Hand accessory data cable
By designing an elastic, anti-shake cable body and an end-capturing structure for the data cable, the problems of inconvenient carrying and easily damaged ends of the data cable are solved, achieving a portable and aesthetically pleasing way to wear the data cable and extending its service life.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DONGGUAN HANHUI ELECTRONICS
- Filing Date
- 2025-04-14
- Publication Date
- 2026-06-16
AI Technical Summary
Existing data cables are too long, making them inconvenient to carry, and the exposed ends are easily damaged, affecting their lifespan.
A bracelet data cable was designed, which uses an elastic and stretchable anti-sway wire body. The end can be inserted into the receiving cavity of the connector to form a loop for wearing. The elastic wire and the braided structure of the wire mesh provide flexibility and elasticity. The locking plate improves the connection stability, and the decorative beads enhance the aesthetics.
It achieves portability and end protection for the data cable, extends its service life, and improves the user experience and aesthetics.
Smart Images

Figure CN224367318U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of electronic product technology, and in particular to a data cable for jewelry. Background Technology
[0002] With the advancement of technology and the booming development of electronic products, they are widely used in people's daily lives. Through electronic products, users can surf the internet, search for items, and take photos anytime, anywhere. However, prolonged use of electronic products can quickly drain their batteries, or when connecting them to other devices, a data cable is needed. Therefore, data cables are widely used as dedicated tools for information transmission and charging electronic products. Users typically need to carry chargers and charging cables when they go out, but existing data cables are often too long and inconvenient to store. Even when coiled, they tend to unravel or tangle, making them unsuitable for use and carrying. Furthermore, existing data cables often lack dedicated end protection when stored, leaving the ends exposed, which can easily damage the cable and shorten its lifespan. Utility Model Content
[0003] To overcome the shortcomings mentioned above, this utility model aims to provide a technical solution that can solve the above problems.
[0004] A bracelet data cable includes an elastic and length-extendable anti-slip cable. One end of the anti-slip cable is provided with a first connector having a first end, and the other end of the anti-slip cable is provided with a second connector having a second end. The end face of the first connector has a first receiving cavity for inserting the second end, and the end face of the second connector has a second receiving cavity for inserting the first end. The first end and the second end can be inserted into the first receiving cavity and the second receiving cavity respectively, so that the anti-slip cable is connected end to end to form a loop.
[0005] As a further embodiment of this utility model: the anti-sway wire body includes an elastic wire and a wire mesh. The elastic wire is elastic and its length is stretchable. The wire mesh covers the elastic wire and is made of several wires wound around it. The several wires are spirally oriented along the axis of the elastic wire. The several wires are divided into a first wire group and a second wire group. The wires of the first wire group and the wires of the second wire group have opposite spiral directions. The wires of the first wire group and the wires of the second wire group are interwoven together.
[0006] As a further embodiment of this utility model: one end of the first connecting seat is stepped and has a first stepped surface, a first contact surface and a second stepped surface. The first accommodating cavity is disposed on the first stepped surface and the first end is disposed on the second stepped surface. One end of the second connecting seat is stepped and has a third stepped surface, a second contact surface and a fourth stepped surface. The second accommodating cavity is disposed on the third stepped surface and the second end is disposed on the fourth stepped surface. When the first end and the second end are respectively inserted into the first accommodating cavity and the second accommodating cavity, the first contact surface and the second contact surface fit together.
[0007] As a further embodiment of this utility model, it also includes a locking plate, which is composed of a top plate and side plates connected to both sides of the top plate. Both side plates are provided with pivot holes. The first connecting seat is provided with pivots on both sides that cooperate with the pivot holes. The top plate can pivot to fit against the second connecting seat. The ends of the side plates are bent to form a snap-fit portion. The second connecting seat is provided with a groove. When the top plate fits against the second connecting seat, the snap-fit portion engages with the groove.
[0008] As a further embodiment of this utility model: the end of the top plate is bent to form a folded edge.
[0009] As a further embodiment of this utility model: a number of decorative beads are sleeved on the anti-shaking wire body.
[0010] As a further embodiment of this utility model: if the number of wires is even, the number of wires in the first wire group is equal to the number of wires in the second wire group, the wires in the first wire group are arranged side by side in a counterclockwise spiral along the axis of the elastic line, a first gap is formed between any two adjacent wires in the first wire group, and a first coil is formed between the wires in the first wire group and the elastic line respectively; the wires in the second wire group are arranged side by side in a clockwise spiral along the axis of the elastic line, a second gap is formed between any two adjacent wires in the second wire group, and a second coil is formed between the wires in the second wire group and the elastic line respectively; the wires in the second wire group are inserted into the first gap and the first coil, and the wires in the first wire group are inserted into the second gap and the second coil.
[0011] As a further embodiment of this utility model: if the number of wires is odd, the first wire group has one less wire than the second wire group, and the wire network also includes a fixed wire. The wires of the first wire group and the fixed wire are arranged side by side in a counterclockwise spiral pattern along the axis of the elastic line. A first gap is formed between the fixed wire and its adjacent wires, as well as between any two adjacent wires of the first wire group. A first coil is formed between the fixed wire and the elastic line, as well as between the wires of the first wire group and the elastic line. The wires of the second wire group are arranged side by side in a clockwise spiral pattern along the axis of the elastic line. A second gap is formed between any two adjacent wires of the second wire group. A second coil is formed between the wires of the second wire group and the elastic line. The wires of the second wire group are inserted into the first gap and the first coil, and the wires of the first wire group are inserted into the second gap and the second coil.
[0012] Compared with the prior art, the beneficial effects of this utility model are as follows: By setting a first accommodating cavity and a second accommodating cavity on the first connecting seat and the second connecting seat, the first end and the second end can be inserted into the first accommodating cavity and the second accommodating cavity during use, so that the anti-twist cable body forms a loop and is worn on the user's hand, which is convenient to carry. In addition, the first accommodating cavity and the second accommodating cavity can cover the first end and the second end, preventing the first end and the second end from being exposed, reducing the damage to the first end and the second end, and extending the service life of the data cable.
[0013] Additional aspects and advantages of this invention will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. Attached Figure Description
[0014] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0015] Figure 1 This is a schematic diagram of the structure of this utility model.
[0016] Figure 2 This is a schematic diagram of the top plate structure of this utility model.
[0017] Figure 3 This is a schematic diagram of the folded edge portion of this utility model.
[0018] Figure 4 This is a schematic diagram of one embodiment of the anti-cracking body of this utility model.
[0019] Figure 5 This is a schematic diagram of another embodiment of the anti-cracking body of this utility model.
[0020] Figure 6 This is a schematic diagram of another embodiment of the anti-cracking body of this utility model.
[0021] In the diagram: 1. Anti-sway wire body, 2. First connecting seat, 3. Second connecting seat, 4. Locking plate, 5. Decorative bead, 11. Elastic wire, 12. Wire mesh, 13. Wire, 140. First wire group, 150. Second wire group, 141. First gap, 142. First coil, 151. Second gap, 152. Second coil, 16. Fixed wire, 21. First end, 22. First receiving cavity, 23. First stepped surface, 24. First contact surface, 25. Second stepped surface, 26. Pivot, 31. Second end, 32. Second receiving cavity, 33. Third stepped surface, 34. Second contact surface, 35. Fourth stepped surface, 36. Groove, 41. Top plate, 42. Side plate, 43. Pivot hole, 44. Snap-fit part, 45. Folded edge part. Detailed Implementation
[0022] The technical solutions in the embodiments of this utility model will be clearly and completely described below. Obviously, the described embodiments are only some embodiments of this utility model, and not all embodiments. Based on the embodiments of this utility model, all other embodiments obtained by those skilled in the art without creative effort are within the protection scope of this utility model.
[0023] Please see Figures 1-6 In this embodiment of the present invention, a bracelet data cable includes an elastic and length-extendable anti-sway cable body 1. One end of the anti-sway cable body 1 is provided with a first connecting seat 2 having a first end 21, and the other end of the anti-sway cable body 1 is provided with a second connecting seat 3 having a second end 31. The end face of the first connecting seat 2 is provided with a first receiving cavity 22 for inserting the second end 31, and the end face of the second connecting seat 3 is provided with a second receiving cavity 32 for inserting the first end 21. The first end 21 and the second end 31 can be inserted into the first receiving cavity 22 and the second receiving cavity 32 respectively, so that the anti-sway cable body 1 is connected end to end to form a loop.
[0024] This utility model provides a first receiving cavity 22 and a second receiving cavity 32 on the first connecting seat 2 and the second connecting seat 3. In use, the first end 21 and the second end 31 can be inserted into the first receiving cavity 22 and the second receiving cavity 32, so that the anti-snagging cable 1 forms a loop and is worn on the user's hand for easy carrying. Furthermore, the first receiving cavity 22 and the second receiving cavity 32 can cover the first end 21 and the second end 31, preventing them from being exposed, reducing damage to the first end 21 and the second end 31, and extending the service life of the data cable. In addition, by providing an elastic and extendable anti-snagging cable 1, when wearing it, the ends of the anti-snagging cable 1 are connected to form a loop, and then the elastic force of the anti-snagging cable 1 is used to directly wear it on the hand. The whole process is simple to operate.
[0025] The anti-sway wire 1 includes an elastic wire 11 and a mesh 12. The elastic wire 11 is elastic and its length is stretchable. The mesh 12 covers the elastic wire 11 and is made of several conductors 13 wound together. The conductors 13 are spirally arranged along the axis of the elastic wire 11. The conductors 13 are divided into a first conductor group 140 and a second conductor group 150. The spiral directions of the conductors 13 in the first conductor group 140 and the second conductor group 150 are opposite. The conductors 13 in the first conductor group 140 and the second conductor group 150 are interwoven together. In this way, when the anti-sway wire 1 is subjected to tension or bending, the elastic wire 11 can drive the mesh 12 woven from the conductors 13 to deform, adapting to the process of stretching and bending, and has a tendency to automatically retract. Therefore, the anti-sway wire 1 has a certain elastic recovery performance and a high swing life and tensile life.
[0026] In the above embodiments, reference is made to Figure 4 If the number of wires 13 is even, the number of wires 13 in the first wire group 140 is equal to the number of wires 13 in the second wire group 150. The wires 13 in the first wire group 140 are arranged side by side in a counterclockwise spiral along the axis of the elastic line 11. A first gap 141 is formed between any two adjacent wires 13 in the first wire group 140. A first coil 142 is formed between the wires 13 in the first wire group 140 and the elastic line 11. The wires 13 in the second wire group 150 are arranged side by side in a clockwise spiral along the axis of the elastic line 11. A second gap 151 is formed between any two adjacent wires 13 in the second wire group 150. A second coil 152 is formed between the wires 13 in the second wire group 150 and the elastic line 11. The wires 13 in the second wire group 150 are interspersed in the first gap 141 and the first coil 142. The wires 13 in the first wire group 140 are interspersed in the second gap 151 and the second coil 152.
[0027] In the above embodiment, the spiral structure formed by the first conductor group 140 is fixed by the second conductor group 150. The two groups of conductors 13 interweave and wrap around the elastic wire 11, making the wire mesh 12 more stably cover the elastic wire 11 and less prone to scattering. Figure 4 As shown, both the first conductor group 140 and the second conductor group 150 are spirally wound around the elastic wire 11. The spiral direction of the first conductor group 140 is opposite to that of the second conductor group 150. That is, the conductors 13 of the first conductor group 140 and the conductors 13 of the second conductor group 150 are interwoven, forming spiral shapes in opposite directions. Specifically, during the weaving process, while the conductors 13 of the second conductor group 150 are spirally wound, they are also inserted into the first gap 141 of the first conductor group 140. Following the spiral extension direction, after extending out of the first gap 141, the conductors 13 of the second conductor group 150 are then inserted into the adjacent first coil 142 near the elastic wire. The surface of the first conductor group 140 extends through the second conductor group 150 and then passes through the second gap 151 of the second conductor group 150. Along the spiral extension direction, the conductor 13 of the first conductor group 140 extends through the second gap 151 and then passes through the adjacent second coil 152 near the surface of the elastic wire 11. Then it passes through the second gap 151 and passes through the surface of the second gap 151. This cycle is repeated to form a wire mesh 12. When the wire mesh 12 is stretched and bent, it produces a deformation with an increased pitch, so that the anti-wrinkle wire body 1 has the advantages of flexibility, stretchability, and good elasticity.
[0028] refer to Figure 5If the number of conductors 13 is odd, the first conductor group 140 has one less conductor 13 than the second conductor group 150. The wire mesh 12 also includes a fixed wire 16. The conductors 13 and the fixed wire 16 of the first conductor group 140 are arranged side by side in a counterclockwise spiral along the axis of the elastic wire 11. A first gap 141 is formed between the fixed wire 16 and its adjacent conductors 13, as well as between any two adjacent conductors 13 in the first conductor group 140. The gaps between the fixed wire 16 and the elastic wire 11, and between the conductors 13 and the elastic wire 11 in the first conductor group 140 are also defined. A first coil 142 is formed between the first wire group 140 and the elastic wire 11. The wires 13 of the second wire group 150 are arranged side by side in a clockwise spiral along the axis of the elastic wire 11. A second gap 151 is formed between any two adjacent wires 13 of the second wire group 150. A second coil 152 is formed between the wires 13 of the second wire group 150 and the elastic wire 11. The wires 13 of the second wire group 150 are inserted into the first gap 141 and the first coil 142, and the wires 13 of the first wire group 140 are inserted into the second gap 151 and the second coil 152. In this embodiment, the spiral structure formed by the second wire group 150 is fixed by the first wire group 140 and the fixing wire 16. The winding method is the same as in the above embodiment and will not be described again here.
[0029] Based on the above, the present invention also provides an embodiment of the wire mesh 12, see reference. Figure 6 In this embodiment, the wire mesh includes a conductor 13 and a fixing wire 16. The fixing wire 16 spirals counterclockwise along the axial direction of the elastic wire 11, and the spiral formed by the fixing wire 16 contains several first gaps 141 and first coils 142. The conductor 13 spirals clockwise along the axial direction of the elastic wire 11, and the spiral formed by the conductor 13 contains several second gaps 151 and second coils 152. The conductor 13 passes through the first gaps 141 and first coils 142, and the fixing wire 16 passes through the second gaps 151 and second coils 152. In this embodiment, the spiral structure formed by the conductor 13 is fixed by the fixing wire 16, and the winding method is the same as in the above embodiment, and will not be described again here.
[0030] One end of the first connecting seat 2 is stepped, forming a first stepped surface 23, a first contact surface 24, and a second stepped surface 25. A first receiving cavity 22 is disposed on the first stepped surface 23, and a first end 21 is disposed on the second stepped surface 25. One end of the second connecting seat 3 is stepped, forming a third stepped surface 33, a second contact surface 34, and a fourth stepped surface 35. A second receiving cavity 32 is disposed on the third stepped surface 33, and a second end 31 is disposed on the fourth stepped surface 35. When the first end 21 and the second end 31 are respectively inserted into the first receiving cavity 22 and the second receiving cavity 32, the first contact surface 24 and the second contact surface 34 fit together. In this way, the first connecting seat 2 and the second connecting seat 3 can fit together precisely and are not easily offset vertically.
[0031] It also includes a locking plate 4, which consists of a top plate 41 and side plates 42 connected to both sides of the top plate 41. Both side plates 42 have pivot holes 43. The first connecting seat 2 has pivots 26 on both sides that mate with the pivot holes 43. The top plate 41 can rotate via the pivots 26 to fit against the second connecting seat 3. The ends of the side plates 42 are bent to form locking portions 44. The second connecting seat 3 has grooves 36. When the top plate 41 fits against the second connecting seat 3, the locking portions 44 engage with the grooves 36. When the first end 21 and the second connecting seat 3 are respectively inserted into the first receiving cavity 22 and the second receiving cavity 32, the locking plate 4 can be rotated to engage the locking portions 44 in the grooves 36, thereby improving the tightness of the connection between the first connecting seat 2 and the second connecting seat 3.
[0032] The top plate 41 has a bent edge 45 at its end. When it is necessary to separate the first connecting seat 2 from the second connecting seat 3, the locking plate 4 can be lifted through the bent edge 45 to disengage the snap-fit part 44 from the groove 36 for easy use.
[0033] The anti-slip cable body 1 is fitted with several decorative beads 5. This enhances the aesthetics of the data cable and caters to the preferences of fashion-conscious individuals.
[0034] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered exemplary and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, it is intended that all variations falling within the meaning and scope of equivalents of the claims be included within this invention.
Claims
1. A hand accessory data cord, characterized in that, The device includes an elastic and length-extendable anti-cracking wire. One end of the anti-cracking wire is provided with a first connecting seat having a first end, and the other end of the anti-cracking wire is provided with a second connecting seat having a second end. The end face of the first connecting seat is provided with a first receiving cavity for inserting the second end, and the end face of the second connecting seat is provided with a second receiving cavity for inserting the first end. The first end and the second end can be inserted into the first receiving cavity and the second receiving cavity respectively, so that the anti-cracking wire is connected end to end to form a ring. It also includes a locking plate, which consists of a top plate and side plates connected to both sides of the top plate. Both side plates have pivot holes. The first connecting seat has pivots on both sides that cooperate with the pivot holes. The top plate can pivot to fit against the second connecting seat. The ends of the side plates are bent to form a snap-fit part. The second connecting seat has a groove. When the top plate fits against the second connecting seat, the snap-fit part engages with the groove.
2. The data cable for jewelry according to claim 1, characterized in that: The anti-sway wire body includes an elastic wire and a wire mesh. The elastic wire is elastic and its length can be stretched. The wire mesh covers the elastic wire and is made of several wires wound together. The wires are spirally oriented along the axis of the elastic wire. The wires are divided into a first wire group and a second wire group. The wires of the first wire group and the wires of the second wire group have opposite spiral directions. The wires of the first wire group and the wires of the second wire group are interwoven together.
3. The data cable for jewelry according to claim 1, characterized in that: One end of the first connector is stepped and has a first stepped surface, a first contact surface and a second stepped surface. The first receiving cavity is disposed on the first stepped surface and the first end is disposed on the second stepped surface. One end of the second connector is stepped and has a third stepped surface, a second contact surface and a fourth stepped surface. The second receiving cavity is disposed on the third stepped surface and the second end is disposed on the fourth stepped surface. When the first end and the second end are respectively inserted into the first receiving cavity and the second receiving cavity, the first contact surface and the second contact surface fit together.
4. The data cable for jewelry according to claim 1, characterized in that: The top plate has a bent edge at the end.
5. A data cable for jewelry as described in claim 1, characterized in that: Several decorative beads are fitted onto the anti-shake wire body.
6. A data cable for jewelry according to claim 2, characterized in that: If the number of wires is even, the number of wires in the first wire group is equal to the number of wires in the second wire group. The wires in the first wire group are parallel to each other and spiral counterclockwise along the axis of the elastic line. A first gap is formed between any two adjacent wires in the first wire group. A first coil is formed between the wires in the first wire group and the elastic line. The wires in the second wire group are parallel to each other and spiral clockwise along the axis of the elastic line. A second gap is formed between any two adjacent wires in the second wire group. A second coil is formed between the wires in the second wire group and the elastic line. The wires in the second wire group are interwoven in the first gap and the first coil. The wires in the first wire group are interwoven in the second gap and the second coil.
7. A data cable for jewelry according to claim 2, characterized in that: If the number of wires is odd, the first wire group has one less wire than the second wire group, and the wire network also includes a fixed wire. The wires of the first wire group and the fixed wire are parallel to each other and spiral counterclockwise along the axis of the elastic wire. A first gap is formed between the fixed wire and its adjacent wires, as well as between any two adjacent wires in the first wire group. A first coil is formed between the fixed wire and the elastic wire, as well as between the wires of the first wire group and the elastic wire. The wires of the second wire group are parallel to each other and spiral clockwise along the axis of the elastic wire. A second gap is formed between any two adjacent wires in the second wire group. A second coil is formed between the wires of the second wire group and the elastic wire. The wires of the second wire group are interwoven in the first gap and the first coil, and the wires of the first wire group are interwoven in the second gap and the second coil.