CN114334285A - Automatic winding displacement braider of cable production - Google Patents

Abstract

The invention belongs to the technical field of cables, and particularly relates to an automatic cable arranging and braiding machine for cable production, wherein when a cable is braided at a fixed length, one end of a lead is fixed by rotating a round table, the other end of the lead is fixed by a clamping mechanism, the lead is always in a tensioning state under the elastic action of a supporting spring, and meanwhile, the lead is guided by moving a circular plate, so that the tensioning effect of the lead is further improved, the lead is prevented from being loosened in the braiding process, and the forming effect of the cable is ensured; when the wire is woven by the device, the wires are uniformly arranged along the axis, when one end of each wire rotates, the wires are separated by the movable circular plate, and the wires are gradually and uniformly wound together from the rotary circular table to the fixed circular plate along with the uniform movement of the movable circular plate from the rotary circular table to the fixed circular plate, so that the uniform winding density of the wires at each position on the cable is ensured.

Description

Automatic winding displacement braider of cable production

Technical Field

The invention belongs to the technical field of cables, and particularly relates to an automatic cable arranging and knitting machine for cable production.

Background

The cable has many uses, and is mainly used for controlling installation, connecting equipment, transmitting power and the like. The cable is generally composed of a plurality of wires with insulating protective layers, the insulated wires are twisted together according to a certain density, and the electric wave radiated by each wire in transmission can be counteracted by the electric wave emitted by other wires, so that the degree of signal interference can be effectively reduced.

At present, the following problems exist in the process of arranging and weaving the cable during the production of the cable: (1) when the cable is woven in a fixed length mode, the fact that each conducting wire is in a tensioning state during weaving is difficult to guarantee, so that the conducting wires are prone to loosening, and the forming effect of the cable is affected; (2) the in-process is woven, each wire is loose form crisscross coiling earlier and is in the same place, and along with wire one end lasts the rotation, the coiling degree of each wire increases gradually, and this process is difficult to guarantee that wire winding density everywhere on the cable is even, can influence the shaping effect of cable equally.

Disclosure of Invention

In order to solve the technical problems, the invention adopts the following technical scheme: an automatic cable arranging and knitting machine for cable production comprises a bottom plate, wherein a vertical fixed circular plate is fixedly arranged above the bottom plate through a first support, a fixed circular ring which is superposed with the axis of the fixed circular plate is arranged at the position, behind the first support, above the bottom plate through a second support, and a rotating circular table which is superposed with the axis of the fixed circular plate is rotatably arranged in the fixed circular ring; the utility model discloses a wire section of thick bamboo, including fixed plectane, fixed plectane is last to have seted up a plurality of bar logical groove along its circumference, and the bar leads to the inslot and has chucking mechanism along the radial slidable mounting of fixed plectane, and chucking mechanism includes the bobbin of slidable mounting in the logical inslot of bar, and the equal fixed mounting in bobbin both ends has the spacing ring with fixed plectane surface sliding fit, and equal symmetrical fixed mounting has two elastic telescopic rod that are parallel to each other on the spacing ring of every bobbin rear end, and the equal fixed mounting of tip that two elastic telescopic rod are relative has the fixture block.

The limiting ring at the front end of each wire barrel is fixedly provided with a moving piece, the surface of the fixed circular plate is provided with a fixed piece corresponding to the position of each moving piece, and a supporting spring is fixedly connected between the fixed piece and the moving piece.

A plurality of L-shaped plates which are uniformly arranged along the circumferential direction of the fixed circular plate are slidably arranged on the fixed circular plate, and the L-shaped plates axially penetrate through the fixed circular plate along the fixed circular plate; a movable circular plate which is positioned between the fixed circular plate and the rotary circular table and is superposed with the axis of the rotary circular table is fixedly installed between the plurality of L-shaped plates, circular grooves with the same number as the strip-shaped through grooves are uniformly formed in the movable circular plate along the circumferential direction of the movable circular plate, and the movable circular plate is axially penetrated through the circular grooves along the movable circular plate.

The rotary round platform is uniformly provided with wire slots with the same number as the strip-shaped through slots along the circumferential direction, the wire slots axially penetrate through the rotary round platform along the rotary round platform, the positions, corresponding to each wire slot, on the rear end surface of the rotary round platform are provided with air slots, the inner ends of the air slots are communicated with the wire slots and are provided with first sealing columns in a sliding manner, and the end parts of the first sealing columns are fixedly provided with arc-shaped pressing sheets positioned in the wire slots; the outer end of the air groove is provided with second sealing columns in an axial sliding mode along the rotating circular table, the second sealing columns are fixedly connected through a connecting ring, the rear end face of the rotating circular table is provided with an adjusting screw rod in a rotating mode, and the adjusting screw rod penetrates through the connecting ring in a threaded fit mode.

As a preferred technical scheme of the invention, a plurality of balls are uniformly arranged on the inner wall of the circular groove along the circumferential direction of the circular groove.

As a preferable technical scheme of the invention, the position of the fixed circular plate corresponding to each L-shaped plate is rotatably provided with a roller which is matched with the surface of the L-shaped plate in a rolling way.

As a preferred technical scheme of the invention, the end faces of the first sealing column and the second sealing column are respectively provided with a sealing ring which is in sealing fit with the air groove; and a connecting spring is arranged between the end surface of the first sealing column and the inner wall of the air groove.

As a preferred technical scheme of the invention, the opposite end parts of the two elastic telescopic rods on the limiting ring are fixedly provided with first guide blocks, and the bottom surfaces of the first guide blocks are arc-shaped surfaces; the fixed circular plate surface is located the equal fixed mounting in position that bar logical inslot end corresponds every first guide block has the second guide block, and the top surface of second guide block is the arcwall face.

As a preferred technical scheme of the invention, the rotating circular table is fixedly sleeved with a driven gear ring, the second bracket is fixedly provided with a bidirectional motor through a motor base, and an output shaft at one end of the bidirectional motor is fixedly provided with a first driving gear meshed with the driven gear ring.

As a preferred technical scheme of the invention, a second driving gear is fixedly arranged on an output shaft at the other end of the bidirectional motor; one of the L-shaped plates is fixedly provided with a sliding plate in sliding fit with the bottom plate, the bottom plate is rotatably provided with a horizontal lead screw through a lead screw support, the lead screw penetrates through the sliding plate in a thread fit mode, and the end part of the lead screw is fixedly provided with a driven gear meshed with the second driving gear.

As a preferred technical scheme of the invention, a synchronous mechanism is arranged on the fixed circular plate, the synchronous mechanism comprises support plates with the same number as the strip-shaped through grooves, the support plates are fixedly arranged on the circumferential surface of the fixed circular plate and correspond to the strip-shaped through grooves in position, horizontal shafts parallel to the axis of the fixed circular plate are rotatably arranged on the support plates, and reels and synchronous gears are fixedly arranged on the horizontal shafts; the reel is wound with a pull rope, the end part of the pull rope is fixedly connected with the corresponding moving piece, and the circumferential surface of the fixed circular plate is rotatably provided with a synchronous gear ring meshed with the synchronous gear.

The invention has at least the following beneficial effects: (1) when the fixed-length weaving machine is used for weaving cables at fixed length, one end of each wire is fixed through the rotary circular table, the other end of each wire is fixed through the clamping mechanism, the wires are always in a tensioning state under the elastic action of the supporting springs, and meanwhile, the wires are guided through the movable circular plate, so that the tensioning effect of the wires is further improved, the wires are prevented from loosening in the weaving process, and the forming effect of the cables is guaranteed.

(2) During the process of weaving the wires, the wires are uniformly arranged along the axis, and during the process of rotating one end of each wire, the wires are separated by the movable circular plate, and along with the uniform movement of the movable circular plate from the rotary circular table to the fixed circular plate, the wires are gradually and uniformly woven together from the rotary circular table to the fixed circular plate, so that the uniform winding density of the wires at each position on the cable is ensured; according to the invention, each clamping mechanism moves synchronously through the synchronous mechanism, so that the end part of each lead moves synchronously, the lead is ensured to be in a tensioning state, and the winding density of the lead is ensured to be uniform.

Drawings

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

Fig. 1 is a schematic first perspective view of an automatic flat cable knitting machine for cable production according to an embodiment of the present invention.

Fig. 2 is an enlarged schematic view of a point a in fig. 1.

Fig. 3 is a schematic second perspective view of the cable production automatic flat cable knitting machine according to the embodiment of the present invention.

Fig. 4 is an enlarged schematic view of fig. 3 at B.

Fig. 5 is an enlarged schematic view at C in fig. 3.

Fig. 6 is a side view of an automated flat cable knitting machine for cable production according to an embodiment of the present invention.

Fig. 7 is a front view showing an inner structure of a moving circular plate according to an embodiment of the present invention.

FIG. 8 is a side view of a portion of the internal structure of the rotary turret according to an embodiment of the present invention.

In the figure: 1. a base plate; 2. a first bracket; 3. fixing the circular plate; 301. a strip-shaped through groove; 4. a second bracket; 5. fixing the circular ring; 6. rotating the circular truncated cone; 601. a wire slot; 7. a chucking mechanism; 701. a bobbin; 702. a limiting ring; 703. an elastic telescopic rod; 704. a clamping block; 705. a first guide block; 8. moving the sheet; 9. a fixing sheet; 10. a support spring; 11. an L-shaped plate; 12. moving the circular plate; 121. a circular groove; 13. a first seal post; 14. arc-shaped pressing sheets; 15. a second seal post; 16. a connecting ring; 17. adjusting the screw rod; 18. a ball bearing; 19. a roller; 20. a seal ring; 21. a connecting spring; 22. a second guide block; 23. a driven gear ring; 24. a bi-directional motor; 25. a first drive gear; 26. a second drive gear; 27. a sliding plate; 28. a lead screw bracket; 29. a lead screw; 30. a driven gear; 31. a synchronization mechanism; 311. a support plate; 312. a horizontal axis; 313. a reel; 314. a synchronizing gear; 315. pulling a rope; 316. and synchronizing the ring gears.

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, 3 and 4, the present embodiment provides an automatic cable arranging knitting machine for cable production, which includes a base plate 1, a vertical fixed circular plate 3 is fixedly mounted above the base plate 1 through a first bracket 2, a fixed circular ring 5 coinciding with the axis of the fixed circular plate 3 is mounted at a position behind the first bracket 2 above the base plate 1 through a second bracket 4, and a rotating circular table 6 coinciding with the axis of the fixed circular ring 5 is rotatably mounted in the fixed circular ring 5; a plurality of strip-shaped through grooves 301 are formed in the fixed circular plate 3 along the circumferential direction of the fixed circular plate, clamping mechanisms 7 are arranged in the strip-shaped through grooves 301 in a sliding mode along the radial direction of the fixed circular plate 3, each clamping mechanism 7 comprises a bobbin 701 which is arranged in the strip-shaped through groove 301 in a sliding mode, limiting rings 702 which are in sliding fit with the surfaces of the fixed circular plate 3 are fixedly arranged at two ends of the bobbin 701, two elastic telescopic rods 703 which are parallel to each other are symmetrically and fixedly arranged on the limiting ring 702 at the rear end of each bobbin 701, and clamping blocks 704 are fixedly arranged at opposite end portions of the two elastic telescopic rods 703; in the weaving process, the tail end of the wire extends into the wire barrel 701, the clamping block 704 clamps the wire under the action of the elastic force of the two elastic telescopic rods 703, and the tail end of the wire is prevented from falling off from the wire barrel 701.

As shown in fig. 3 and 4, the opposite ends of the two elastic telescopic rods 703 on the limiting ring 702 are both fixedly provided with a first guide block 705, and the bottom surface of the first guide block 705 is an arc surface; the surface of the fixed circular plate 3 is positioned at the inner end of the strip-shaped through groove 301 and is fixedly provided with a second guide block 22 corresponding to the position of each first guide block 705, and the top surface of each second guide block 22 is an arc-shaped surface.

As shown in fig. 1 and 2, a moving plate 8 is fixedly mounted on the limiting ring 702 at the front end of each bobbin 701, a fixing plate 9 is mounted on the surface of the fixed circular plate 3 at a position corresponding to each moving plate 8, and a supporting spring 10 is fixedly connected between the fixing plate 9 and the moving plate 8.

As shown in fig. 2 and 3, the fixed circular plate 3 is provided with the synchronizing mechanism 31, the synchronizing mechanism 31 comprises a support plate 311 with the same number as the strip-shaped through grooves 301, the support plate 311 is fixedly arranged on the circumferential surface of the fixed circular plate 3 and corresponds to the strip-shaped through grooves 301 in position, a horizontal shaft 312 parallel to the axis of the fixed circular plate 3 is rotatably arranged on the support plate 311, a reel 313 and a synchronizing gear 314 are fixedly arranged on the horizontal shaft 312, and the reel 313 is positioned in front of the synchronizing gear 314; a pull rope 315 is wound around the reel 313, the end of the pull rope 315 is fixedly connected to the corresponding movable piece 8, and a synchronizing ring gear 316 that meshes with the synchronizing gear 314 is rotatably attached to the circumferential surface of the fixed disk 3.

In the weaving process, the conducting wire pulls the clamping mechanism 7 to move towards the axis of the fixed circular plate 3 along the strip-shaped through groove 301, the moving plate 8 gradually compresses the supporting spring 10 until the first guide block 705 is attached to the second guide block 22 and is far away from the second guide block 22 under the thrust action of the second guide block 22, the tail end of the conducting wire is not clamped by the clamping mechanism 7 any more, and the tail end of the conducting wire is pulled away from the bobbin 701; in the above process, the moving plate 8 drives the pulling rope 315 to move, the pulling rope 315 drives the reels 313, the horizontal shaft 312 and the synchronizing gears 314 to rotate, and since each synchronizing gear 314 is meshed with the synchronizing ring 316, the rotating speeds of each reel 313 are consistent, that is, the moving plate 8, the clamping mechanism 7 and the tail ends of the wires move along the strip-shaped through groove 301, so that the tail ends of the wires are ensured to move towards the axis of the fixed circular plate 3 synchronously.

As shown in fig. 3 and 7, a plurality of L-shaped plates 11 uniformly arranged along the circumferential direction are slidably mounted on the fixed circular plate 3, the L-shaped plates 11 axially penetrate through the fixed circular plate 3 along the fixed circular plate 3, and a roller 19 in rolling fit with the surface of each L-shaped plate 11 is rotatably mounted on the fixed circular plate 3 corresponding to the position of each L-shaped plate 11; a movable circular plate 12 which is positioned between the fixed circular plate 3 and the rotary circular table 6 and is superposed with the axis of the rotary circular table 6 is fixedly arranged between the plurality of L-shaped plates 11, circular grooves 121 which are the same as the strip-shaped through grooves 301 in number are uniformly formed in the movable circular plate 12 along the circumferential direction of the movable circular plate, the circular grooves 121 axially penetrate through the movable circular plate 12 along the movable circular plate 12, and a plurality of balls 18 are uniformly arranged on the inner wall of each circular groove 121 along the circumferential direction of the circular groove to reduce the friction force between the circular groove 121 and the wire.

The wire passes through the circular groove 121, the movable circular plate 12 plays a role in tensioning the wire and simultaneously divides the wire into two parts, wherein the part close to the rotating circular table 6 can be woven, and the part close to the fixed circular plate 3 cannot be woven; in the process of weaving the wires, the L-shaped plate 11 drives the movable circular plate 12 to move from the rotary circular table 6 to the fixed circular plate 3 at a constant speed, so that the wires can be gradually and uniformly woven from the rotary circular table 6 to the fixed circular plate 3.

As shown in fig. 3, 5 and 8, the rotary circular truncated cone 6 is uniformly provided with the same number of slots 601 as the number of the strip-shaped through slots 301 along the circumferential direction thereof, the slots 601 axially penetrate through the rotary circular truncated cone 6 along the rotary circular truncated cone 6, the rear end surface of the rotary circular truncated cone 6 is provided with an air groove 602 corresponding to each slot 601, the inner end of the air groove 602 is communicated with the slots 601 and is slidably provided with a first sealing column 13, and the end part of the first sealing column 13 is fixedly provided with an arc-shaped pressing sheet 14 positioned in the slot 601; a second sealing column 15 is axially and slidably mounted at the outer end of the air groove 602 along the rotary circular table 6, and sealing rings 20 in sealing fit with the air groove 602 are mounted on the end surfaces of the first sealing column 13 and the second sealing column 15; a connecting spring 21 is arranged between the end surface of the first sealing column 13 and the inner wall of the air groove 602; the second sealing columns 15 are fixedly connected through a connecting ring 16, an adjusting screw 17 is rotatably mounted on the rear end face of the rotary circular table 6, and the adjusting screw 17 penetrates through the connecting ring 16 in a threaded fit mode.

The head of the wire is left in the wire slot 601 after the wire passes through the wire slot 601, the adjusting screw 17 is rotated to drive the connecting ring 16 to move, the connecting ring 16 drives the second sealing column 15 to move, the second sealing column 15 extrudes air in the air slot 602, the first sealing column 13 pushes the arc-shaped pressing sheet 14 to extrude the wire under the action of air pressure until the arc-shaped pressing sheet 14 presses the wire against the inner wall of the wire slot 601, and therefore the fixing of the head of the wire is completed.

As shown in fig. 6, a driven gear ring 23 is fixedly sleeved on the rotary circular table 6, a bidirectional motor 24 is fixedly mounted on the second bracket 4 through a motor base, and a first driving gear 25 meshed with the driven gear ring 23 is fixedly mounted on an output shaft at one end of the bidirectional motor 24; a second driving gear 26 is fixedly arranged on an output shaft at the other end of the bidirectional motor 24; a sliding plate 27 in sliding fit with the bottom plate 1 is fixedly arranged on one of the L-shaped plates 11, a horizontal lead screw 29 is rotatably arranged on the bottom plate 1 through a lead screw bracket 28, the lead screw 29 penetrates through the sliding plate 27 in a threaded fit manner, and a driven gear 30 meshed with the second driving gear 26 is fixedly arranged at the end part of the lead screw 29.

The working process of the automatic flat cable knitting machine for cable production in the embodiment is as follows: a wire arranging step: each wire sequentially passes through the wire slot 601, the circular slot 121 and the wire barrel 701, the tail end of each wire is tightly clamped by the clamping block 704 under the elastic action of the two elastic telescopic rods 703, and the adjusting screw 17 is rotated to drive the connecting ring 16 to move, so that the head of each wire is fixed.

Weaving: the bidirectional motor 24 drives the first driving gear 25 and the second driving gear 26 to synchronously rotate, the first driving gear 25 drives the driven gear ring 23, the rotary circular table 6 and the heads of all the wires to rotate, and the wires between the rotary circular table 6 and the movable circular plate 12 are wound together in a staggered manner, so that the weaving effect is achieved; meanwhile, the second driving gear 26 drives the driven gear 30 and the lead screw 29 to rotate, the lead screw 29 drives the sliding plate 27, the L-shaped plate 11 and the movable circular plate 12 to move from the rotary circular table 6 to the fixed circular plate 3 at a constant speed, the distance between the rotary circular table 6 and the movable circular plate 12 is gradually increased, and a lead between the rotary circular table 6 and the movable circular plate 12 is gradually woven and formed; the conducting wire pulls the clamping mechanism 7 to move towards the axis of the fixed circular plate 3 along the strip-shaped through groove 301, the moving piece 8 gradually compresses the supporting spring 10 until the first guide block 705 is attached to the second guide block 22 and is far away from the second guide block 22 under the action of thrust, the tail end of the conducting wire is not clamped by the clamping mechanism 7 any more, the tail end of the conducting wire is pulled out from the wire barrel 701, and the synchronizing mechanism 31 ensures that the tail end of each conducting wire synchronously moves towards the axis of the fixed circular plate 3; after weaving and forming, the adjusting screw rod 17 is rotated reversely to release the fixation of the head of the lead, the woven lead is taken down, the synchronous gear ring 316 is poked reversely, and the pull rope 315 is wound on the reel 313 to facilitate weaving of the next section of lead.

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 (8)

1. The utility model provides an automatic winding displacement braider of cable production, includes bottom plate (1), bottom plate (1) top has vertical fixed plectane (3) through first support (2) fixed mounting, and bottom plate (1) top is located the position at first support (2) rear and installs through second support (4) with fixed plectane (3) axis coincidence fixed ring (5), and fixed ring (5) internal rotation is installed rather than axis coincidence rotation round platform (6), its characterized in that: the wire winding mechanism is characterized in that a plurality of strip-shaped through grooves (301) are formed in the fixed circular plate (3) along the circumferential direction of the fixed circular plate, clamping mechanisms (7) are arranged in the strip-shaped through grooves (301) in a sliding mode along the radial direction of the fixed circular plate (3), each clamping mechanism (7) comprises a wire barrel (701) which is arranged in the strip-shaped through grooves (301) in a sliding mode, two ends of each wire barrel (701) are fixedly provided with limiting rings (702) which are in sliding fit with the surface of the fixed circular plate (3), two elastic telescopic rods (703) which are parallel to each other are symmetrically and fixedly arranged on each limiting ring (702) at the rear end of each wire barrel (701), and clamping blocks (704) are fixedly arranged at the opposite end portions of the two elastic telescopic rods (703);

a moving piece (8) is fixedly arranged on a limiting ring (702) at the front end of each wire barrel (701), a fixing piece (9) is arranged on the surface of the fixed circular plate (3) at a position corresponding to each moving piece (8), and a supporting spring (10) is fixedly connected between the fixing piece (9) and the moving piece (8);

a plurality of L-shaped plates (11) which are uniformly arranged along the circumferential direction of the fixed circular plate (3) are slidably arranged on the fixed circular plate (3), and the L-shaped plates (11) axially penetrate through the fixed circular plate (3) along the fixed circular plate (3); a movable circular plate (12) which is positioned between the fixed circular plate (3) and the rotary circular table (6) and is superposed with the axis of the rotary circular table (6) is fixedly arranged between the L-shaped plates (11), circular grooves (121) with the same number as the strip-shaped through grooves (301) are uniformly formed in the movable circular plate (12) along the circumferential direction of the movable circular plate, and the circular grooves (121) axially penetrate through the movable circular plate (12) along the movable circular plate (12);

the rotary circular table (6) is uniformly provided with wire grooves (601) with the same number as the strip-shaped through grooves (301) along the circumferential direction, the wire grooves (601) axially penetrate through the rotary circular table (6) along the rotary circular table (6), the rear end face of the rotary circular table (6) is provided with an air groove (602) corresponding to each wire groove (601), the inner end of the air groove (602) is communicated with the wire grooves (601) and is provided with a first sealing column (13) in a sliding manner, and the end part of the first sealing column (13) is fixedly provided with an arc-shaped pressing sheet (14) positioned in the wire grooves (601); the outer end of the air groove (602) is provided with second sealing columns (15) in an axial sliding mode along the rotating circular truncated cone (6), the second sealing columns (15) are fixedly connected through a connecting ring (16), the rear end face of the rotating circular truncated cone (6) is rotatably provided with an adjusting screw rod (17), and the adjusting screw rod (17) penetrates through the connecting ring (16) in a threaded fit mode.

2. The cable production automatic flat cable knitting machine of claim 1, wherein: a plurality of balls (18) are uniformly arranged on the inner wall of the circular groove (121) along the circumferential direction.

3. The cable production automatic flat cable knitting machine of claim 1, wherein: and the fixed circular plate (3) is rotatably provided with a roller (19) which is matched with the surface of the L-shaped plate (11) in a rolling way at the position corresponding to each L-shaped plate (11).

4. The cable production automatic flat cable knitting machine of claim 1, wherein: sealing rings (20) which are in sealing fit with the air grooves (602) are arranged on the end faces of the first sealing column (13) and the second sealing column (15); and a connecting spring (21) is arranged between the end surface of the first sealing column (13) and the inner wall of the air groove (602).

5. The cable production automatic flat cable knitting machine of claim 1, wherein: the two opposite ends of the two elastic telescopic rods (703) on the limiting ring (702) are fixedly provided with first guide blocks (705), and the bottom surfaces of the first guide blocks (705) are arc-shaped surfaces; the surface of the fixed circular plate (3) is positioned at the inner end of the strip-shaped through groove (301) and is fixedly provided with a second guide block (22) corresponding to the position of each first guide block (705), and the top surface of each second guide block (22) is an arc-shaped surface.

6. The cable production automatic flat cable knitting machine of claim 1, wherein: the rotary circular table (6) is fixedly sleeved with a driven gear ring (23), the second support (4) is fixedly provided with a two-way motor (24) through a motor base, and an output shaft at one end of the two-way motor (24) is fixedly provided with a first driving gear (25) meshed with the driven gear ring (23).

7. The cable production automated flat cable knitting machine of claim 6, wherein: a second driving gear (26) is fixedly arranged on an output shaft at the other end of the bidirectional motor (24); a sliding plate (27) in sliding fit with the bottom plate (1) is fixedly mounted on one L-shaped plate (11), a horizontal lead screw (29) is rotatably mounted on the bottom plate (1) through a lead screw support (28), the lead screw (29) penetrates through the sliding plate (27) in a threaded fit mode, and a driven gear (30) meshed with the second driving gear (26) is fixedly mounted at the end part of the lead screw (29).

8. The cable production automatic flat cable knitting machine of claim 1, wherein: the synchronous mechanism (31) is mounted on the fixed circular plate (3), the synchronous mechanism (31) comprises support plates (311) with the same number as the strip-shaped through grooves (301), the support plates (311) are fixedly mounted on the circumferential surface of the fixed circular plate (3) and correspond to the strip-shaped through grooves (301), horizontal shafts (312) parallel to the axis of the fixed circular plate (3) are rotatably mounted on the support plates (311), and reels (313) and synchronous gears (314) are fixedly mounted on the horizontal shafts (312); the reel (313) is positioned in front of the synchronizing gear (314); a pull rope (315) is wound on the reel (313), the end part of the pull rope (315) is fixedly connected to the corresponding moving piece (8), and a synchronous gear ring (316) meshed with the synchronous gear (314) is rotatably arranged on the circumferential surface of the fixed circular plate (3).

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