A fishing gear storage assembly
The locking structure design of the spool and the housing solves the problem of the fishing tackle storage components being easily opened by accident, realizing fast and safe fishing line storage and convenient carrying of fishing tackle, and improving the overall durability and space utilization of the structure.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 东阳市嗨大叔电子商务商行
- Filing Date
- 2025-06-26
- Publication Date
- 2026-06-19
AI Technical Summary
Existing fishing tackle storage components have complex structures and are cumbersome to operate. They are easily opened by accident, causing fishing lines to scatter and wear, affecting the convenience and safety of fishing.
The design employs a combination of a spool and a housing, utilizing a locking structure to achieve stable locking through axial insertion and circumferential rotation. This eliminates the need for a flip-top structure and uses a first baffle to seal the opening, simplifying the assembly process and improving anti-detachment performance.
It enables quick storage and safe preservation of fishing line, simplifies the assembly process, reduces structural weight, improves convenience and space utilization, avoids accidental opening, and extends service life.
Smart Images

Figure CN224368835U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of fishing gear storage technology, and in particular relates to a fishing gear storage component. Background Technology
[0002] Fishing supplies typically include fishing rods, lines, hooks, and bait. However, improperly stored fishing lines not only easily become tangled and knotted, making them difficult to untangle quickly, but also pose safety hazards. Although the surface of the fishing line appears smooth, it can easily cut fingers when taut, and may also cause accidental cuts due to external pulling. To effectively solve these problems, storing fishing lines in a dedicated container has become an essential practice for anglers. These containers, through their reasonable structural design, prevent fishing lines from becoming tangled and provide physical isolation, ensuring safety and convenience throughout the fishing process.
[0003] In existing technologies, fishing tackle storage components generally suffer from problems such as complex structural design and poor practicality. For example, storage boxes using a simple flip-top snap design are easily opened by external impacts when anglers carry their tackle bags while walking, squatting, or experiencing accidental collisions. Once the box is open, the neatly stored fishing lines will scatter, not only losing their purpose of organization but also potentially causing line wear and damage to accessories, resulting in significant inconvenience for subsequent fishing trips.
[0004] This utility model proposes a fishing tackle storage component to solve the problems of complex structural design, cumbersome operation, and easy accidental opening of existing fishing line storage components. It ensures the safety and integrity of the stored fishing line and accessories, while also providing fishing enthusiasts with a more efficient and reliable fishing tackle storage solution. Utility Model Content
[0005] In order to overcome the shortcomings of the existing technology, this utility model provides a fishing tackle storage component that can quickly store fishing lines. It can not only store the fishing lines, but also keep the stored fishing lines in a closed space. The overall structure is simple, lightweight and portable, and has a high utilization rate of idle space.
[0006] The technical solution adopted by this utility model to solve its technical problem is: a fishing gear storage component, comprising:
[0007] A spool for winding fishing line has a first and a second wall that are parallel to each other, and a winding body located between the first and the second walls. The outer diameter of the first wall is larger than the outer diameter of the second wall, and a keyhole is formed inside the winding body.
[0008] The housing forms a cavity for placing the spool, the first side of the cavity is closed and the second side opposite to the first side forms an open opening, and a positioning part is provided inside the cavity;
[0009] A locking structure is formed between the inner wall of the lock hole and the positioning part. The spool is inserted into the cavity of the housing and rotates circumferentially relative to the housing. The locking structure forms an anti-disengagement fit between the housing and the spool in the axial direction, and the first baffle seals the opening of the housing.
[0010] This utility model fishing tackle storage component can quickly store fishing lines. The overall structure is completed by the cooperation of a spool and a housing. After the fishing line is wound around the spool and placed into the housing, the two form a radial limit. Then, the spool rotates circumferentially relative to the housing. After rotating a certain angle, the locking structure forms an axial anti-disengagement fit between the positioning part and the inside of the locking hole. At the same time, the first baffle of the spool seals the opening of the housing, which functions as a cover for the opening of the housing. Compared with the independent end cap and flip-top buckle design of traditional storage components, this design omits the flip-top structure and cleverly uses the first baffle to seal the opening of the housing, saving manufacturing materials. Moreover, during the assembly of the spool and the housing, a stable locking assembly is achieved by axial insertion and circumferential rotation. The assembly process is simple, and the spool and the housing are not easy to separate after assembly. In addition, the locking structure is located between the positioning part and the inner wall of the locking hole, which effectively utilizes the internal space of the positioning part and the locking hole without adding extra volume, reducing the overall structural weight and increasing storage space.
[0011] Furthermore, the locking structure includes a limiting boss, a notch, and a buckle located between the lock hole and the positioning part. The spool is inserted into the housing cavity, and a portion of the buckle extends into the notch. The spool and housing rotate circumferentially relative to each other, and the buckle and the limiting boss abut against each other to form an axial anti-disengagement fit. After the buckle is axially inserted into the notch, it forms a radial limit; after circumferential rotation, the buckle achieves an anti-disengagement fit with the limiting boss. This structural design achieves stable locking assembly through two actions: axial insertion and circumferential rotation. The assembly process is simple, and after assembly, the spool and housing are not easily separated, ensuring a stable connection of the storage assembly during storage or carrying.
[0012] Furthermore, the positioning part extends along the axial direction, and its end forms a buckle. The limiting boss extends circumferentially along the inner wall of the lock hole and is interrupted to form a notch. The buckle extends into the notch.
[0013] Furthermore, the inner wall of the positioning part extends circumferentially to form a limiting boss and interrupts to form a notch groove. The lock hole extends along the axial direction, and its end forms a buckle. The buckle extends into the notch groove.
[0014] In this locking mechanism, the limiting boss, notch, and buckle between the lock hole and the positioning part can be interchanged between the lock hole and the positioning part. Regardless of how the positions of the limiting boss, notch, and buckle are changed, the axial and radial constraint functions are not affected when the spool is inside the housing. This provides storage flexibility and improves processing flexibility.
[0015] Furthermore, there are two notches, arranged radially symmetrically. This radially symmetrical distribution ensures that the latch and the limiting boss are subjected to more balanced forces when circumferentially locked, resulting in a more stable lock between the spool and the housing.
[0016] Furthermore, the latch has an inclined guide surface for guiding the spool into the housing cavity. The inclined guide surface of the latch acts as a guide, reducing the risk of misalignment during installation and ensuring that the spool and housing can be quickly and accurately positioned, allowing the subsequent locking function to operate smoothly.
[0017] Furthermore, the housing has a line outlet end with a line outlet through the side wall, which communicates with the cavity; the second baffle wall has a groove for the line outlet end to pass through. This design eliminates the need for opening and closing, allowing direct removal of the fishing line. That is, the fishing line can be retrieved without removing the spool from the housing, avoiding frequent opening and closing of the spool and housing, improving the durability of the fishing tackle storage components, increasing operational efficiency, and allowing the line outlet end to be replaced according to actual needs, providing storage flexibility and functional adaptability.
[0018] Furthermore, when the lead end and the groove are aligned, the buckle is located within the notch. These two positioning methods work together to assist in spool positioning. This dual positioning function improves the docking accuracy between components, facilitates quick positioning and installation of the spool and housing by the operator, reduces assembly errors, and achieves efficient and rapid assembly.
[0019] Furthermore, the first baffle wall is abutted against the open end face of the shell. Compared with the independent end cap and flip-top buckle design in traditional storage components, this design omits the flip-top structure and cleverly uses the first baffle wall to seal the open end of the shell, saving manufacturing materials and making the overall structure compact and easy to put in and take out.
[0020] Furthermore, the second baffle has a radially formed slit for the fishing line to pass through. This slit firmly locks the beginning of the fishing line, ensuring that each loop of line fits tightly and preventing loosening or displacement due to uneven force.
[0021] The beneficial effects of this utility model are: the fishing tackle storage component can quickly store fishing lines. The overall structure is completed by the cooperation of the spool and the shell. After the fishing line is wound and stored in the spool, it is placed in the shell. Then the spool rotates circumferentially relative to the shell. After rotating at a certain angle, the locking structure forms a radial anti-detachment fit inside. At the same time, the first baffle of the spool seals the opening of the shell, which functions as a cover for the opening of the shell, eliminating the need for a flip-top structure and reducing the overall structural weight. During the assembly of the spool and the shell, stable locking assembly is achieved by two actions: axial insertion and circumferential rotation. The assembly process is simple, and the spool and the shell are not easy to separate after assembly, effectively preventing the storage component from being accidentally opened by external force. At the same time, it improves the convenience of carrying fishing tackle and the space utilization rate. Attached Figure Description
[0022] Figure 1 An exploded view of the fishing gear storage component provided by this utility model.
[0023] Figure 2 The three-dimensional fishing gear storage component provided by this utility model Figure 1 .
[0024] Figure 3 The three-dimensional fishing gear storage component provided by this utility model Figure 2 .
[0025] Figure 4 The three-dimensional spool provided by this utility model Figure 1 .
[0026] Figure 5 The three-dimensional shell provided by this utility model Figure 1 .
[0027] Figure 6 Cross-sectional view of the fishing gear storage component provided by this utility model Figure 1 .
[0028] Figure 7 The three-dimensional spool provided by this utility model Figure 2 .
[0029] Figure 8 The three-dimensional shell provided by this utility model Figure 2 .
[0030] Figure 9 Cross-sectional view of the fishing gear storage component provided by this utility model Figure 2 .
[0031] Among them, 1-spool, 11-first baffle, 12-second baffle, 121-groove, 122-gap, 13-winding body, 14-lock hole, 2-shell, 21-cavity, 211-ring protrusion, 22-opening, 23-positioning part, 24-lead end, 241-lead outlet, 242-ring groove, 3-locking structure, 31-limiting boss, 32-notch groove, 33-buckle, 331-inclined guide surface. Detailed Implementation
[0032] To enable those skilled in the art to better understand the present invention, the technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only a part of the embodiments of the present invention, and not all of them. All other embodiments obtained by those skilled in the art based on the embodiments of the present invention without creative effort should fall within the scope of protection of the present invention.
[0033] like Figures 1-3 As shown, a fishing tackle storage assembly includes a spool 1 and a housing 2. The spool 1 includes a winding body 13 and a first baffle 11 and a second baffle 12 distributed parallel to each other on both sides of the winding body 13. The first baffle 11 and the second baffle 12 are annular, and the outer diameter of the first baffle 11 is larger than the outer diameter of the second baffle 12. A locking hole 14 is formed inside the winding body 13, and the locking hole 14 is concentric and coaxial with the winding body 13. Specifically, when the fishing line is wound around the winding body 13, because the first baffle 11 and the second baffle 12 are distributed parallel to each other on both sides of the winding body 13, the winding range of the fishing line is limited between the first baffle 11 and the second baffle 12. After the fishing line is stored, the spool 1 can be placed entirely into the housing 2.
[0034] like Figure 1 As shown, the shell 2 is cylindrical, with an internal cavity 21 that matches the size and shape of the spool 1. This cavity 21 is concentric and coaxial with the shell 2. The bottom surface of the shell 2 is the first side of the cavity 21, which is closed, while the top surface of the shell 2 is the second side of the cavity 21, which is completely open, forming an opening 22. The first and second sides of the cavity 21 are positioned opposite each other. A positioning part 23 is provided inside the cavity 21. This positioning part 23 is a hollow annular structure that extends vertically upward from the bottom surface of the shell 2, and it is concentric and coaxial with the cavity 21.
[0035] A locking structure 3 is formed between the positioning part 23 and the inner wall of the lock hole 14. When the spool 1 is axially inserted into the cavity 21 of the housing 2 from the opening 22, the locking structure 3 achieves mutual nesting between the lock hole 14 and the internal structure of the positioning part 23, preventing the spool 1 from moving radially relative to the housing 2. Then, when the spool 1 is rotated circumferentially relative to the housing 2 by a certain angle, the locking structure 3 makes the inner wall of the lock hole 14 and the positioning part 23 form an anti-disengagement fit in the axial direction, preventing the spool 1 from moving axially away from the housing 2. In this state, the first baffle 11 just seals the opening 22 of the housing 2. Compared to the independent end caps and flip-top buckles in traditional storage components, this design omits the flip-top structure and cleverly uses the first baffle 11 to seal the opening 22 of the housing 2, saving manufacturing materials. Moreover, during the assembly of the spool 1 and the housing 2, stable locking assembly is achieved by using two actions: axial insertion and circumferential rotation. The assembly process is simple, and the spool 1 and the housing 2 are not easily separated after assembly. In addition, the locking structure 3 is located between the positioning part 23 and the inner wall of the lock hole 14, effectively utilizing the internal space of the positioning part 23 and the lock hole 14 without adding extra volume, reducing the overall structural weight, and increasing storage space.
[0036] like Figures 1-6 As shown, the locking structure 3 includes a limiting boss 31, a notch 32, and a latch 33 located between the lock hole 14 and the positioning part 23. The positioning part 23 is adapted to the size of the lock hole 14. The limiting boss 31 protrudes from the inner surface of the lock hole 14 or the inner surface of the positioning part 23. The notch 32 is formed by interruption of the circumferentially extending limiting boss 31. The circumferential width of the latch 33 is less than or equal to the circumferential width of the notch 32. When the spool 1 is inserted into the cavity 21 of the housing 2, part of the structure of the latch 33 extends into the notch 32, and then the spool 1 and the housing 2 rotate circumferentially relative to each other. At this time, the latch 33 rotates away from the notch 32 and coincides with the projection of the limiting boss 31 in the axial direction, thereby realizing the contact between the end face of the latch 33 and the limiting boss 31, forming an anti-disengagement fit between the latch 33 and the limiting boss 31 in the axial direction. Here, the axial direction is the direction of the central axis of the spool 1 and the housing 2. The specific distribution of the limiting boss 31, notch 32 and buckle 33 is not limited for now, as long as they can achieve the function of radial limiting after axial insertion and anti-disengagement after circumferential rotation.
[0037] like Figures 5-6As shown, after the spool 1 is placed into the housing 2, to prevent excessive contact area between the second baffle 12 of the spool 1 and the bottom surface of the housing 2, which would lead to excessive rotational resistance and easy wear, an arc-shaped circular protrusion 211 surrounding the axis is provided on the bottom surface of the housing 2. Specifically, after the spool 1 is placed into the housing 2, the top surface of the circular protrusion 211 forms an annular support surface with the second baffle 12. The second baffle 12 only contacts the top of the circular protrusion 211, so that the second baffle 12 does not directly contact the bottom surface of the housing 2, greatly reducing the contact area between the two, and keeping the spool 1 in a relatively vertical state inside the housing 2. While ensuring the smooth rotation of the locking structure 3, it effectively reduces rotational friction, reduces the external force required for rotation, makes operation easier, and slows down wear between components, extending the service life of the components.
[0038] like Figures 4-6 As shown, when the limiting boss 31 and the notch 32 are located inside the lock hole 14, and the buckle 33 is located on the positioning part 23, the locking structure 3 is specifically designed such that the limiting boss 31 is formed by extending circumferentially along the inner wall of the lock hole 14, and the notch 32 is formed by its interruption. The buckle 33 is formed at the rear end of the positioning part 23 extending along the axial direction, which cooperates with the notch 32. Specifically, when the spool 1 is inserted into the cavity 21 of the housing 2, the buckle 33 on the positioning part 23 extends into the notch 32 in the lock hole 14, and then rotates the spool 1 and the housing 2 in a circumferential direction. At this time, the buckle 33 on the positioning part 23 rotates away from the notch 32 in the lock hole 14 and coincides with the projection of the limiting boss 31 in the lock hole 14 in the axial direction. This achieves the abutment between the buckle 33 on the positioning part 23 and the end face of the limiting boss 31 in the lock hole 14, forming an anti-disengagement engagement between the buckle 33 on the positioning part 23 and the limiting boss 31 in the lock hole 14 in the axial direction.
[0039] like Figures 7-9 As shown, when the limiting boss 31 and the notch 32 are located within the positioning part 23, and the buckle 33 is located on the lock hole 14, the locking structure 3 is specifically designed such that the inner wall of the positioning part 23 extends circumferentially to form the limiting boss 31, which is interrupted to form the notch 32. The rear end of the lock hole 14 extends along the axial direction to form the buckle 33, which cooperates with the notch 32. The specific steps for implementing the anti-disengagement engagement of the locking structure 3 are the same as described above, and will not be repeated here.
[0040] like Figures 4-5 , Figures 7-8 As shown, in this embodiment, there are two notches 32, which are radially symmetrically distributed and correspond to the number and position of the latches 33. Each latch 33 has an inclined guide surface 331. Specifically, as... Figure 5As shown, the inclined guide surface 331 extends from top to bottom and from inside to outside, thereby guiding the buckle 33 along the preset path of the notch 32 to accurately place the spool 1 into the housing 2. This inclined guide surface 331 acts as a guide, reducing the probability of misalignment during installation and ensuring smooth operation of the subsequent locking function. In this embodiment, the design of two radially symmetrical notches 32 and buckles 33 ensures a more balanced circumferential locking force between the buckles 33 and the limiting boss 31, resulting in a more stable lock between the spool 1 and the housing 1. Of course, in other embodiments, the number of notches 32 can be several, and the number of buckles 33 should be increased accordingly, depending on the actual situation.
[0041] like Figures 1-3 , Figure 5 , Figure 8 As shown, a line outlet 24 is provided at the notch in the side wall of the housing 2. This line outlet 24 has a line outlet 241 that penetrates the side wall and communicates with the cavity 21. To facilitate changing the size of the line outlet 241, the line outlet 24 is set as an independent component, and an annular groove 242 is provided on the outer periphery of the line outlet 24. The side wall of the housing 2 is inserted into the annular groove 242 for a tight fit. Specifically, a notch is formed in the side wall of the housing 2 for the line outlet 24 to be inserted. A suitable line outlet 24 is selected, and the annular groove 242 is inserted into the notch in the side wall of the housing 2. Before the spool 1 is placed into the housing 2, the starting end of the fishing line is led out from the line outlet 241. After the assembly of the spool 1 and the housing 2 is completed, the fishing line can be used directly from the line outlet 241. This design eliminates the need for opening and closing, allowing direct access to the fishing line. This means that the fishing line can be retrieved without removing the spool 1 from the housing 2, avoiding frequent opening and closing of the spool 1 and housing 2. This improves the durability of the fishing tackle storage components, increases operational efficiency, and allows the line outlet 24 to be replaced according to actual needs, providing storage flexibility and functional adaptability.
[0042] like Figure 1 , Figures 7-8 As shown, the second baffle 12 has a groove 121 through which the lead wire 24 passes. When the spool 1 is inserted into the cavity 21 of the housing 2, the groove 121 of the second baffle 12 aligns with the lead wire 24, and at the same time, the buckle 33 and the notch 32 are aligned vertically. Thus, when the spool 1 and the housing 2 are aligned and engaged through the groove 121 and the lead wire 24, the buckle 33 and the notch 32 are simultaneously aligned and engaged. This design can assist in the positioning of the spool 1. The dual positioning function improves the docking accuracy between components, facilitates the operator to quickly position and install the spool 1 and the housing 2, reduces assembly errors, and achieves efficient and rapid assembly.
[0043] like Figure 4 , Figure 7As shown, the second baffle 12 forms a slit 122 in the radial direction for the fishing line to pass through. Before the fishing line begins to wind around the winding body 13, a certain length of the starting end of the fishing line is reserved and embedded in the slit 122. Then the fishing line is wound. The slit 122 fixes the starting end of the fishing line on the spool 1, so that each turn of the fishing line fits tightly and avoids loosening and displacement due to uneven force.
[0044] The specific assembly process of the spool 1 and the housing 2 in this utility model is as follows: First, the fishing line is wound around the winding body 13 as the axis. After winding, a certain length of fishing line is reserved as the starting end for use. The starting end of the fishing line is led out of the housing 2 through the line outlet 241 for easy retrieval later. Then, the groove 121 on the second baffle 12 is aligned with the line outlet end 24 on the side wall of the housing 2. At this time, the locking hole 14 in the spool 1 is axially aligned with the positioning part 23 in the cavity 21. The spool 1 is axially inserted into the cavity 21 of the housing 2 from the opening 22. Then, the spool 1 is rotated circumferentially relative to the housing 2 by a certain angle, so that the inner wall of the locking hole 14 and the positioning part 23 form a locking structure 3, preventing the spool 1 from detaching from the housing 2. In this state, the first baffle 11 and the opening 22 of the housing 2 are abutted, and the first baffle 1 completely seals the opening 22 of the housing 2.
[0045] When it is necessary to remove the spool 1, rotate the spool 1 in the opposite direction relative to the housing 2 to release the locking structure 3 between the inner wall of the locking hole 14 and the positioning part 23, so that the spool 1 and the housing 2 are disconnected. At this time, the spool 1 can be easily removed from the cavity 21 of the housing 2 by pulling it axially.
[0046] The above specific embodiments are used to explain and illustrate the present utility model, and are not intended to limit the present utility model. Any modifications and changes made to the present utility model within the spirit and scope of the claims shall fall within the protection scope of the present utility model.
Claims
1. A fishing gear storage component, characterized in that, include: A spool (1) for winding fishing line has a first baffle (11) and a second baffle (12) that are parallel to each other, and a winding body (13) located between the first baffle (11) and the second baffle (12). The outer diameter of the first baffle (11) is larger than the outer diameter of the second baffle (12). A lock hole (14) is formed inside the winding body (13). The housing (2) forms a cavity (21) for placing the bobbin (1). The first side of the cavity (21) is closed, and the second side opposite to the first side forms an open opening (22). The cavity (21) is provided with a positioning part (23). A locking structure (3) is formed between the inner wall of the lock hole (14) and the positioning part (23). The spool (1) is inserted into the cavity (21) of the housing (2) and rotates circumferentially relative to the housing (2). The locking structure (3) forms an anti-disengagement fit between the housing (2) and the spool (1) in the axial direction, and the first baffle (11) seals the opening (22) of the housing (2).
2. The fishing gear storage component according to claim 1, characterized in that: The locking structure (3) includes a limiting boss (31), a notch (32) and a buckle (33) located between the lock hole (14) and the positioning part (23). The spool (1) is inserted into the cavity (21) of the housing (2). Part of the buckle (33) extends into the notch (32) and rotates the spool (1) and the housing (2) circumferentially. The buckle (33) and the limiting boss (31) abut against each other to form an anti-disengagement fit in the axial direction.
3. The fishing gear storage component according to claim 2, characterized in that: The positioning part (23) extends along the axial direction, and a buckle (33) is formed at its end. The limiting boss (31) extends circumferentially along the inner wall of the lock hole (14) and is interrupted to form a notch (32). The buckle (33) extends into the notch (32).
4. The fishing gear storage component according to claim 2, characterized in that: The inner wall of the positioning part (23) extends circumferentially to form a limiting boss (31) and interrupts to form a notch (32). The lock hole (14) extends along the axial direction and its end forms a buckle (33). The buckle (33) extends into the notch (32).
5. The fishing gear storage component according to claim 3 or 4, characterized in that: The number of notches (32) is two, and they are arranged radially symmetrically.
6. The fishing gear storage component according to claim 3 or 4, characterized in that: The buckle (33) has an inclined guide surface (331) for guiding the spool (1) into the cavity (21) of the housing (2).
7. The fishing gear storage component according to claim 2, characterized in that: The housing (2) has a wire outlet (24) with a wire outlet (241) through the side wall and the wire outlet (241) is connected to the cavity (21); the second baffle (12) has a groove (121) through which the wire outlet (24) passes.
8. The fishing gear storage component according to claim 7, characterized in that: When the outlet end (24) and the groove (121) are aligned, the buckle (33) is located in the notch (32).
9. The fishing gear storage component according to claim 1, characterized in that: The first baffle (11) is abutted against the end face of the opening (22) of the shell (2).
10. The fishing gear storage component according to claim 1, characterized in that: The second baffle (12) forms a slit (122) in the radial direction for the fishing line to pass through.