CN118136346B - Intelligent stranded wire system with tension self-adaptive adjustment function - Google Patents
Intelligent stranded wire system with tension self-adaptive adjustment function Download PDFInfo
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- CN118136346B CN118136346B CN202410547375.3A CN202410547375A CN118136346B CN 118136346 B CN118136346 B CN 118136346B CN 202410547375 A CN202410547375 A CN 202410547375A CN 118136346 B CN118136346 B CN 118136346B
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Abstract
The invention belongs to the technical field of stranding machines, in particular to an intelligent stranding system with tension self-adaptive adjustment, which comprises the following components: the wire twisting frame is provided with a wire homogenizing mechanism for uniformly winding the wires on the wire twisting frame; the twisted wire frame is connected with a twisted wire bow and a balance bow which are fixedly connected through a pair of rotating frames; the wire winding bow is provided with a wire winding and unwinding mechanism for adjusting the tensioning degree of the wire, the wire winding and unwinding mechanism comprises a connecting frame, a pair of wire winding and unwinding wheels are connected to the connecting frame, the connecting frame is connected with a transition mechanism, and the two wire winding and unwinding wheels are respectively arranged on two sides of the transition mechanism; according to the invention, the wire winding and unwinding mechanism is connected to the wire twisting bow, so that the tensioning degree of the wire is adaptively adjusted, and the problem of over-tightening or over-loosening during wire winding is solved.
Description
Technical Field
The invention relates to the technical field of stranding machines, in particular to an intelligent stranding system with tension self-adaptive adjustment.
Background
The wire twisting machine is a winding device for producing wires, cables and the like, which are formed by mutually twisting a plurality of thin wires. After each single wire is stranded to form a stranded wire, the stranded wire is required to reach a wire collecting device through a traction device, and a finished wire barrel is finally obtained; the wire collecting device comprises a wire homogenizing device and a wire collecting disc arranged below the wire homogenizing device, and stranded wires are uniformly distributed on the wire collecting disc only when the wire homogenizing device is used for homogenizing wires left and right.
However, because the wire evening device needs to move left and right and the rotation speed of the wire winding drum changes, the situation that the too-high-tension stranded wire is tightened or the too-low-tension stranded wire is loosened can occur when the traction device conveys the stranded wire to the wire evening device, the too-high-tension stranded wire can be broken, the too-low-tension stranded wire can cause uneven wire winding distribution, and the normal operation of the wire twisting machine can be affected under the conditions.
Disclosure of Invention
Aiming at the defects of the prior art, the invention provides an intelligent stranded wire system with self-adaptive tension adjustment, which is used for self-adaptively adjusting the tensioning degree of wires by connecting a wire winding and unwinding mechanism on a stranded wire bow and aims at solving the problems in the background art.
In order to achieve the technical purpose, the specific technical scheme of the invention is as follows, the intelligent stranded wire system for tension self-adaptive adjustment provided by the invention comprises: the wire twisting frame is characterized in that two ends of the wire twisting frame are respectively connected with a wire inlet shaft and a wire outlet shaft in a rotating mode, a wire winding barrel is arranged in the wire twisting frame and used for winding wires, and a wire homogenizing mechanism is arranged on the wire twisting frame and used for uniformly winding the wires on the wire winding barrel; the twisted wire frame is connected with a twisted wire bow and a balance bow which are fixedly connected through a pair of rotating frames; the wire winding and unwinding mechanism comprises a connecting frame, a pair of wire winding and unwinding wheels are connected to the connecting frame, a transition mechanism is connected to the connecting frame, and the two wire winding and unwinding wheels are respectively arranged on two sides of the transition mechanism.
As a preferable technical scheme of the invention, the coiling and uncoiling wheel is coaxially and fixedly connected with a first rotary table, the first rotary table is rotationally connected with a rotary shaft, the rotary shaft is connected with a second rotary table which rotates together, and the first rotary table and the second rotary table are connected with mutually adsorbed magnet sheets.
As a preferable technical scheme of the invention, the rotating shafts are provided with limit convex strips, the second rotating discs are in sliding connection with the limit convex strips, a reset spring is connected between the first rotating discs and the second rotating discs, the connecting frame is provided with a rotating motor for driving the rotating shafts to rotate, and the two rotating shafts are fixedly connected with gears meshed with each other.
As a preferable technical scheme of the invention, a rotating ring is rotatably connected to the second turntable, a bracket is fixedly connected to the rotating ring, and a roller is connected to the bracket; the wire twisting bow is fixedly connected with a sliding rail matched with the roller, the sliding rail is provided with a plurality of convex parts, and when the roller rolls to the convex parts, the second turntable is in adsorption contact with the first turntable; and the sliding rail is fixedly connected with a plurality of probe frames, and the probe frames are provided with inductors for sensing whether the rollers move to the convex positions or not.
As a preferable technical scheme of the invention, the transition mechanism comprises a fixed disc, a plurality of sliding holes are uniformly formed in the fixed disc, a sliding frame is connected to the sliding holes in a sliding mode, and a winding wheel is connected to the sliding frame in a rotating mode.
As an optimized technical scheme of the invention, the fixed disc is fixedly connected with the fixed shaft, the fixed shaft is fixedly connected with the connecting frame, the fixed shaft is slidably connected with the sliding seat, the sliding seat is rotatably connected with the connecting rod with each sliding frame, the fixed shaft is fixedly connected with the stop block, and the elastic piece is connected between the stop block and the sliding seat.
As a preferable technical scheme of the invention, a vertical frame is fixedly connected to the stranded wire bow, a tensioning rod is rotatably connected to the vertical frame, a wire pressing wheel is connected to the tensioning rod, a tension spring is fixedly connected between the tensioning rod and the vertical frame, and a connecting rod is rotatably connected between the tensioning rod and the connecting frame; the wire twisting bow is provided with a strip-shaped connecting hole, and the connecting frame is connected with a sliding shaft which is in sliding connection with the connecting hole.
As an optimized technical scheme of the invention, a plurality of wire wheels are connected to the stranded wire bow along the length direction of the stranded wire bow, and two ends of the stranded wire bow are respectively connected with a wire inlet wheel and a wire outlet wheel.
As a preferred technical solution of the present invention, the wire homogenizing mechanism includes: the screw rod frame is internally and rotatably connected with a screw rod; the driving motor is used for driving the screw rod to rotate; the wire homogenizing seat is in threaded connection with the screw rod, and a plurality of guide wheels are connected to the wire homogenizing seat and used for guiding the wire rod to the winding reel.
As a preferable technical scheme of the invention, the balancing bow is fixedly connected with a fixing rod, and the fixing rod is fixedly connected with a plurality of balancing weights with adjustable positions.
The beneficial effects of the invention are as follows:
1. According to the invention, the wire winding and unwinding mechanism is connected to the wire twisting bow, and when the tension of the wire is too large or too small, the wire winding and unwinding mechanism is driven to move to two sides respectively to lock the wire winding and unwinding wheel, and at the moment, the rotating motor is started to drive the wire winding and unwinding wheel to rotate, so that the length of the wire on the transition mechanism is increased or reduced, the tensioning degree of the wire is adaptively adjusted, and the wire is prevented from being too tight or too loose.
2. According to the invention, the balancing bow is arranged, the balancing weights are connected to the balancing bow, and the positions of the balancing weights can be adjusted, so that the balance of the winch frame can be conveniently adjusted.
Drawings
Fig. 1 is a schematic structural diagram of an intelligent stranded wire system with tension adaptive adjustment according to the present invention.
Fig. 2 is a schematic view of a wire stranding bow and a balancing bow according to the present invention.
Fig. 3 is a schematic structural view of a stranded wire bow according to the present invention.
Fig. 4 is a schematic view of a stranded wire bow wire according to the present invention.
Fig. 5 is a schematic structural diagram of the pay-off and take-up mechanism according to the present invention.
Fig. 6 is a schematic front view of the pay-off and take-up mechanism according to the present invention.
Fig. 7 is a schematic structural diagram of a take-up reel according to the present invention.
Fig. 8 is a schematic structural diagram of a transition mechanism according to the present invention.
Fig. 9 is another angular schematic view of the transition mechanism according to the present invention.
Fig. 10 is a schematic structural diagram of a sliding rail according to the present invention.
Fig. 11 is a schematic structural diagram of a wire evening mechanism according to the present invention.
In the figure: 1. a twisted wire frame; 101. a feed spool; 102. a spool is discharged; 2. a spool; 3. a winding and unwinding mechanism; 31. a take-up reel; 311. a rotating shaft; 312. a first turntable; 313. a second turntable; 314. a rotating ring; 315. limit raised strips; 316. a return spring; 317. a magnet piece; 318. a bracket; 319. a roller; 32. a connecting frame; 33. a transition mechanism; 331. a fixed plate; 332. a carriage; 333. a slide hole; 334. a reel; 335. a fixed shaft; 336. a slide; 337. a stop block; 338. an elastic member; 339. a connecting rod; 34. a rotating electric machine; 35. a slide shaft; 36. a gear; 4. a balancing bow; 41. balancing weight; 42. a fixed rod; 5. a stranded wire bow; 51. a wire guide wheel; 52. a wire inlet wheel; 53. a wire outlet wheel; 54. a vertical frame; 55. a tension rod; 56. a wire pressing wheel; 57. a connecting rod; 58. a tension spring; 59. a connection hole; 6. a rotating frame; 7. a slide rail; 71. a convex portion; 72. a probe holder; 73. an inductor; 8. a wire homogenizing mechanism; 81. a screw rod; 82. a driving motor; 83. a wire homogenizing seat; 84. a guide wheel; 85. a screw rod frame.
Detailed Description
The following description of the embodiments of the present invention 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 invention, but not all embodiments.
Embodiment one: the embodiment discloses an intelligent stranded wire system with tension self-adaptive adjustment, as shown in fig. 1-11, comprising: the wire twisting frame 1 can be mounted on a wire twisting machine, two ends of the wire twisting frame 1 are respectively connected with a wire inlet shaft 101 and a wire outlet shaft 102 in a rotating mode, a wire winding barrel 2 is mounted in the wire twisting frame 1 and used for winding twisted wires, a motor used for driving the wire winding barrel 2 to rotate is mounted on the wire twisting frame 1, and a wire homogenizing mechanism 8 is mounted on the wire twisting frame 1 and used for uniformly winding the wires on the wire winding barrel 2; the wire twisting frame 1 is connected with a wire twisting bow 5 and a balance bow 4, the wire twisting bow 5 and the balance bow 4 are fixedly connected through a pair of rotating frames 6, and the two rotating frames 6 are respectively and fixedly connected with a wire inlet shaft 101 and a wire outlet shaft 102; after being stranded, the wires are respectively wound on the winding reel 2 after passing through the wire inlet shaft 101, the wire stranded bow 5 and the wire outlet shaft 102, and when the wire inlet shaft 101 and the wire outlet shaft 102 rotate, the rotating frame 6, the wire stranded bow 5 and the balance bow 4 are driven to rotate together.
As shown in fig. 3-7, the wire winding and unwinding mechanism 3 for adjusting the tensioning degree of the wire is installed on the wire twisting bow 5, the wire winding and unwinding mechanism 3 comprises a connecting frame 32, the connecting frame 32 can slide on the wire twisting bow 5, a pair of wire winding and unwinding wheels 31 are connected to the connecting frame 32, a transition mechanism 33 is connected to the connecting frame 32, the tensioning degree of the wire can be adjusted through the change of the length of the wire on the transition mechanism 33, two wire winding and unwinding wheels 31 are respectively arranged on two sides of the transition mechanism 33, wherein the wire is wound on the wire winding and unwinding wheels 31 on the right side for 3-5 circles, then wound on the transition mechanism 33 for 1-2 circles, finally wound on the wire winding wheels 31 on the left side for 3-5 circles, the wire is not slipped between the wire and the wire winding and unwinding wheels 31, and the wire is driven to rotate in the wire conveying process.
Preferably, a plurality of wire wheels 51 are connected to the wire twisting bow 5 along the length direction thereof, and two ends of the wire twisting bow 5 are respectively connected with a wire inlet wheel 52 and a wire outlet wheel 53; the wire is wound around the wire guide wheel 51, and normal conveying of the wire is ensured.
Preferably, a fixing rod 42 is fixedly connected to the balancing bow 4, a plurality of balancing weights 41 with adjustable positions are fixedly connected to the fixing rod 42, the balancing weights 41 can be in threaded connection with the fixing rod 42, and the balancing properties of the balancing bow 4 and the stranded wire bow 5 are adjusted by adjusting the positions of the balancing weights 41.
Preferably, as shown in fig. 11, the yarn evening mechanism 8 includes: a screw rod frame 85, wherein a screw rod 81 is rotatably connected to the screw rod frame 85; a driving motor 82 for driving the screw 81 to rotate; the wire homogenizing seat 83 is in threaded connection with the screw rod 81, a plurality of guide wheels 84 are connected to the wire homogenizing seat 83 and used for guiding wires to the winding reel 2, wherein the guide wheels 84 comprise the guide wheels 84 which are horizontally arranged and vertically arranged, the screw rod 81 is driven to repeatedly rotate in the forward and reverse directions through the driving motor 82, the wire homogenizing seat 83 is driven to reciprocate, and the wires are uniformly wound on the winding reel 2.
As shown in fig. 7, a first rotating disc 312 is coaxially and fixedly connected to the take-up and pay-off wheel 31, a rotating shaft 311 is rotatably connected to the first rotating disc 312, a second rotating disc 313 which rotates together is connected to the rotating shaft 311, and magnet pieces 317 which are mutually adsorbed are connected to the first rotating disc 312 and the second rotating disc 313; the rotating shafts 311 are provided with limit convex strips 315, the second rotating discs 313 are in sliding connection with the limit convex strips 315, a reset spring 316 is connected between the first rotating discs 312 and the second rotating discs 313, the reset spring 316 is sleeved on the surfaces of the rotating shafts 311, the connecting frame 32 is provided with a rotating motor 34 for driving the rotating shafts 311 to rotate, and the two rotating shafts 311 are fixedly connected with gears 36 which are meshed with each other; when the wire is conveyed normally, the first rotating disc 312 and the second rotating disc 313 are not contacted, the wire is conveyed to drive the take-up and pay-off wheel 31 to rotate, and when the take-up and pay-off wheel 31 rotates, the first rotating disc 312 is driven to rotate, and the first rotating disc 312 and the rotating shaft 311 are kept motionless; when the wire tensioning degree is required to be adjusted, the first rotating disc 312 and the second rotating disc 313 are in adsorption contact, the rotating motor 34 drives the rotating shaft 311 to rotate quickly and instantaneously, the first rotating disc 312 and the second rotating disc 313 are driven to rotate simultaneously, the wire winding and unwinding wheel 31 is driven to rotate, and the length of the wire on the transition mechanism 33 is increased or reduced when the wire winding and unwinding wheel 31 rotates, so that the aim of adjusting the wire tensioning degree is fulfilled.
As shown in fig. 8-9, the transition mechanism 33 comprises a fixed disk 331, a plurality of sliding holes 333 are uniformly formed in the fixed disk 331, the sliding holes 333 face the center direction of the fixed disk 331, a sliding frame 332 is connected to the sliding holes 333 in a sliding manner, and a reel 334 is connected to the sliding frame 332 in a rotating manner; the fixed disk 331 is fixedly connected with a fixed shaft 335, the fixed shaft 335 is fixedly connected with the connecting frame 32, the fixed shaft 335 is slidably connected with a sliding seat 336, a connecting rod 339 is rotatably connected between the sliding seat 336 and each sliding seat 332, the fixed shaft 335 is fixedly connected with a stop block 337, an elastic piece 338 is connected between the stop block 337 and the sliding seat 336, the elastic piece 338 can be made of a spring material with a smaller elastic coefficient, and when the sliding seat 332 moves towards the side direction of the fixed disk 331, the length of a wire wound on the transition mechanism 33 can be increased; when the carriage 332 moves toward the center of the fixed disk 331, the length of the wire wound on the transition mechanism 33 decreases.
The specific implementation method comprises the following steps: when the tension of the wire on the stranded wire bow 5 is overlarge, the first rotary disc 312 and the second rotary disc 313 are in adsorption contact, the rotary motor 34 drives the right wire take-up and pay-off wheel 31 to instantly rotate clockwise at a high speed, the left wire take-up and pay-off wheel 31 rotates anticlockwise simultaneously, at the moment, the tension of the wire on the transition mechanism 33 is increased, the sliding frame 332 is driven to move towards the circle center direction of the fixed disc 331, the length of the wire wound on the transition mechanism 33 is further shortened, a part of the length of the wire on the transition mechanism 33 is instantly released, the tension of the wire on the stranded wire bow 5 is reduced, the wire is prevented from being overtightened and broken, then the first rotary disc 312 and the second rotary disc 313 are separated, and the wire is continuously conveyed normally; similarly, when the wire tension is too small, the rotating motor 34 drives the two take-up and pay-off wheels 31 to rotate at a high speed in an instant reverse direction, the wire tension on the transition mechanism 33 becomes small, the sliding frame 332 on the transition mechanism 33 moves outwards under the elasticity of the elastic piece 338, the length of the wire on the transition mechanism 33 is increased, the wire tension on the stranded wire bow 5 is further increased, and the wire is prevented from being too loose.
Embodiment two: based on the structure of the first embodiment, in order to control the automatic adsorption and separation of the first turntable 312 and the second turntable 313, as shown in fig. 4, a vertical frame 54 is fixedly connected to the wire twisting bow 5, a tension rod 55 is rotatably connected to the vertical frame 54, a wire pressing wheel 56 is connected to the tension rod 55, a wire passes below the wire pressing wheel 56, a tension spring 58 is fixedly connected between the tension rod 55 and the vertical frame 54, the tension spring 58 applies a tension force to the tension rod 55, and a connecting rod 57 is rotatably connected between the tension rod 55 and the connecting frame 32; the wire twisting bow 5 is provided with a strip-shaped connecting hole 59, the connecting frame 32 is connected with a sliding shaft 35 which is in sliding connection with the connecting hole 59, and the end part of the sliding shaft 35 is provided with a blocking part, so that the wire winding and unwinding mechanism 3 can move on the wire twisting bow 5.
As shown in fig. 7 and 10, a rotating ring 314 is rotatably connected to the second turntable 313, a bracket 318 is fixedly connected to the rotating ring 314, and a roller 319 is connected to the bracket 318; the wire twisting bow 5 is fixedly connected with a sliding rail 7 matched with the roller 319, the sliding rail 7 is provided with a plurality of convex parts 71, the two rollers 319 simultaneously move to the convex parts 71, when the roller 319 rolls to the convex parts 71, the second rotary table 313 is in adsorption contact with the first rotary table 312, and when the roller 319 is separated from the convex parts 71, the second rotary table 313 is separated from the first rotary table 312 under the elasticity of the reset spring 316; and the slide rail 7 is fixedly connected with a plurality of probe frames 72, the probe frames 72 are provided with the sensors 73, the sensors 73 can adopt displacement sensors, when the roller 319 is close to be opposite to the opposite sensors 73, the roller 319 rolls to the convex parts 71 at the moment, the sensors 73 sense the roller 319, signals are sent to the controller, and the rotating motor 34 is automatically started.
The specific implementation method comprises the following steps: when the wire is overtightened, the tensioning rod 55 is driven to rotate upwards, the tensioning rod 55 drives the wire winding and unwinding mechanism 3 to move to the right when rotating upwards, the roller 319 rolls to the convex part 71 when the wire winding and unwinding mechanism 3 moves to the right, the second rotary table 313 is driven to move towards the direction close to the first rotary table 312, the second rotary table 313 is in adsorption contact with the first rotary table 312, the sensor 73 sends a signal when sensing that the roller 319 rolls to the convex part 71, the rotating motor 34 is automatically started to drive the two wire winding and unwinding wheels 31 to rotate instantly at a high speed, the right wire winding and unwinding wheel 31 rotates instantly at a high speed, the left wire winding and unwinding wheel 31 rotates anticlockwise simultaneously, the length of the wire on the transition mechanism 33 is reduced, a part of the length of the wire on the transition mechanism 33 is released instantly, the wire tension on the stranded wire bow 5 is reduced, when the wire tension is restored to a normal value, the tensioning rod 55 rotates downwards to a home position, the wire winding and unwinding mechanism 3 is driven to move leftwards to a home position, the second rotary table 313 is separated from the first rotary table 312, and the normal rotation of the wire winding and unwinding wheel 31 is prevented from being influenced; similarly, when the wire is too loose, the tension spring 58 drives the tension rod 55 to rotate downwards, the roller 319 rolls to the convex part 71 when the wire winding and unwinding mechanism 3 is driven to move to the left side, the second rotary disc 313 is driven to be in adsorption contact with the first rotary disc 312, the rotary motor 34 is automatically started to drive the two wire winding and unwinding wheels 31 to rotate reversely, the length of the wire on the transition mechanism 33 is increased, the tension of the wire on the stranded wire bow 5 is increased, the wire is prevented from being too loose, when the wire tension is restored to a normal value, the tension rod 55 rotates to the original position and drives the wire winding and unwinding mechanism 3 to move to the right side to the original position, and the second rotary disc 313 is separated from the first rotary disc 312.
Finally, it should be noted that: in the description of the present invention, it should be noted that the azimuth or positional relationship indicated by the terms "vertical", "upper", "lower", "horizontal", etc. are based on the azimuth or positional relationship shown in the drawings, and are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or element referred to must have a specific azimuth, be constructed and operated in a specific azimuth, and thus should not be construed as limiting the present invention.
The foregoing description is only a preferred embodiment of the present invention, and the present invention is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present invention has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.
Claims (8)
1. Intelligent stranded wire system of tension self-adaptation adjustment, its characterized in that includes:
the wire twisting frame (1), both ends of the wire twisting frame (1) are respectively connected with a wire inlet shaft (101) and a wire outlet shaft (102) in a rotating way, a wire winding barrel (2) is arranged in the wire twisting frame (1) and used for winding wires, and a wire homogenizing mechanism (8) is arranged on the wire twisting frame (1) and used for uniformly winding the wires on the wire winding barrel (2);
The wire twisting frame (1) is connected with a wire twisting bow (5) and a balance bow (4), and the wire twisting bow (5) is fixedly connected with the balance bow (4) through a pair of rotating frames (6);
A wire winding and unwinding mechanism (3) for adjusting the tensioning degree of a wire is arranged on the stranded wire bow (5), the wire winding and unwinding mechanism (3) comprises a connecting frame (32), a pair of wire winding and unwinding wheels (31) are connected to the connecting frame (32), a transition mechanism (33) is connected to the connecting frame (32), and the two wire winding and unwinding wheels (31) are respectively arranged on two sides of the transition mechanism (33);
The winding and unwinding wheel (31) is coaxially and fixedly connected with a first rotary table (312), the first rotary table (312) is rotationally connected with a rotary shaft (311), the rotary shaft (311) is connected with a second rotary table (313) which rotates together, and the first rotary table (312) and the second rotary table (313) are connected with magnet pieces (317) which are mutually adsorbed;
Be equipped with spacing sand grip (315) on axis of rotation (311), second carousel (313) and spacing sand grip (315) sliding connection, and be connected with reset spring (316) between first carousel (312) and second carousel (313), install on link (32) and be used for driving axis of rotation (311) pivoted rotating electrical machines (34), two all fixedly connected with intermeshing's gear (36) on axis of rotation (311).
2. The intelligent stranded wire system with self-adaptive tension adjustment according to claim 1, wherein a rotating ring (314) is rotatably connected to the second turntable (313), a bracket (318) is fixedly connected to the rotating ring (314), and a roller (319) is connected to the bracket (318); the wire twisting bow (5) is fixedly connected with a sliding rail (7) matched with the roller (319), the sliding rail (7) is provided with a plurality of convex parts (71), and when the roller (319) rolls to the convex parts (71), the second rotary table (313) is in adsorption contact with the first rotary table (312); and a plurality of probe frames (72) are fixedly connected to the sliding rail (7), and sensors (73) are arranged on the probe frames (72) and used for sensing whether the rollers (319) move to the positions of the convex parts (71).
3. The intelligent stranded wire system of self-adaptive tension adjustment according to claim 2, wherein the transition mechanism (33) comprises a fixed disc (331), a plurality of sliding holes (333) are uniformly formed in the fixed disc (331), a sliding frame (332) is slidably connected to the sliding holes (333), and a reel (334) is rotatably connected to the sliding frame (332).
4. The intelligent stranded wire system for tension self-adaptive adjustment according to claim 3, wherein a fixed shaft (335) is fixedly connected to the fixed disc (331), the fixed shaft (335) is fixedly connected to the connecting frame (32), a sliding seat (336) is slidingly connected to the fixed shaft (335), connecting rods (339) are rotationally connected between the sliding seat (336) and each sliding frame (332), a stop block (337) is fixedly connected to the fixed shaft (335), and an elastic piece (338) is connected between the stop block (337) and the sliding seat (336).
5. The intelligent stranded wire system with the self-adaptive tension adjustment according to claim 4, wherein a vertical frame (54) is fixedly connected to the stranded wire bow (5), a tensioning rod (55) is rotatably connected to the vertical frame (54), a wire pressing wheel (56) is connected to the tensioning rod (55), a tension spring (58) is fixedly connected between the tensioning rod (55) and the vertical frame (54), and a connecting rod (57) is rotatably connected between the tensioning rod (55) and the connecting frame (32); the stranded wire bow (5) is provided with a strip-shaped connecting hole (59), and the connecting frame (32) is connected with a sliding shaft (35) which is in sliding connection with the connecting hole (59).
6. The intelligent stranded wire system with tension self-adaptive adjustment according to claim 5, wherein a plurality of wire guiding wheels (51) are connected on the stranded wire bow (5) along the length direction of the stranded wire bow, and two ends of the stranded wire bow (5) are respectively connected with a wire inlet wheel (52) and a wire outlet wheel (53).
7. Intelligent stranded wire system with adaptive tension adjustment according to claim 6, characterized in that the wire evening mechanism (8) comprises: a screw rod frame (85), wherein the screw rod frame (85) is rotationally connected with a screw rod (81); the driving motor (82) is used for driving the screw rod (81) to rotate; and the wire homogenizing seat (83) is in threaded connection with the screw rod (81), and a plurality of guide wheels (84) are connected to the wire homogenizing seat (83) and used for guiding the wire rod to the winding reel (2).
8. The intelligent stranded wire system of self-adaptive tension adjustment according to claim 7, wherein a fixing rod (42) is fixedly connected to the balancing bow (4), and a plurality of balancing weights (41) with adjustable positions are fixedly connected to the fixing rod (42).
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CN202410547375.3A CN118136346B (en) | 2024-05-06 | 2024-05-06 | Intelligent stranded wire system with tension self-adaptive adjustment function |
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CN202410547375.3A CN118136346B (en) | 2024-05-06 | 2024-05-06 | Intelligent stranded wire system with tension self-adaptive adjustment function |
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CN118136346B true CN118136346B (en) | 2024-07-09 |
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Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN201765885U (en) * | 2010-05-06 | 2011-03-16 | 江苏新远程电缆有限公司 | Concentric wire twisting device |
CN114530292A (en) * | 2022-01-25 | 2022-05-24 | 广州市鸿辉电工机械有限公司 | High-speed stranding machine wire passing system |
Family Cites Families (1)
Publication number | Priority date | Publication date | Assignee | Title |
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JP5723145B2 (en) * | 2010-12-22 | 2015-05-27 | 株式会社Hci | Magnetic bearing type tubular stranded wire machine |
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Patent Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN201765885U (en) * | 2010-05-06 | 2011-03-16 | 江苏新远程电缆有限公司 | Concentric wire twisting device |
CN114530292A (en) * | 2022-01-25 | 2022-05-24 | 广州市鸿辉电工机械有限公司 | High-speed stranding machine wire passing system |
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