating column is fixed on an output shaft of the seventh motor, is hexagonal and can extend into the rotating cylinder and drive the rotating cylinder to rotate.

In the screw fixing mechanism for the high-voltage wire distributing coil, the rotating cylinder is internally provided with a plurality of grooves, and the elastic sheet is fixed in the grooves.

In the screw fixing mechanism for the high-voltage wire distributing coil, the end part of the rotating cylinder is fixed with the limiting elastic sheet.

In the above screw fixing mechanism for a high-voltage wire dividing coil, the rotating post has a cylindrical insertion portion at a distal end thereof.

Compared with the prior art, the invention has the following advantages:

the invention can automatically fix the high-voltage wire on the distributing ring, greatly improve the working efficiency and reduce the operation danger of workers. When the traditional coil is installed, the screw installation at the upper part is relatively safe, while the screw installation at the lower part is relatively dangerous, workers need to squat down for processing, and the invention can automatically fix the screw.

Drawings

FIG. 1 is a schematic of the present invention.

Fig. 2 is a schematic view of the retainer ring of the present invention.

Fig. 3 is a schematic view of the present invention on a rotating plate.

Fig. 4 is a partially enlarged view of fig. 1.

Fig. 5 is a schematic view of a rotating disc according to the present invention.

Fig. 6 is a schematic view of the assist mechanism in the present invention.

Fig. 7 is a sectional view of the rotary cylinder of the present invention.

Fig. 8 is a schematic view of a rotary cylinder according to the present invention.

Fig. 9 is a schematic view of a coil in the present invention.

In the figure, 1, a fixed ring; 2. a rotating ring; 2a, a chute; 2b, a gap; 3. a first motor; 4. a gear; 5. a toothed ring; 6. a swing arm; 6a, a first guide groove; 7. positioning pins; 8. a slider; 9. a first half ring; 11. a second half ring; 12. a second motor; 13. a first push rod motor; 14. a rotating plate; 14a, a second guide groove; 14b, a third guide groove; 15. a first guide piece; 16. a second guide piece; 17. a guide pin; 18. a limiting clamp; 18a, a limiting groove; 19. fixing the rod; 20. an auxiliary roller; 21. rotating the block; 22. a third motor; 23. a movable frame; 24. a moving wheel; 25. a guide rail; 26. a moving block; 26a, a clamping part; 27. rotating the disc; 27a, a fourth guide groove; 28. a fourth motor; 29. a second push rod motor; 30. a fixed cylinder; 31. a slide bar; 32. a fixed mount; 33. a third push rod motor; 34. a fourth push rod motor; 35. a fixing plate; 36. a fifth push rod motor; 37. a first expansion panel; 38. a second expansion panel; 39. a first splint; 40. a second splint; 41. a fifth motor; 42. a sixth push rod motor; 43. a sixth motor; 44. a seventh motor; 46. a rotating frame; 47. a rotating cylinder; 47a, an accommodating channel; 47a1, groove; 48. rotating the column; 48a, an insertion portion; 49. a turntable; 50. a tension spring; 51. an elastic sheet; 52. a push block; 53. a limiting elastic sheet; 54. a coil splitting; 54a, a coil body; 54b, a fixing ring; 54b1, stationary half ring one; 54b2, stationary half ring two; 55. a screw; 56. a first slide rail; 56a slide rail two.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

As shown in fig. 1 to 9, in the present invention, the coil dividing ring 54 includes a coil body 54a and a fixing ring 54b fixed on the coil body 54a, the fixing ring 54b includes a first fixing half ring 54b1 and a second fixing half ring 54b2, the first fixing half ring 54b1 is fixedly connected to the coil body 54a, the second fixing half ring 54b2 is hinged on the first fixing half ring 54b1, and the other end of the second fixing half ring 54b can be fixedly connected with the first fixing half ring 54b1 through a screw 55.

A mounting device for a six-wire high-voltage wire distribution ring 54 comprises a fixed ring 1, wherein a rotating ring 2 is rotatably arranged on the fixed ring 1, an annular sliding groove 2a is formed in the rotating ring 2, a gap 2b connected with the sliding groove 2a is formed in the rotating ring 2, a first motor 3 is fixed on the fixed ring 1, a gear 4 is fixed on an output shaft of the first motor 3, a gear ring 5 is fixed on the rotating ring 2, and the gear 4 is meshed with the gear ring 5; six swing arms 6 are circumferentially arranged on the fixed ring 1 in an array manner, a first guide groove 6a is formed in each swing arm 6, six positioning pins 7 are fixed on the fixed ring 1, the positioning pins 7 extend into the first guide grooves 6a, each swing arm 6 can rotate around the corresponding positioning pin 7, each swing arm 6 can move along the corresponding positioning pin 7 through the corresponding first guide groove 6a, each swing arm 6 is fixedly provided with a sliding block 8, each sliding block 8 is slidably arranged in each sliding groove 2a, after a notch 2b in each rotating ring 2 rotates to one sliding block 8, each sliding block 8 can be separated from each sliding groove 2a, each swing arm 6 can move, a first semi-ring 9 is fixed at the outer end of each swing arm 6, each first semi-ring 9 is rotatably provided with a pulley for abutting against a high-voltage line, each first semi-ring 9 is hinged with a second semi-ring 11 capable of sealing each first semi-ring 9, and each fixed ring 1 is provided with a driving mechanism capable of driving each first semi-ring 9 to move and form a D-shaped track, at least two swing arms 6 are provided with moving mechanisms at the ends for driving the fixing ring 1 to move, the fixing ring 1 is provided with a fixing mechanism for fixing the wire dividing ring 54, the fixing ring 1 is also provided with an auxiliary mechanism for opening or clamping the fixing ring 54b on the wire dividing ring 54, and the auxiliary mechanism further comprises a screw 55 for feeding the screw 55 and screwing the screw 55 for fixing the fixing ring 54b by the screw 55 into the assembly.

The working principle of the invention is as follows: the fixing ring 1 can be fixed on a high-voltage wire through the first half ring 9 and the second half ring 11, then the whole device is driven to move on the high-voltage wire through the moving mechanism, in operation, the wire separating ring 54 can be fixed on the fixing ring 1 through the fixing mechanism manually, then after the mounting device is moved to a preset position, the first motor 3 is started, the first motor 3 drives the gear 4 to rotate, the gear 4 drives the gear ring 5 and the rotating ring 2 to rotate, the notch 2b on the rotating ring 2 is moved to one of the swinging arms 6, the sliding block 8 on the swinging arm 6 enters the notch 2b, then the swinging arm 6 is driven to swing through the driving mechanism, the other end of the swinging arm 6 can form a D-shaped track, so that the high-voltage wire is sent into the fixing ring 54b component, and the fixing ring 54b is opened through the auxiliary mechanism before the high-voltage wire is sent into the fixing ring, then, the high-voltage electric wire is fed into the fixing ring 54b through the swing arm 6, then, the first fixing half ring 54b1 and the second fixing half ring 54b2 on the fixing ring 54b are fitted and fixed through the auxiliary mechanism again, then, the first fixing half ring 54b1 and the second fixing half ring 54b2 are fixedly connected through the screws 55 screwed into the assembly by the screws 55, at this time, the high-voltage electric wire is fixed in the fixing ring 54b, and then, the auxiliary mechanism is disengaged from the fixing ring 54b and rotated to the next fixing ring 54b for operation.

The invention can automatically fix the high-voltage wire on the coil divider 54, greatly improve the working efficiency and reduce the operation danger of workers.

Specifically, the driving mechanism comprises a second motor 12 and a first push rod motor 13, the rotating plate 14 is fixed on the output shaft of the second motor 12, the second motor 12 is fixed in the middle of the fixing ring 1, the output shaft of the second motor 12 is concentrically arranged with the fixing ring 1, the rotating plate 14 is fixed on the output shaft of the second motor 12, the rotating plate 14 is provided with an arc-shaped second guide groove 14a and a straight-line-shaped third guide groove 14b, two ends of the second guide groove 14a are connected with two ends of the third guide groove 14b, two junctions of the second guide groove 14a and the third guide groove 14b are provided with a first guide sheet 15 and a second guide sheet 16 in a hinged mode, the inner end of the swing arm 6 is fixed with a guide nail 17, a cylinder body of the first push rod motor 13 is hinged on the rotating plate 14, a limit clamp 18 and a fixing rod 19 are fixed on a push rod of the first push rod motor 13, the limit clamp 18 is provided with a limit groove 18a for accommodating the guide nail 17, and the fixing rod 19 extends into the second guide groove 14a or the third guide groove 14 b. When the second motor 12 is started to drive the rotating plate 14 to rotate, after the rotating plate 14 rotates to a preset position, the guide nail 17 on the swing arm 6 enters the limiting groove 18a of the limiting clamp 18, then the first push rod motor 13 is started to drive the lower end of the swing arm 6 to move along the second guide groove 14a and the third guide groove 14b, the end part of the swing arm 6 forms a D-shaped track, the other end of the swing rod also forms a mirror image D-shaped track, when the high-voltage wire is driven, the high-voltage wire firstly enters the second guide groove 14a of the knife, the high-voltage wire bypasses the fixing ring 54b, and then the high-voltage wire enters the fixing ring 54b through the third guide groove 14 b. The present invention can effectively feed the high-voltage electric wire into the fixing ring 54 b.

The first guide piece 15 can be turned in the direction of the second guide groove 14a, and the second guide piece 16 can be turned in the direction of the third guide groove 14 b. When the first push rod motor 13 drives the fixing rod 19 to move along the second guide groove 14a and enters the third guide groove 14b, the second guide piece 16 is pushed open and then enters the third guide groove 14b, the second guide piece 16 is reset, the second guide groove 14a is closed, the push rod motor drives the fixing rod 19 to move along the third guide groove 14b until the first guide piece 15 is pushed open, then the first guide piece 15 closes the third guide groove 14b, the push rod motor drives the fixing rod 19 to enter the second guide groove 14a to form a D-shaped track and can reciprocate, an arc-shaped track can be effectively driven by the high-voltage wire, the high-voltage wire is prevented from the fixing ring 54b, and then the high-voltage wire forms a linear track and enters the fixing ring 54 b. When the fixed ring 54b is opened, the first half ring 54b1 is fixed on the coil body 54a, and the second half ring 54b2 is hinged on the first half ring 54b1 and is located away from the connection between the first half ring 54b1 and the coil body 54 a; therefore, the electric wire must enter the fixing ring 54b from the side of the fixing ring 54b close to the coil body 54 a.

After the high-voltage wire is fixed, the rotating ring 2 can be driven to rotate by the first motor 3, so that the sliding block 8 on the swing arm 6 enters the first guide groove 6a again, the swing arm 6 cannot swing, and then the rotating plate 14 is driven to rotate by the second motor 12, so that the limiting clamp 18 is separated from the guide nail 17.

Specifically, the hinge joints of the first guide piece 15 and the second guide piece 16 are provided with torsion springs. The first guide piece 15 and the second guide piece 16 can be better returned after being turned over by the torsion spring.

Specifically, an auxiliary roller 20 is rotatably provided on the fixing lever 19. The fixing lever 19 can be moved more smoothly by the auxiliary roller 20, resulting in a longer life span of the apparatus.

Specifically, the end of the positioning pin 7 is rotatably provided with a rotating block 21, and the rotating block 21 is slidably disposed in the first guide groove 6 a. The turning block 21 is slidable in the first guide groove 6 a. It is possible to make the oscillating arm 6 only able to rotate or to translate in the same plane.

Specifically, the moving mechanism comprises a third motor 22, a moving frame 23 and a moving wheel 24, the moving frame 23 is fixed on the swing arm 6, the third motor 22 is fixed on the moving frame 23, the moving wheel 24 is rotatably arranged on the moving frame 23, the moving wheel 24 is coaxially connected with an output shaft of the third motor 22, and a limiting plate is fixed on two sides of the moving frame 23. The third motor 22 is activated to rotate the movable wheel 24, and the movable wheel 24 is in contact with the high-voltage wire and can drive the mounting device to move.

Specifically, the fixing mechanism comprises a plurality of guide rails 25, a plurality of moving blocks 26, a rotating disc 27 and a fourth motor 28, the guide rails 25 are fixed on the fixing ring 1, the guide rails 25 are arranged outwards from the center of the fixing ring 1, the moving blocks 26 are arranged on the guide rails 25 in a sliding mode, the fourth motor 28 is fixed on the fixing ring 1, the rotating disc 27 is fixed on an output shaft of the fourth motor 28, a plurality of arc-shaped fourth guide grooves 27a are formed in the rotating disc 27, the moving blocks 26 extend into the corresponding fourth guide grooves 27a, and clamping portions 26a are formed in the moving blocks 26. The seventh motor 44 is turned on to rotate the rotating disc 27, and the rotating disc 27 moves the moving block 26 along the fourth guide groove 27a, so that the coil 54 can be fixed by the holding portion 26a of the moving block 26.

Specifically, the auxiliary mechanism includes a second push rod motor 29, a fixed cylinder 30, a sliding rod 31, a fixed frame 32, a third push rod motor 33, a fourth push rod motor 34, a fixed plate 35, a fifth push rod motor 36, a first expanding plate 37, a second expanding plate 38, a first clamping plate 39 and a second clamping plate 40, the fixed frame 32 is fixed on the fixed ring 1, the fixed frame 32 is fixed with the fifth motor 41, the fixed cylinder 30 is fixed on the fifth motor 41, the sliding rod 31 is slidably arranged in the fixed cylinder 30, the second push rod motor 29 is fixed on the fixed cylinder 30, a push rod of the second push rod motor 29 is fixedly connected with the sliding rod 31, the third push rod motor 33 is fixed on the sliding rod 31, the fixed plate 35 is fixed on a push rod of the third push rod motor 33, a first sliding rail 56 and a second sliding rail 56a are fixed on the fixed plate 35, the first expanding plate 37 is fixed on the first sliding rail 56, the first clamping plate 39 is fixed on the second sliding rail 56a, the second expansion plate 38 is arranged on the first sliding rail 56 in a sliding manner, the second clamping plate 40 is arranged on the second sliding rail 56a in a sliding manner, the first clamping plate 39 and the second clamping plate 40 are positioned on the outer sides of the first expansion plate 37 and the second expansion plate 38, the first expansion plate 37 and the second expansion plate 38 are short in length and the first clamping plate 39 and the second clamping plate 40 are short in length, the fourth push rod motor 34 is fixed on the fixing plate 35, a push rod of the fourth push rod motor 34 is fixedly connected with the second expansion plate 38, the fifth push rod motor 36 is fixed on the fixing plate 35, and a push rod of the fifth push rod motor 36 is fixedly connected with the second clamping plate 40.

The principle of the mechanism is that the second push rod motor 29 drives the slide rod 31 to stretch, so that the wire separating ring 54 can be conveniently fixed on the fixing mechanism.

After the auxiliary mechanism is driven by the fifth motor 41 to rotate to a preset position, the third push rod motor 33 is started to drive the first expansion plate 37, the second expansion plate 38, the first clamping plate 39 and the second clamping plate 40 to move towards the fixing ring 54b of the wire dividing ring 54, so that the first expansion plate 37 and the second expansion plate 38 are inserted into the fixing ring 54b, the first expansion plate 37 abuts against the first fixing half ring 54b1, the second expansion plate 38 abuts against the second fixing half ring 54b2, the second expansion plate 38 is driven by the fourth push rod motor 34 to move, so that the second fixing half ring 54b2 is turned outwards and opened, after a high-voltage wire enters between the first fixing half ring 54b1 and the second fixing half ring 54b2, the third push rod motor 33 is started again to separate the first expansion plate 37 and the second expansion plate 38 from the first fixing half ring 54b1 and the second fixing half ring 54b2, and then the fifth push rod motor 36 is started to drive the second clamping plate 40 to approach to the first clamping plate 39, the second stationary half 54b2 abuts against the first stationary half 54b 1.

The present mechanism enables the fixing ring 54b to be automatically opened and closed.

Specifically, the screw screwing assembly comprises a sixth push rod motor 42, a sixth motor 43, a seventh motor 44, a rotating frame 46, a plurality of rotating cylinders 47 and a rotating column 48, wherein the sixth motor 43 is fixed on the fixed plate 35, the rotating frame 46 is fixed on an output shaft of the sixth motor 43, a plurality of rotating discs 49 are circumferentially arrayed and rotatably arranged on the rotating frame 46, through holes are formed in the rotating discs 49, the rotating cylinders 47 are slidably arranged in the through holes, the rotating cylinders 47 are connected with the rotating discs 49 through a plurality of tension springs 50, accommodating channels 47a which are hexagonal prism-shaped and can be used for accommodating screws 55 are arranged in the rotating cylinders 47, a plurality of elastic sheets 51 are fixed in the rotating cylinders 47, the sixth push rod motor 42 is fixed on the fixed plate 35, the seventh motor 44 is fixed on a push rod of the sixth push rod motor 42, the rotating column 48 is fixed on an output shaft of the seventh motor 44, the rotating column 48 is hexagonal prism-shaped, a push block 52 is further fixed on the rotating column 48, the rotating column 48 can extend into the rotating cylinder 47 and can drive the rotating cylinder 47 to rotate.

The principle of the mechanism is as follows: the screw 55 is put into the rotating cylinder 47 in advance, the screw 55 is fixed through the elastic sheet 51 in the rotating cylinder 47, the sixth push rod motor 42 is started to drive the seventh motor 44 and the rotating column 48 on the seventh motor 44 to move, the rotating column 48 is inserted into the rotating cylinder 47, the seventh motor 44 is started to drive the rotating column 48 to rotate, the rotating column 48 drives the rotating cylinder 47 to rotate, and the rotating cylinder 47 drives the screw 55 to rotate until the screw 55 is screwed into the fixing ring 54 b. When screwing in, the rotating column 48 can drive the screw 55 to rotate, the push block 52 can push the rotating cylinder 47 forward even at the later screwing-in stage, the screw 55 can be made to be closer to the fixing ring 54b, after screwing, the sixth push rod motor 42 resets, and the rotating cylinder 47 resets through the tension spring 50.

After the screw 55 in the rotary cylinder 47 is used, the sixth motor 43 drives the rotary rack 46 to rotate, and the rotary rack 46 can move other rotary cylinders 47 to the corresponding rotary columns 48.

Specifically, the rotating cylinder 47 has a plurality of grooves 47a1 formed therein, and the elastic piece 51 is fixed in the groove 47a 1. The elastic piece 51 can be pressed into the groove 47a 1.

Specifically, a limiting elastic sheet is fixed at the end of the rotating cylinder 47. The screw 55 can be prevented from falling out of the rotary cylinder 47.

Specifically, the rotation column 48 has a cylindrical insertion portion 48a at the front end. The insertion of the rotary post 48 into the rotary cylinder 47 can be facilitated.

The above components are all standard components or components known to those skilled in the art, and the structure and principle thereof can be known to those skilled in the art through technical manuals or through routine experiments.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the spirit or ambit of the invention as defined in the appended claims.

Claims

1. A screw fixing mechanism for a high-voltage wire distributing ring comprises a fixing ring and is characterized by further comprising a second push rod motor, a fixing barrel, a slide rod, a fixing frame, a third push rod motor, a fourth push rod motor, a fixing plate, a fifth push rod motor, a first expansion plate, a second expansion plate, a first clamping plate and a second clamping plate, wherein the fixing frame is fixed on the fixing ring, the fifth motor is fixed on the fixing frame, the fixing barrel is fixed on the fifth motor, the slide rod is arranged in the fixing barrel in a sliding mode, the second push rod motor is fixed on the fixing barrel, a push rod of the second push rod motor is fixedly connected with the slide rod, the third push rod motor is fixed on the slide rod, the fixing plate is fixed on a push rod of the third push rod motor, a first slide rail and a second slide rail are fixed on the fixing plate, the first expansion plate is fixed on the first slide rail, the first clamping plate is fixed on the second slide rail, the second expansion plate is arranged on the first sliding rail in a sliding mode, the second clamping plate is arranged on the second sliding rail in a sliding mode, the first clamping plate and the second clamping plate are located on the outer sides of the first expansion plate and the second expansion plate, the first expansion plate and the second expansion plate are short in length and the first clamping plate and the second clamping plate are short in length, the fourth push rod motor is fixed on the fixing plate, a push rod of the fourth push rod motor is fixedly connected with the second expansion plate, the fifth push rod motor is fixed on the fixing plate, a push rod of the fifth push rod motor is fixedly connected with the second clamping plate, and the screw-in device further comprises a screw assembly used for feeding screws and fixing rings by screws; the screw screwing component comprises a sixth push rod motor, a sixth motor, a seventh motor, a rotating frame, a plurality of rotating cylinders and a rotating column, the sixth motor is fixed on the fixing plate, the rotating frame is fixed on an output shaft of the sixth motor, a plurality of rotating discs are circumferentially arrayed and rotatably arranged on the rotating frame, through holes are formed in the rotating discs, the rotating cylinder is slidably arranged in the through holes and is connected with the rotating discs through a plurality of tension springs, the rotating cylinder is internally provided with a hexagonal prism-shaped accommodating channel capable of accommodating screws, a plurality of elastic sheets are fixed in the rotating cylinder, the sixth push rod motor is fixed on the fixed frame, the seventh motor is fixed on the push rod of the sixth push rod motor, the rotating column is fixed on an output shaft of the seventh motor, is hexagonal and can extend into the rotating cylinder and drive the rotating cylinder to rotate.

2. The screw fixing mechanism for the high-voltage wire distributing coil as claimed in claim 1, wherein the rotating cylinder is formed with a plurality of grooves therein, and the elastic piece is fixed in the groove.

3. The screw fixing mechanism for the high-voltage wire distributing coil as claimed in claim 1, wherein a limiting elastic sheet is fixed at the end of the rotating cylinder.

4. The screw fixing mechanism for a high-voltage wire distributing coil as claimed in claim 1, wherein the front end of the rotary post has a cylindrical insertion portion.