A fishing line winding mechanism

Abstract

The application discloses a fish line winding mechanism and relates to the technical field of fish line manufacturing.The fish line winding mechanism comprises a long frame, a driving element one is arranged at one end of the long frame, a threaded rod is arranged at the output end of the driving element one, a sliding block one is threadedly connected with the threaded rod, and a sliding plate is arranged on the sliding block one.The top surface of the sliding plate is provided with a fixed plate, the fixed plate is provided with a sleeve, the sleeve is provided with a rotating bearing, the rotating bearing comprises an outer ring and an inner ring, the fixed plate is provided with a driving element two, a driving gear is arranged at the output end of the driving element two, a synchronous belt is arranged in mesh with the driving gear, the synchronous belt is in mesh with the outer ring, the outer ring is provided with a fixing frame, and a rotating roller is rotatably arranged on the fixing frame.The driving element one drives the threaded rod to rotate, the sliding block one and related components are moved along the long frame, the driving element two drives the outer ring of the rotating bearing to rotate through the driving gear and the synchronous belt, the rotating roller on the fixing frame is rotated around the main line, the winding of the auxiliary line on the main line is completed, the consistency of the winding rhythm and angle is guaranteed, and the winding quality of the fish line is improved.

Description

Technical Field

[0001] This application relates to the field of fishing line manufacturing technology, and in particular to a fishing line winding mechanism. Background Technology

[0002] In the process of making fishing line, line strength is one of the core indicators for measuring product quality, and the process of winding secondary lines around the main line is a key means of improving the strength of the fishing line. The principle of this process is to use multiple strands of secondary lines to be wound around one or more main lines at a specific angle and tension, so that the main line and secondary lines form a mutually supporting overall structure, thereby significantly enhancing the tensile strength and abrasion resistance of the fishing line, while also improving the flexibility and knot resistance of the line.

[0003] In existing technologies, the process of winding the secondary line around the main line is mainly done manually. The operator needs to fix the main line on a simple support, hold a spool with the secondary line wound on it, and control the secondary line to wind around the main line at a certain rhythm and angle by manually rotating the spool or moving their hand. During the winding process, the operator needs to rely on their experience to judge the tension of the main line and adjust the tension of the secondary line in a timely manner to ensure even winding.

[0004] Regarding the aforementioned technologies, the inventors believe that it is difficult to precisely control the winding tension of the sub-line manually, resulting in significant differences in the tightness of the sub-line within the same batch of fishing lines. In some areas, the sub-line is too loose and cannot effectively enhance the strength of the main line, while in other areas, the sub-line is too tight, causing excessive stretching of the main line, which in turn reduces the overall performance of the line. Utility Model Content

[0005] The purpose of this application is to provide a fishing line winding mechanism to improve the problem of the difficulty in accurately controlling the winding tension of the sub-line manually.

[0006] This application provides a fishing line winding mechanism, which adopts the following technical solution:

[0007] A fishing line winding mechanism includes a long frame. A driving component is located at one end of the long frame. A threaded rod is located inside the long frame at the output end of the driving component, and a slider is threadedly connected to the threaded rod. A sliding plate is provided on the top surface of the sliding plate. A sleeve for the main line to pass through is provided through the fixed plate along the length of the long frame. A rotating bearing is fitted onto the sleeve, and the rotating bearing includes an outer ring and an inner ring fixed to the sleeve. A second driving component is located on the fixed plate, and a driving gear is located at the output end of the second driving component. The driving gear meshes with a synchronous belt, which meshes with the outer ring. A fixed frame is provided on the outer ring, and a rotating roller for unwinding auxiliary line is rotatably mounted on the fixed frame.

[0008] By adopting the above technical solution, the first drive component drives the threaded rod to rotate, causing the first slider and related components to move along the long frame, thereby achieving automatic adjustment of the secondary line winding position; the second drive component drives the outer ring of the rotating bearing to rotate through the drive gear and synchronous belt, causing the rotating roller on the fixed frame to rotate around the main line, completing the winding of the secondary line around the main line; replacing manual operation, the winding process is automated, solving the problems of low efficiency and unstable quality of manual winding, helping to ensure the consistency of winding rhythm and angle, and improving the quality of fishing line winding.

[0009] Optionally, a fixed plate frame is provided on one side of the long frame, and a plurality of slide rails are provided on the fixed plate frame along the length of the long frame. The slide plate is provided with a side plate, and a slider two that is slidably connected to the slide rails is provided on the side of the side plate near the fixed plate frame.

[0010] By adopting the above technical solution, it is helpful to reduce the shaking caused by the rotation of the threaded rod driven by the first driving component and the rotation of the outer ring driven by the second driving component, improve the stability and accuracy of the movement of the secondary wire winding position along the length of the main wire, and further ensure the uniformity of the winding.

[0011] Optionally, the inner wall of the side plate is provided with a reinforcing block that is fixed to the fixing plate.

[0012] By adopting the above technical solution, the movement and rotation of the components during the operation of the mechanism will generate a certain force. The reinforcing block helps to prevent the connection between the side plate and the fixed plate from deforming or being damaged due to excessive force, thereby improving the overall structural stability and service life of the mechanism.

[0013] Optionally, one end of the fixing frame is provided with a damper connected to the rotating roller.

[0014] By adopting the above technical solution and setting an appropriate damping force, the tension during the unwinding of the secondary line can be controlled, the tension of the secondary line can be kept stable, the tightness of the secondary line winding around the main line can be consistent, and the overall performance of the line can be enhanced.

[0015] Optionally, the fixing frame is provided with a wire feeding straight cylinder for the auxiliary wire to pass through, and the wire feeding straight cylinder is inclined in the direction of the axis of the rotating bearing.

[0016] By adopting the above technical solution, the straight tube for laying out the secondary line plays a guiding role, ensuring that the secondary line is accurately wound around the main line at a preset tilt angle. This avoids the situation where the secondary line is wound at a chaotic angle when manually winding the line, making the secondary line winding more regular and reducing the risk of tangling and knotting when using the main line.

[0017] Optionally, the fixed plate is rotatably provided with a pressure roller that abuts against the outer side of the timing belt.

[0018] By adopting the above technical solution, the pressure roller can apply a certain pressure to the timing belt, so that the timing belt meshes tightly with the drive gear and the outer ring, which helps to ensure the stability of the outer ring rotation speed, and thus ensures the consistency of the secondary wire winding speed.

[0019] Optionally, the pressure roller is provided with several anti-slip grooves.

[0020] By adopting the above technical solution, the anti-slip groove increases the friction between the pressure roller and the timing belt, thus more effectively preventing the timing belt from slipping.

[0021] Optionally, the outer ring is provided with a plurality of mounting surfaces for installing counterweights.

[0022] By adopting the above technical solution, the mounting plane can adjust the overall weight and center of gravity of the outer ring by installing counterweights. When the outer ring rotates, the counterweights can improve its rotational balance by balancing the weight of the fixing frame, which helps to alleviate the shaking or vibration of the outer ring during rotation and improve the quality of fishing line winding.

[0023] In summary, this application includes at least one of the following beneficial technical effects of the fishing line winding mechanism:

[0024] 1. Drive component one drives the threaded rod to rotate, causing slider one and related components to move along the long frame, thereby automatically adjusting the position of the secondary line winding; drive component two drives the outer ring of the rotating bearing to rotate through the drive gear and synchronous belt, causing the rotating roller on the fixed frame to rotate around the main line, completing the winding of the secondary line onto the main line; replacing manual operation, realizing the automation of the winding process, solving the problems of low efficiency and unstable quality of manual winding, helping to ensure the consistency of winding rhythm and angle, and improving the quality of fishing line winding;

[0025] 2. The straight tube for releasing the line guides the secondary line, ensuring that the secondary line is accurately wound around the main line at a preset angle. This avoids the chaotic winding angle of the secondary line during manual winding, making the winding of the secondary line more regular and reducing the risk of tangling and knotting when using the main line.

[0026] 3. The pressure roller can apply a certain pressure to the timing belt, so that the timing belt meshes tightly with the drive gear and the outer ring, which helps to ensure the stability of the outer ring rotation speed, and thus ensures the consistency of the secondary wire winding speed. Attached Figure Description

[0027] Figure 1 This is a schematic diagram of the overall structure of the fishing line winding mechanism.

[0028] Figure 2 This is a schematic diagram illustrating the fixed frame structure in the embodiment.

[0029] In the diagram: 1. Long frame; 11. Drive component one; 12. Threaded rod; 2. Slider one; 21. Slide plate; 3. Fixed plate; 31. Sleeve; 4. Rotating bearing; 41. Outer ring; 411. Mounting plane; 42. Inner ring; 5. Drive component two; 51. Drive gear; 52. Synchronous belt; 6. Fixed frame; 61. Rotating roller; 62. Damper; 63. Line feeding cylinder; 7. Fixed plate frame; 71. Slide rail; 8. Side plate; 81. Slider two; 82. Reinforcing block; 9. Pressure roller; 91. Anti-slip groove. Detailed Implementation

[0030] The following is in conjunction with the appendix Figure 1 - Appendix Figure 2 This application will be described in further detail below.

[0031] A fishing line winding mechanism, as shown in the figure Figure 1 , Figure 2 It includes a long frame 1, which is a cuboid frame structure. One end of the long frame 1 is fixed with a drive component 11 by bolts. The drive component 11 can be a servo motor. The output end of the drive component 11 passes through the side wall of the long frame 1 and is located inside the long frame 1. It is connected to a threaded rod 12 by a coupling. The two ends of the threaded rod 12 are rotatably connected to the inner side wall of the long frame 1 by bearings. The threaded rod 12 is threadedly connected to a slider 2. The reciprocating motion of the slider is controlled by the forward and reverse rotation of the drive component 11. The top of the slider 2 is fixed with a slide plate 21 by welding.

[0032] Reference Figure 1 , Figure 2 A fixing plate 3 is bolted to the top surface of the slide plate 21. A fixing plate 3 frame is provided on one side of the long frame 1. The fixing plate 3 frame is a metal frame structure and is not connected to the long frame 1. It is fixed to the external ground or wall or other components by expansion bolts. Several slide rails 71 are bolted to the fixing plate 3 frame along the length of the long frame 1. The slide rails 71 are long strip-shaped metal tracks. In this embodiment, two slide rails are preferred. A side plate 8 is vertically provided on one side of the slide plate 21 by welding. A slider 81 that is slidably connected to the slide rail 71 is bolted to the side of the side plate 8 near the fixing plate 3 frame. The slider 81 can slide freely along the length of the slide rail 71. A reinforcing block 82 is welded to the side of the fixing plate 3 on the inner side wall of the side plate 8. The reinforcing block 82 is an L-shaped metal block used to enhance the connection strength between the side plate 8 and the fixing plate 3.

[0033] Reference Figure 1 , Figure 2A sleeve 31 for the main line to pass through is provided through the fixed plate 3 along the length of the long frame 1. The sleeve 31 is a hollow metal cylinder. A rotating bearing 4 is sleeved on the outside of the sleeve 31. The rotating bearing 4 includes an outer ring 41 and an inner ring 42 that is fixed to the outer wall of the sleeve 31 by an interference fit. A second drive component 5 is fixed to the top of the fixed plate 3 by bolts. The second drive component 5 can be a servo motor. A drive gear 51 is provided at the output end of the second drive component 5 by a key. A synchronous belt 52 is meshed with the drive gear 51. The inner side of the synchronous belt 52 meshes with the outer teeth of the outer ring 41, so that when the drive gear 51 rotates, it drives the outer ring 41 to rotate through the synchronous belt 52.

[0034] Reference Figure 1 , Figure 2 The outer ring 41 is provided with a plurality of mounting surfaces 411 for mounting counterweights. The mounting surfaces 411 are machined flat metal surfaces, and their number can be flexibly set according to the size of the outer ring 41 and the weight of the counterweight required. In this embodiment, two are preferred. The counterweight can be a metal block, the side of which contacts the mounting surface 411 is also a flat surface, and it is fixed by bolts.

[0035] Reference Figure 1 , Figure 2 The fixed plate 3 is rotatably mounted on the side of the synchronous belt 52 near the synchronous belt 52, and a pressure roller 9 is abutting against the outer side of the synchronous belt 52. The pressure roller 9 is made of rubber and has several anti-slip grooves 91 on its outer circumference. The anti-slip grooves 91 can increase the friction between the pressure roller 9 and the synchronous belt 52 and prevent the synchronous belt 52 from slipping.

[0036] Reference Figure 1 , Figure 2 A fixing frame 6 is bolted to the side of the outer ring 41 away from the fixing plate 3. The fixing frame 6 is rotatably mounted with a rotating roller 61 for unwinding the auxiliary wire via a bearing. The rotating roller 61 is a cylindrical metal roller, and the auxiliary wire is wound on the rotating roller 61. A damper 62 connected to the end of the rotating roller 61 is bolted to one end of the fixing frame 6. The damper 62 can be a rotary damper 62, used to adjust the rotational resistance of the rotating roller 61. A wire-laying straight cylinder 63 for the auxiliary wire to pass through is welded to the other end of the fixing frame 6 away from the rotating roller 61. The wire-laying straight cylinder 63 is a hollow metal cylinder and is inclined towards the axis of the rotating bearing 4 so that the auxiliary wire can be accurately wound on the main wire passing through the sleeve 31.

[0037] The implementation principle of this application embodiment is as follows:

[0038] In actual use, the main line is first passed through the sleeve 31 and fixed to the external take-up device. The auxiliary line is led out through the pay-off straight cylinder 63 and fixed at the starting position of the main line. At the same time, the damper 62 is adjusted according to the line parameters to set the tension of the auxiliary line. After the equipment is started, the drive component 11 drives the threaded rod 12 to rotate, so that the slider 12 moves axially along the slide rail 71 to adjust the winding position. The drive component 2 5 drives the outer ring 41 of the rotating bearing 4 and the fixed frame 6 to move around the main line through the drive gear 51 and the synchronous belt 52. The auxiliary line unwound by the rotating roller 61 is guided to wind onto the main line by the pay-off straight cylinder 63. The pressure roller 9 prevents the synchronous belt 52 from slipping to ensure the stability of the winding angle. The damper 62 maintains the tension of the auxiliary line. Through the cooperation of the two, the auxiliary line is evenly wound around the main line at the set angle, tension and pitch, completing the automated high-precision operation and improving the winding quality.

[0039] The embodiments described in this specific implementation are preferred embodiments of this application and are not intended to limit the scope of protection of this application. Identical components are represented by the same reference numerals. Therefore, all equivalent changes made to the structure, shape, and principle of this application should be covered within the scope of protection of this application.

Claims

1. A fishing line winding mechanism, comprising a long frame (1), characterized in that: One end of the long frame (1) is provided with a driving component (11). The output end of the driving component (11) is provided with a threaded rod (12) inside the long frame (1). The threaded rod (12) is threadedly connected to a slider (2). The slider (2) is provided with a sliding plate (21). The top surface of the sliding plate (21) is provided with a fixing plate (3). The fixing plate (3) is provided with a sleeve (31) through which the main line passes along the length of the long frame (1). The sleeve (31) is fitted with a rotating bearing (4). The rotating bearing (4) includes an outer ring (41) and an inner ring (42) fixed to the sleeve (31); the fixed plate (3) is provided with a second driving component (5), the output end of the second driving component (5) is provided with a driving gear (51), the driving gear (51) is meshed with a synchronous belt (52), the synchronous belt (52) meshes with the outer ring (41); the outer ring (41) is provided with a fixed frame (6), the fixed frame (6) is rotatably provided with a rotating roller (61) for unwinding the secondary wire.

2. The fishing line winding mechanism according to claim 1, characterized in that: A fixed plate (3) frame is provided on one side of the long frame (1). The fixed plate (3) frame is provided with several slide rails (71) along the length of the long frame (1). The slide plate (21) is provided with a side plate (8). A slider (81) that is slidably connected to the slide rail (71) is provided on the side of the side plate (8) near the fixed plate (3) frame.

3. A fishing line winding mechanism according to claim 2, characterized in that: The inner wall of the side plate (8) is provided with a reinforcing block (82) that is fixed to the fixing plate (3).

4. A fishing line winding mechanism according to claim 2, characterized in that: One end of the fixed frame (6) is provided with a damper (62) connected to the rotating roller (61).

5. A fishing line winding mechanism according to claim 4, characterized in that: The fixing frame (6) is provided with a wire feeding cylinder (63) for the auxiliary wire to pass through, and the wire feeding cylinder (63) is inclined towards the axis of the rotating bearing (4).

6. A fishing line winding mechanism according to claim 1, characterized in that: The fixed plate (3) is rotatably provided with a pressure roller (9) that abuts against the outside of the synchronous belt (52).

7. A fishing line winding mechanism according to claim 6, characterized in that: The pressure roller (9) is provided with several anti-slip grooves (91).

8. A fishing line winding mechanism according to claim 1, characterized in that: The outer ring (41) is provided with a plurality of mounting surfaces (411) for installing counterweights.

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