CN220604400U - Rotary cabling combined die - Google Patents

Abstract

The utility model relates to the technical field of combined dies and discloses a rotary cabling combined die which comprises an electric wire, wherein a first twisting die is arranged on the outer side of the electric wire, a second twisting die is arranged on one side of the first twisting die, a third twisting die is arranged on one side of the second twisting die, a detector is fixedly connected to the upper side of the third twisting die, a driven gear is rotatably connected to the outer side of the third twisting die, a driving gear is in meshed connection with the outer side of the driven gear, a motor component is fixedly connected to one side of the driving gear, and a control device is fixedly connected to the lower side of the motor component.

Description

Rotary cabling combined die

Technical Field

The utility model relates to the technical field of combined dies, in particular to a rotary cabling combined die.

Background

The cabling of the cable is to twist various copper wires, wire cores or fillers into a whole, most of the twisting shapes are round structures, the twisting mold is round, and the cable core rotates along the center of the mold without barriers and resistance.

Through searching, the utility model with the patent number of CN210788710U and the name of a cable forming combined die comprises a supporting table, and research and analysis show that although a plurality of dies on the combined die are always positioned on the same straight line during working, the dies are gradually pressed and formed, the defect of inaccurate welding seams caused by uneven stress due to bending of a copper strip is avoided, meanwhile, the dies are effectively cooled by a circulating water cooling system, the internal thermal stress of the copper tube is reduced, the problem that fatigue damage possibly generates stretch-breaking is solved, and the water temperature change is detected to judge the forming effect, the welding quality is improved, and the service life is prolonged.

However, there are also disadvantages to some extent, such as: when the cable is required to be changed into a semicircular shape or a non-circular shape, the corresponding shape mould is required to be used for compaction forming, however, the compacted conductor is generally a thicker conductor (more than 1 mm), the compaction is not broken, the conductor is deformed to fix the shape, but the thinner conductor (about 0.2 mm) is not suitable for compaction, if the thinner conductor is required to be stranded into a semicircular structure or a different structure, the front shaping structure is damaged due to rotation resistance when the later procedure is used for rotation movement, thereby leading to failure of the stranded structure or only using the front one to finish stranding, the final cable forming quality is not high, and therefore, by the process design, the problems of reduction of the generated rotation resistance and center centering when the subsequent stranding mould is used for the stranding which is finished by the first mould at first are solved, and the problems of improving the production quality and the process level are the quick to be solved.

Disclosure of Invention

The utility model aims to provide a rotary cabling combined die which is used for solving the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the rotary cabling combined die comprises an electric wire, wherein a first twisting die is arranged on the outer side of the electric wire, a second twisting die is arranged on one side of the first twisting die, a third twisting die is arranged on one side of the second twisting die, a detector is fixedly connected to the upper side of the third twisting die, a driven gear is rotatably connected to the outer side of the third twisting die, a driving gear is connected to the outer side of the driven gear in a meshed manner, a motor assembly is fixedly connected to one side of the driving gear, and a control device is fixedly connected to the lower side of the motor assembly;

the first stranding die comprises a first fixing seat, a first supporting rod, a stranding die frame, a first anisotropic conductor and a first die shell, wherein the first fixing seat is arranged on the outer side of the electric wire, the first supporting rod is fixedly connected to the upper side of the first fixing seat, the first die shell is fixedly connected to the upper side of the first supporting rod, the stranding die frame is fixedly connected to the inner side of the first die shell, the first anisotropic conductor is fixedly connected to the axis position of the stranding die frame, and a through hole is formed in the upper side of the first anisotropic conductor and the inner side of the through hole is provided with the electric wire penetrating through the first fixing seat.

Further, the second stranding mould includes second fixing base, second bracing piece, bearing, second opposite sex conductor and second mould shell, one side of first mould shell is provided with the second fixing base, the upside fixedly connected with second bracing piece of second fixing base, the upside fixedly connected with second mould shell of second bracing piece, the inboard fixedly connected with bearing of second mould shell, the central point of bearing puts fixedly connected with second opposite sex conductor, the second opposite sex conductor can be in free rotation in the bearing, the through-hole has been seted up to the central point of second opposite sex conductor, the electric wire runs through the inboard and extends out to both sides respectively through its through-hole.

The second twisting mold is used for installing a required second opposite conductor in the bearing, so that the shape of the front twisting can be well maintained after the wire passes through the second opposite conductor when rotating, but the rotation resistance and the inertia force brought by the wire can be eliminated due to self-transmission of the bearing when encountering resistance or reaction force;

further, the third stranding die comprises a third fixing seat and a third supporting rod, one side of the second die shell is provided with the third fixing seat, the upper side of the third fixing seat is fixedly connected with the third supporting rod, the upper side of the third supporting rod is also provided with a foreign conductor, the inner side of the foreign conductor is provided with a through hole, and the inner side of the through hole is also provided with the electric wire passing through the through hole.

Further, the driven gear comprises a driven gear body and an angle scale mark, the driven gear body is rotationally connected to the outer side of the third support rod, an opposite conductor is fixedly connected to the axis position of the driven gear body, the shape of the opposite conductor is identical to that of the second opposite conductor, the angle scale mark is fixedly connected to one side, away from the third support rod, of the driven gear body, and the center position of the angle scale mark is vertically arranged.

Further, the driving gear comprises a driving gear body and a gear shaft, the driving gear body is connected to the outer side of the driven gear body in a meshed mode, and the gear shaft is fixedly connected to the center of the driving gear body.

The electric wire passes through a first opposite conductor in a first twisting mold, passes through the first opposite conductor and then enters a second opposite conductor, then passes through the second opposite conductor, sequentially passes through a through hole formed in the center of a driven gear body, passes through the opposite conductor arranged in a third twisting mold and passes out, and sequentially ensures that the whole electric wire always keeps a horizontal state in the passing action process, wherein whether the whole electric wire keeps a horizontal display is displayed by an angle scale mark fixedly connected on the driven gear body arranged on the outer side of a third supporting rod, the position of the electric wire is offset or does not keep a horizontal state, the electric wire can be adjusted by rotating a driving gear body meshed with the outer side of the driven gear body, the gear shaft is fixedly connected with the output shaft of the adjustable motor, namely, the adjustable motor starts to rotate so as to drive the gear shaft fixedly connected with the output shaft of the adjustable motor to rotate, so that the driving gear body is driven to rotate, the driven gear body in meshed connection with the driving gear body is driven to rotate to adjust the position, the special-shaped hole fixedly connected to the center of the driven gear body is driven to rotate, the electric wire passing through the special-shaped hole is further corrected to rotate, the actually required angle position of the electric wire in the rotating cabling process can be flexibly adjusted, the rotation resistance and the inertia force caused by the electric wire can be eliminated, the electric wire is finally positioned at the horizontal position, and the structural damage caused by torsion force is eliminated;

further, the motor assembly comprises an adjustable motor and a motor controller, one side of the gear shaft is fixedly connected with the adjustable motor, an output shaft of the adjustable motor is fixedly connected with the gear shaft, and the lower side of the adjustable motor is fixedly connected with the motor controller.

Further, the control device comprises an angle identification controller and a feedback cable, wherein the angle identification controller is fixedly connected to the lower side of the adjustable motor, the angle identification controller is electrically connected with the motor controller, the feedback cable is arranged on the outer side of the angle identification controller, and the feedback cable is connected with the motor controller.

The angle recognition controller is fixedly connected to the lower side of the adjustable motor to perform angle recognition control, the detector is fixedly connected to the upper side of the third supporting rod to perform angle detection, angle detection data are transmitted to the angle recognition controller, the angle recognition controller further transmits the data to the motor controller, and the motor controller further performs feedback control on the speed regulation and steering of the adjustable motor according to analysis of the angle detection data, so that real-time deviation correction and speed regulation are realized to meet the requirement of maximizing effective rotation cabling operation;

further, the first anisotropic conductor comprises a fan-shaped conductor structure, a semicircular conductor structure, a rectangular conductor structure and a polygonal conductor structure, the first anisotropic conductor fixedly connected with the axis of the stranding die frame can be one of the fan-shaped conductor structure, the semicircular conductor structure, the rectangular conductor structure and the polygonal conductor structure, and the shapes of the second anisotropic conductor and the opposite conductor in the third stranding die are correspondingly matched with the first anisotropic conductor.

Furthermore, the outer gear shape of the driven gear body can be a cylindrical gear or a conical gear.

Compared with the prior art, the utility model provides the rotary cabling combined die which has the following beneficial effects:

1. according to the rotary cabling combined die, through the interaction among the electric wires, the first twisting die, the second twisting die, the third twisting die, the detector, the driven gear, the driving gear, the motor component, the control device, the first fixing seat, the first supporting rod, the twisting die frame, the first opposite conductor and the first die shell, the shaping effect of the first twisting die cannot be damaged due to the resistance of the second twisting die or the third twisting die or more twisting dies in the twisting process of a cable core, particularly, conductors and cable cores of special-shaped structures can form stable structural shapes under the condition of no need of compressing deformation, the problem that small conductors or non-circular structures composed of insulated wire cores are kept in a stable shape under the condition of no need of stress and compression deformation is solved, or the special-shaped conductors are located in a horizontal position as straightening line stabilizing devices of the front channels of an extruder, the special-shaped conductors are powerful tools for guaranteeing the quality of a final product, and therefore, the non-circular twisting process of the small conductors is solved, the special-shaped structures of the cable can be kept, the best customer experience is achieved under the condition that the special-shaped structures of the cable are kept, and the best service life of the customer is achieved, and the comprehensive effects are achieved;

2. the rotary cabling combined die has the advantages that the speed and the direction of rotation can be regulated through the mutual coordination among the driven gear, the driving gear, the motor assembly and the control device, so that the state of the stranded cable core can be controlled or regulated, and the ideal cable core stranded structure can be achieved.

Drawings

FIG. 1 is a schematic view of the overall three-dimensional structure of the present utility model;

FIG. 2 is a schematic view of a first twisting mold structure according to the present utility model;

FIG. 3 is a schematic view of a second stranding die structure according to the present utility model;

FIG. 4 is a schematic view of a third twisting mold according to the present utility model;

fig. 5 is a schematic diagram of a first anisotropic conductor structure according to the present utility model.

In the figure: 1. an electric wire; 2. a first stranding die; 21. a first fixing seat; 22. a first support bar; 23. a stranding die frame; 24. a first anisotropic conductor; 241. a sector conductor structure; 242. a semicircular conductor structure; 243. a rectangular conductor structure; 244. a polygonal conductor structure; 25. a first mold shell; 3. a second twisting mold; 31. the second fixing seat; 32. a second support bar; 33. a bearing; 34. a second anisotropic conductor; 35. a second mold shell; 4. a third twisting mold; 41. a third fixing seat; 42. a third support bar; 5. a motor assembly; 51. an adjustable motor; 52. a motor controller; 6. a detector; 7. a driven gear; 71. a driven gear body; 72. angle graduation marks; 8. a drive gear; 81. a driving gear body; 82. a gear shaft; 9. a control device; 91. an angle recognition controller; 92. and feeding back the cable.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Examples

Referring to fig. 1-5, a rotary cabling combined die comprises an electric wire 1, wherein a first twisting die 2 is arranged on the outer side of the electric wire 1, a second twisting die 3 is arranged on one side of the first twisting die 2, a third twisting die 4 is arranged on one side of the second twisting die 3, a detector 6 is fixedly connected to the upper side of the third twisting die 4, a driven gear 7 is rotatably connected to the outer side of the third twisting die 4, a driving gear 8 is connected to the outer side of the driven gear 7 in a meshed manner, a motor assembly 5 is fixedly connected to one side of the driving gear 8, and a control device 9 is fixedly connected to the lower side of the motor assembly 5;

the first stranding die 2 comprises a first fixing seat 21, a first supporting rod 22, a stranding die frame 23, a first anisotropic conductor 24 and a first die housing 25, wherein the first fixing seat 21 is arranged on the outer side of the electric wire 1, the first supporting rod 22 is fixedly connected to the upper side of the first fixing seat 21, the first die housing 25 is fixedly connected to the upper side of the first supporting rod 22, the stranding die frame 23 is fixedly connected to the inner side of the first die housing 25, the first anisotropic conductor 24 is fixedly connected to the axial center position of the stranding die frame 23, a through hole is formed in the upper side of the first anisotropic conductor 24, and the electric wire 1 penetrates through the through hole.

Further, the second stranding die 3 includes a second fixing seat 31, a second supporting rod 32, a bearing 33, a second anisotropic conductor 34 and a second die housing 35, the second fixing seat 31 is disposed on one side of the first die housing 25, the second supporting rod 32 is fixedly connected to the upper side of the second fixing seat 31, the second die housing 35 is fixedly connected to the upper side of the second supporting rod 32, the bearing 33 is fixedly connected to the inner side of the second die housing 35, the second anisotropic conductor 34 is fixedly connected to the central position of the bearing 33, the second anisotropic conductor 34 can freely rotate in the bearing 33, a through hole is formed in the central position of the second anisotropic conductor 34, and the electric wire 1 penetrates through the inner side of the through hole and extends out to two sides respectively.

The second twisting mold 3 is to install the required second anisotropic conductor 34 inside the bearing 33, so that the shape of the front twisting can be well maintained after passing through the second anisotropic conductor 34 when the electric wire 1 rotates, but the rotation resistance and inertia force brought by the electric wire 1 can be eliminated due to self-transmission of the bearing 33 when the resistance or the reaction force is encountered;

further, the third twisting mold 4 comprises a third fixing seat 41 and a third supporting rod 42, the third fixing seat 41 is arranged on one side of the second mold shell 35, the third supporting rod 42 is fixedly connected to the upper side of the third fixing seat 41, a different conductor is also arranged on the upper side of the third supporting rod 42, a through hole is formed in the inner side of the different conductor, and the electric wire 1 passes through the through hole.

Further, the driven gear 7 includes a driven gear body 71 and an angle scale mark 72, the driven gear body 71 is rotatably connected to the outer side of the third support rod 42, a different conductor is fixedly connected to the axis position of the driven gear body 71, the shape of the different conductor is the same as that of the second different conductor 34, the angle scale mark 72 is fixedly connected to one side of the driven gear body 71 far away from the third support rod 42, and the center position of the angle scale mark 72 is vertically arranged.

Further, the driving gear 8 includes a driving gear body 81 and a gear shaft 82, the driving gear body 81 is engaged with the outer side of the driven gear body 71, and the gear shaft 82 is fixedly connected to the central position of the driving gear body 81.

The electric wire 1 passes through the first opposite conductor 24 in the first twisting mold 2, and enters the second opposite conductor 34 after passing through the first opposite conductor 24, then passes through the second opposite conductor 34, and sequentially passes through a through hole formed in the center of the driven gear body 71, and then passes through the opposite conductor arranged in the third twisting mold 4, so that the whole electric wire 1 is always kept in a horizontal state in the passing action process, wherein whether the whole electric wire 1 is kept in a horizontal display is displayed through an angle scale mark 72 fixedly connected to the driven gear body 71 arranged on the outer side of the third supporting rod 42, the position of the electric wire 1 is offset or not kept in a horizontal state, the electric wire 1 can be adjusted in a rotating way through a driving gear body 81 in meshed connection with the outer side of the driven gear body 71, and the gear shaft 82 is fixedly connected with an output shaft of the adjustable motor 51, namely, the adjustable motor 51 starts to rotate and then drives the gear shaft 82 fixedly connected with the driven gear body to rotate, and further drives the driving gear body 81 to rotate, the electric wire 1 is further driven to further drive the driven gear body to rotate, the electric wire 1 is further drive the driven gear body to rotate, and the electric wire 1 is further rotated and the position of the electric wire 1 is further rotated to be in a special-shaped hole to be further rotated, and the special-shaped resistance is further rotated, and the electric wire is further required to be adjusted in the position of the electric wire is rotated, and the electric wire is further rotated and the position is further rotated and is required to be adjusted by the electric wire 1 to be rotated;

further, the motor assembly 5 includes an adjustable motor 51 and a motor controller 52, one side of the gear shaft 82 is fixedly connected with the adjustable motor 51, an output shaft of the adjustable motor 51 is fixedly connected with the gear shaft 82, and a lower side of the adjustable motor 51 is fixedly connected with the motor controller 52.

Further, the control device 9 includes an angle recognition controller 91 and a feedback cable 92, the angle recognition controller 91 is fixedly connected to the lower side of the adjustable motor 51, the angle recognition controller 91 is electrically connected to the motor controller 52, the feedback cable 92 is disposed on the outer side of the angle recognition controller 91, and the feedback cable 92 is connected to the motor controller 52.

The angle recognition control is performed through an angle recognition controller 91 fixedly connected to the lower side of the adjustable motor 51, then angle detection is performed through a detector 6 fixedly connected to the upper side of the third supporting rod 42, angle detection data are transmitted to the angle recognition controller 91, the angle recognition controller 91 further transmits the data to the motor controller 52, and the motor controller 52 further performs feedback control on the speed regulation and steering of the adjustable motor 51 according to the analysis of the angle detection data, so that real-time deviation correction and speed regulation are realized to meet the maximum effective rotation cabling operation;

further, the first hetero-conductor 24 includes a fan-shaped conductor structure 241, a semicircular conductor structure 242, a rectangular conductor structure 243 and a polygonal conductor structure 244, and the first hetero-conductor 24 fixedly connected to the axis of the twisting mold frame 23 may be one of the fan-shaped conductor structure 241, the semicircular conductor structure 242, the rectangular conductor structure 243 and the polygonal conductor structure 244, and the shapes of the corresponding second hetero-conductor 34 and the hetero-conductor in the third twisting mold 4 are matched with those of the first hetero-conductor 24.

Further, the outer gear shape of the driven gear body 71 may be a cylindrical gear or a conical gear.

Specific use and action of the embodiment:

when in use, the electric wire 1 passes through the first opposite conductor 24 in the first twisting mold 2, passes through the first opposite conductor 24 and then enters the second opposite conductor 34, then passes through the second opposite conductor 34, sequentially passes through the through hole formed in the center of the driven gear body 71, passes through the opposite conductor arranged in the third twisting mold 4 and sequentially ensures that the whole electric wire 1 always keeps a horizontal state in the passing action process, wherein whether the whole electric wire 1 keeps a horizontal display is displayed through the angle scale marks 72 fixedly connected on the driven gear body 71 arranged on the outer side of the third supporting rod 42, when the position of the electric wire 1 is offset or does not keep a horizontal state, the electric wire 1 can be adjusted by rotating the driving gear body 81 meshed with the outer side of the driven gear body 71, the gear shaft 82 is fixedly connected with the output shaft of the adjustable motor 51, that is, the adjustable motor 51 starts to rotate and drives the gear shaft 82 fixedly connected with the output shaft thereof to rotate, so as to drive the driving gear body 81 to rotate, further drive the driven gear body 71 in meshed connection with the driving gear body to rotate and adjust the position, further drive the special-shaped hole fixedly connected with the center of the driven gear body 71 to rotate, further correct the electric wire 1 passing through the special-shaped hole to rotate, further flexibly adjust the actually required angle position of the electric wire 1 in the rotating cabling process, and eliminate the rotation resistance and inertia force caused by the electric wire 1, further ensure that the electric wire 1 is in a horizontal position finally, and also eliminate the structural damage caused by torsion;

the angle recognition control is performed through an angle recognition controller 91 fixedly connected to the lower side of the adjustable motor 51, then angle detection is performed through a detector 6 fixedly connected to the upper side of the third supporting rod 42, angle detection data are transmitted to the angle recognition controller 91, the angle recognition controller 91 further transmits the data to the motor controller 52, and the motor controller 52 further performs feedback control on the speed regulation and steering of the adjustable motor 51 according to the analysis of the angle detection data, so that real-time deviation correction and speed regulation are realized to meet the maximum effective rotation cabling operation;

finally, it should be noted that the number of the first stranding dies 2 can be increased or decreased according to the requirement when the combined die is used, the internal structure of the first stranding dies is consistent with the shape of the designed stranding, the first stranding dies are necessary and cannot be lacked, the second stranding dies 3 or the third stranding dies 4 are used for stabilizing the shape and preventing loosening, and meanwhile, the rotation resistance is mainly eliminated for ensuring the stability and the compactness of the stranding structure, generally, two structures are respectively provided, namely the second stranding dies 3 and the third stranding dies 4, and the two modes can be arranged and increased and decreased behind the first stranding dies 2 according to the requirement of products so as to meet the actual production requirement;

the second twisting mold 3 is provided with a second anisotropic conductor 34 inside the bearing 33, so that the shape of the front twisting can be well maintained after passing through the second anisotropic conductor 34 when the electric wire 1 rotates, but the rotation resistance and inertia force of the electric wire 1 can be eliminated due to self-transmission of the bearing 33 when the resistance or reaction force is encountered.

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

Claims (9)

1. The utility model provides a rotary cabling assembling die, includes electric wire (1), and electric wire (1) outside is provided with first stranding mould (2), and one side of first stranding mould (2) is provided with second stranding mould (3), its characterized in that: a third twisting die (4) is arranged on one side of the second twisting die (3), a detector (6) is fixedly connected to the upper side of the third twisting die (4), a driven gear (7) is rotationally connected to the outer side of the third twisting die (4), a driving gear (8) is connected to the outer side of the driven gear (7) in a meshed mode, a motor assembly (5) is fixedly connected to one side of the driving gear (8), and a control device (9) is fixedly connected to the lower side of the motor assembly (5);

the first stranding die (2) comprises a first fixing seat (21), a first supporting rod (22), a stranding die frame (23), a first opposite conductor (24) and a first die housing (25), wherein the first fixing seat (21) is arranged on the outer side of the electric wire (1), the first supporting rod (22) is fixedly connected to the upper side of the first fixing seat (21), the first die housing (25) is fixedly connected to the upper side of the first supporting rod (22), the stranding die frame (23) is fixedly connected to the inner side of the first die housing (25), the first opposite conductor (24) is fixedly connected to the axis position of the stranding die frame (23), and a through hole is formed in the upper side of the first opposite conductor (24) and the inner side of the through hole is formed in the electric wire (1) penetrating through the through hole.

2. A rotary cabling assembling die according to claim 1, wherein: the second stranding die (3) comprises a second fixing seat (31), a second supporting rod (32), a bearing (33), a second opposite conductor (34) and a second die housing (35), wherein one side of the first die housing (25) is provided with the second fixing seat (31), the second supporting rod (32) is fixedly connected to the upper side of the second fixing seat (31), the second die housing (35) is fixedly connected to the upper side of the second supporting rod (32), the bearing (33) is fixedly connected to the inner side of the second die housing (35), the second opposite conductor (34) is fixedly connected to the central position of the bearing (33), the second opposite conductor (34) can rotate freely in the bearing (33), a through hole is formed in the central position of the second opposite conductor (34), and the electric wire (1) penetrates through the inner side of the through hole and extends to two sides of the through hole respectively.

3. A rotary cabling assembling die according to claim 2, wherein: the third twisting die (4) comprises a third fixing seat (41) and a third supporting rod (42), one side of the second die shell (35) is provided with the third fixing seat (41), the upper side of the third fixing seat (41) is fixedly connected with the third supporting rod (42), the upper side of the third supporting rod (42) is also provided with a different conductor, the inner side of the different conductor is provided with a through hole, and the inner side of the through hole is also provided with the electric wire (1) penetrating through the through hole.

4. A rotary cabling assembling die according to claim 3, wherein: the driven gear (7) comprises a driven gear body (71) and angle scale marks (72), the driven gear body (71) is rotationally connected to the outer side of the third supporting rod (42), an opposite conductor is fixedly connected to the axis position of the driven gear body (71), the shape of the opposite conductor is identical to that of the second opposite conductor (34), the angle scale marks (72) are fixedly connected to one side, away from the third supporting rod (42), of the driven gear body (71), and the center position of the angle scale marks (72) is vertically arranged.

5. The rotary cabling assembling die according to claim 4, wherein: the driving gear (8) comprises a driving gear body (81) and a gear shaft (82), the driving gear body (81) is connected to the outer side of the driven gear body (71) in a meshed mode, and the gear shaft (82) is fixedly connected to the central position of the driving gear body (81).

6. The rotary cabling assembling die according to claim 5, wherein: the motor assembly (5) comprises an adjustable motor (51) and a motor controller (52), one side of the gear shaft (82) is fixedly connected with the adjustable motor (51), an output shaft of the adjustable motor (51) is fixedly connected with the gear shaft (82), and the lower side of the adjustable motor (51) is fixedly connected with the motor controller (52).

7. The rotary cabling assembling die of claim 6, wherein: the control device (9) comprises an angle identification controller (91) and a feedback cable (92), wherein the angle identification controller (91) is fixedly connected to the lower side of the adjustable motor (51), the angle identification controller (91) is electrically connected with the motor controller (52), the feedback cable (92) is arranged on the outer side of the angle identification controller (91), and the feedback cable (92) is connected with the motor controller (52).

8. A rotary cabling assembling die according to claim 2, wherein: the first opposite conductor (24) comprises a fan-shaped conductor structure (241), a semicircular conductor structure (242), a rectangular conductor structure (243) and a polygonal conductor structure (244), the first opposite conductor (24) fixedly connected with the axis of the stranding die frame (23) can be one of the fan-shaped conductor structure (241), the semicircular conductor structure (242), the rectangular conductor structure (243) or the polygonal conductor structure (244), and the shape of the opposite conductor in the second opposite conductor (34) and the third stranding die (4) is matched with that of the first opposite conductor (24).

9. The rotary cabling assembling die according to claim 4, wherein: the outer gear shape of the driven gear body (71) can be a cylindrical gear or a conical gear.