High-performance data transmission electronic product data line
By using a flat data cable with a hybrid design of fiber optic and copper wires, combined with a binding section and a metal reinforcing frame, the problems of slow data cable transmission speed and inconvenience in carrying are solved, achieving efficient data transmission and portability.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GUIZHOU QILIAN INTELLIGENT TECH CO LTD
- Filing Date
- 2025-05-06
- Publication Date
- 2026-06-19
AI Technical Summary
Existing data cables suffer from slow data transfer speeds over long-term use, especially when transferring large files, and are prone to tangling and knotting when carried, making them inconvenient to use.
It adopts a hybrid design of optical fiber and copper wire, with optical fiber used for data transmission and copper wire used for power supply. The wire body is designed to be flat and has a binding part for easy winding and fixing. The outer sheath is made of braided nylon and TPE composite material, with embedded tensile fiber material to improve flexibility and durability. The interface part uses a metal reinforced skeleton to enhance the structure. The connector and photoelectric conversion module are embedded in the housing.
It improves data transmission speed, solves the problem of traditional data cables being prone to tangling and knotting, and achieves lightweight, durable and portable design, thus enhancing the user experience.
Smart Images

Figure CN224384722U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to a high-performance data transmission electronic product data cable, belonging to the field of electronic equipment technology. Background Technology
[0002] Data cables are used to charge electronic devices or connect them for data transfer or communication. With the rapid development of the electronics industry, data cables have become an indispensable part of our lives. However, existing data cables have some common drawbacks in long-term use. Data transmission is slow, especially with the rapid development of electronic products and the increasing demand for large file transfers. The data transmission speed of existing data cables is too slow, particularly when the cables are long, and their speed is no longer sufficient for daily needs. Furthermore, data cables are prone to tangling and knotting, making them extremely inconvenient to carry. Therefore, we propose a high-performance data transmission cable for electronic products. Utility Model Content
[0003] The purpose of this invention is to provide a high-performance data cable for electronic products that solves the problems that the data transmission speed of existing data cables cannot meet people's daily needs, and that they are easy to get tangled and knotted when carried, making them inconvenient to use.
[0004] To solve the above-mentioned technical problems, this utility model adopts the following technical solution: A high-performance data transmission electronic product data cable includes:
[0005] The cable is flat and contains power lines and optical fibers. The power lines are made of copper wire and there are at least two of them, one for positive and one for negative power supply. The optical fibers are used for data transmission. Multiple power lines can also be used. It is compatible with fast charging protocols such as PD and QC+ and supports high current and high power fast charging. It uses a combination of optical fibers and copper wire power lines. The embedded optical fiber improves the data transmission speed while retaining the copper wire power lines for power supply.
[0006] The interface section has an interface section at both ends of the line body. The interface section contains a connector and a photoelectric conversion module that are electrically connected to each other. The photoelectric conversion module is connected to the optical fiber, and both the connector and the photoelectric conversion module are electrically connected to the power line. The power line and the connector enable the charging function. The photoelectric conversion module converts optical and electrical signals. When necessary, the power line can supply power to the photoelectric conversion module.
[0007] The binding part is provided on the thread body, which can be wound into a roll and fixed by the binding part. The flat thread body is easy to wind up and roll up. After being fixed by the binding part, it is easy to carry and avoids the problems of easy tangling and knotting when carrying, which makes it inconvenient to use.
[0008] The aforementioned high-performance data transmission electronic product data cable includes an outer sheath, which may be made of braided nylon and TPE composite material, with anti-slip texture on the outer surface. The power cord and optical fiber are placed inside the outer sheath. An insulation layer made of flexible insulating material is provided on the surface of the power cord. A protective layer made of aramid fiber is provided on the surface of the optical fiber to improve the bending resistance of the optical fiber cable. A filling layer made of tensile fiber material is provided in the gaps between the outer sheath, the insulation layer, and the protective layer.
[0009] The aforementioned high-performance data transmission electronic product data cable has a power cord and an optical fiber arranged in a straight line in a uniform row. The positive and negative wires of the power cord are respectively set on both sides of the optical fiber, making the cable flat. This avoids the problem of easy knotting of traditional round cables, allowing for easy winding and storage. Furthermore, the positive and negative wires are separated, reducing the occurrence of short circuits.
[0010] The aforementioned high-performance data transmission electronic product data cable includes an interface portion comprising a housing, a connector and a photoelectric conversion module disposed within the housing, wherein the insertion end of the connector extends through the surface of the housing and protrudes outwards, and the end of the cable extends through the surface of the housing away from the connector and into its interior.
[0011] The aforementioned high-performance data transmission electronic product data cable has a reinforcing skeleton that supports the housing within its inner cavity. The reinforcing skeleton is tightly fitted to the surface of the inner cavity of the housing, and a metal reinforcing skeleton is used to support the hard plastic housing, thereby improving the structural strength of the interface.
[0012] The aforementioned high-performance data transmission electronic product data cable has a spring with two ends of different widths on the outer surface of the housing away from the connector. The wider end of the spring is attached to the outer surface of the housing. The spring is sleeved on the outside of the cable body, and the narrower end of the spring extends outward and is attached to the surface of the cable body. The outside of the spring is wrapped with a flexible outer sleeve. The spring and the flexible outer sleeve made of flexible material are added at the connection between the housing and the cable body to distribute the bending pressure.
[0013] The aforementioned high-performance data transmission electronic product data cable includes a binding part comprising a winding part and a flexible fixing strap. Two cylindrical winding parts are provided on both sides of the cable body, and fixing pins are provided at both ends of each winding part. The flexible fixing strap has fixing holes arranged along its length on its surface. The fixing pins can be inserted into and fixed within the fixing holes. A flat cable body can be wound around the two winding parts, and after winding, it is fixed by the flexible fixing strap. Installation is simple and it is easy to carry.
[0014] The aforementioned high-performance data transmission electronic product data cable has a connector that is one of USB-A, USB-C, Lightning, Micro-USB, or Type-C interfaces.
[0015] Compared with existing technologies, this utility model uses a hybrid of optical fiber and copper power cord. The embedded optical fiber improves data transmission speed while retaining the copper power cord for power supply. The ultra-thin copper wire and flexible optical fiber reduce the weight of the cable. It can also adopt a multi-power cord design, is compatible with fast charging protocols such as PD 3.1 and QC 4+, and supports high-current, high-power fast charging. The flat cable body avoids the problem of easy knotting of traditional round cables, can be easily rolled up and stored, and can be fixed by the binding part. The portable design not only solves the problems of traditional cables being bulky, easily damaged, and having poor compatibility, but also achieves breakthroughs in lightweight, durability, and scene adaptability. The improved structure significantly enhances the portability, reliability, and user experience of the device. Attached Figure Description
[0016] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0017] Figure 2 This is a schematic diagram of the internal installation structure of the interface part of this utility model;
[0018] Figure 3 This is a schematic diagram of the line cross-section of this utility model;
[0019] Figure 4 This is a schematic diagram of the reinforced skeleton structure of this utility model;
[0020] Figure 5 This is a schematic diagram of the binding part structure of this utility model;
[0021] Figure 6 This is a schematic diagram of the thread of this utility model when it is wound in the winding section.
[0022] Reference numerals: 1-Line body, 2-Interface part, 3-Power cord, 4-Fiber optic cable, 5-Connector, 6-Photoelectric conversion module, 7-Binding part, 8-Outer sheath, 9-Insulation layer, 10-Protective layer, 11-Filling layer, 12-Shell, 13-Reinforcing skeleton, 14-Spring, 15-Flexible outer jacket, 16-Winding part, 17-Flexible fixing strap, 18-Fixing pin, 19-Fixing hole.
[0023] The present invention will be further described below with reference to the accompanying drawings and specific embodiments. Detailed Implementation
[0024] Embodiment 1 of this utility model: A high-performance data transmission electronic product data cable includes: a cable body 1, which is flat and has power lines 3 and optical fibers 4 inside. The power lines 3 are made of copper wire and at least two are provided, one for positive and one for negative power supply. The optical fibers 4 are used for data transmission. Multiple power lines can also be used in the design, which is compatible with PD 3.1 and QC. The cable supports fast charging protocols such as 4+, enabling high-current and high-power fast charging. It employs a hybrid system of optical fiber 4 and copper power cable 3, with embedded optical fiber 4 enhancing data transmission speed while retaining the copper power cable 3 for power supply. Interface section 2: Both ends of the cable body 1 have interface sections 2, each containing an electrically connected connector 5 and photoelectric conversion module 6. The photoelectric conversion module 6 connects to the optical fiber 4, and both the connector 5 and the photoelectric conversion module 6 are electrically connected to the power cable 3. The power cable 3 and connector 5 enable charging, while the photoelectric conversion module 6 converts light and electrical signals. The power cable 3 can supply power to the photoelectric conversion module 6 when necessary. Binding section 7: Located on the cable body 1, the cable body 1 can be wound into a roll and secured by the binding section 7. The flat shape of the cable body 1 facilitates winding and is easy to carry, avoiding tangling and knotting issues during transport.
[0025] Embodiment 2 of this utility model: A high-performance data transmission electronic product data cable includes: a cable body 1, which is flat and has a power cord 3 and an optical fiber 4 inside. The power cord 3 is made of copper wire and at least two are provided, one for positive and one for negative power supply. The optical fiber 4 is used for data transmission. Multiple power cords can also be used. It is compatible with fast charging protocols such as PD 3.1 and QC 4+, and supports high current and high power fast charging. It uses a combination of optical fiber 4 and copper wire power cord 3, with embedded optical fiber 4 to improve data transmission speed while retaining the copper wire power cord 3 for power supply. The cable body 1 includes an outer sheath 8, which can be made of braided nylon and TPE composite material, with anti-slip texture on the outer surface. The power cord 3 and optical fiber 4 are placed inside the outer sheath 8. An insulation layer 9 is provided on the surface of the power cord 3, which is made of flexible insulating material. A protective layer 10 is provided on the surface of the optical fiber 4 to protect it. The sheath 10 is made of aramid fiber to improve the bending resistance of the optical fiber 4 cable. A filling layer 11 is provided in the gap between the outer sheath 8 and the insulation layer 9 and the protective layer 10. The filling layer 11 is made of tensile fiber material. The power line 3 and the optical fiber 4 are evenly arranged in a straight line, and the positive and negative wires of the power line 3 are respectively set on both sides of the optical fiber 4, making the cable 1 flat. This avoids the problem of easy knotting of traditional round cables, and can be easily wound and stored. The positive and negative wires are separated to reduce the occurrence of short circuits.
[0026] Interface section 2, both ends of the line body 1 are provided with interface section 2, the interface section 2 is provided with connector 5 and photoelectric conversion module 6 which are electrically connected to each other. The photoelectric conversion module 6 is connected to optical fiber 4, and both connector 5 and photoelectric conversion module 6 are electrically connected to power line 3. Power line 3 and connector 5 realize charging function. Photoelectric conversion module 6 performs optical and electrical signal conversion. When necessary, power line 3 can supply power to photoelectric conversion module 6.
[0027] The binding part 7 is disposed on the thread 1. The thread 1 can be wound into a roll and fixed by the binding part 7. The flat thread 1 is easy to wind up and roll up. After being fixed by the binding part 7, it is easy to carry and avoids the problem of easy tangling and knotting when carrying, which is inconvenient to use.
[0028] Embodiment 3 of this utility model: A high-performance data transmission electronic product data cable includes: a cable body 1, which is flat and has a power cord 3 and an optical fiber 4 inside. The power cord 3 is made of copper wire and at least two are provided, one for positive and one for negative power supply. The optical fiber 4 is used for data transmission. Multiple power cords can also be used. It is compatible with fast charging protocols such as PD 3.1 and QC 4+, and supports high current and high power fast charging. It uses a combination of optical fiber 4 and copper wire power cord 3, with embedded optical fiber 4 to improve data transmission speed while retaining the copper wire power cord 3 for power supply. The cable body 1 includes an outer sheath 8, which can be made of braided nylon and TPE composite material, with anti-slip texture on the outer surface. The power cord 3 and optical fiber 4 are placed inside the outer sheath 8. An insulation layer 9 is provided on the surface of the power cord 3. The insulation layer 9 is made of flexible insulating material. A protective layer 10 is provided on the surface of the optical fiber 4 to protect it. The sheath 10 is made of aramid fiber to improve the bending resistance of the optical fiber 4 cable. A filling layer 11 is provided in the gap between the outer sheath 8 and the insulation layer 9 and the protective layer 10. The filling layer 11 is made of tensile fiber material. The power line 3 and the optical fiber 4 are evenly arranged in a straight line, and the positive and negative wires of the power line 3 are respectively set on both sides of the optical fiber 4, making the cable 1 flat. This avoids the problem of easy knotting of traditional round cables, and can be easily wound and stored. The positive and negative wires are separated to reduce the occurrence of short circuits.
[0029] Interface section 2, both ends of the line body 1 are provided with interface section 2, the interface section 2 is provided with connector 5 and photoelectric conversion module 6 electrically connected to each other. The photoelectric conversion module 6 is connected to optical fiber 4, and both connector 5 and photoelectric conversion module 6 are electrically connected to power line 3. Power line 3 and connector 5 realize charging function. Photoelectric conversion module 6 performs optical and electrical signal conversion. When necessary, power line 3 can supply power to photoelectric conversion module 6. The interface section 2 includes housing 12, the connector 5 and photoelectric conversion module 6 are placed in housing 12, and the plug end of connector 5 penetrates through the surface of housing 12 and extends out. The end of line body 1 penetrates through the surface of housing 12 away from connector 5 and extends into its interior.
[0030] The binding part 7 is disposed on the thread 1. The thread 1 can be wound into a roll and fixed by the binding part 7. The flat thread 1 is easy to wind up and roll up. After being fixed by the binding part 7, it is easy to carry and avoids the problem of easy tangling and knotting when carrying, which is inconvenient to use.
[0031] Embodiment 4 of this utility model: A high-performance data transmission electronic product data cable includes: a cable body 1, which is flat and has a power cord 3 and an optical fiber 4 inside. The power cord 3 is made of copper wire and at least two are provided, one for positive and one for negative power supply. The optical fiber 4 is used for data transmission. Multiple power cords can also be used. It is compatible with fast charging protocols such as PD 3.1 and QC 4+, supports high-current and high-power fast charging, and uses a combination of optical fiber 4 and copper wire power cord 3. The embedded optical fiber 4 improves data transmission speed while retaining the copper wire power cord 3 for power supply. The cable body 1 includes an outer sheath 8, which can be made of braided nylon and TPE composite material, with anti-slip texture on the outer surface. The power cord 3 and optical fiber 4 are placed inside the outer sheath 8. An insulation layer 9 is provided on the surface of the power cord 3, which is made of flexible insulating material. A protective layer 10 is provided on the surface of the optical fiber 4 to protect... The sheath 10 is made of aramid fiber to improve the bending resistance of the optical fiber 4 cable. A filling layer 11 is provided in the gap between the outer sheath 8 and the insulation layer 9 and the protective layer 10. The filling layer 11 is made of tensile fiber material. The power line 3 and the optical fiber 4 are evenly arranged in a straight line, and the positive and negative wires of the power line 3 are respectively set on both sides of the optical fiber 4, making the cable 1 flat. This avoids the problem of easy knotting of traditional round cables, and can be easily wound and stored. The positive and negative wires are separated to reduce the occurrence of short circuits.
[0032] Interface section 2: Both ends of the cable 1 are provided with interface section 2. Each interface section 2 contains a connector 5 and a photoelectric conversion module 6 that are electrically connected to each other. The photoelectric conversion module 6 is connected to the optical fiber 4, and both the connector 5 and the photoelectric conversion module 6 are electrically connected to the power cord 3. The power cord 3 and connector 5 enable charging. The photoelectric conversion module 6 converts optical and electrical signals. When necessary, the power cord 3 can supply power to the photoelectric conversion module 6. The interface section 2 includes a housing 12. The connector 5 and the photoelectric conversion module 6 are placed inside the housing 12, with the insertion end of the connector 5 penetrating through the surface of the housing 12 and extending outwards. The end of the cable 1 extends through the surface of the housing 12 away from the connector 5 and into its interior. Simultaneously, a reinforcing frame 13 is provided inside the housing 12 to support it. The reinforcing frame 13 is tightly fitted to the surface of the inner cavity of the housing 12. The metal reinforcing frame 13 supports the hard plastic housing 12, improving the structural strength of the interface section 2.
[0033] The binding part 7 is disposed on the thread body 1. The thread body 1 can be wound into a roll and fixed by the binding part 7. The flat thread body 1 is easy to wind up and is easy to carry after being fixed by the binding part 7, avoiding the problems of easy tangling and knotting during carrying and inconvenience of use. The binding part 7 includes a winding part 16 and a flexible fixing strap 17. There are two winding parts 16, which are cylindrical and are disposed on both sides of the thread body 1. Each end of the winding part 16 is provided with a fixing pin 18. The surface of the flexible fixing strap 17 has fixing holes 19 arranged along the length direction. The fixing pins 18 can be inserted into and fixed in the fixing holes 19. The flat thread body 1 can be wound around the two winding parts 16. After winding, it is fixed by the flexible fixing strap 17. The installation is simple and the carrying is convenient.
[0034] Embodiment 5 of this utility model: A high-performance data transmission electronic product data cable includes: a cable body 1, which is flat and has a power cord 3 and an optical fiber 4 inside. The power cord 3 is made of copper wire and at least two are provided, one for positive and one for negative power supply. The optical fiber 4 is used for data transmission. Multiple power cords can also be used. It is compatible with fast charging protocols such as PD 3.1 and QC 4+, supports high-current and high-power fast charging, and uses a combination of optical fiber 4 and copper wire power cord 3. The embedded optical fiber 4 improves data transmission speed while retaining the copper wire power cord 3 for power supply. The cable body 1 includes an outer sheath 8, which can be made of braided nylon and TPE composite material, with anti-slip texture on the outer surface. The power cord 3 and optical fiber 4 are placed inside the outer sheath 8. An insulation layer 9 is provided on the surface of the power cord 3, which is made of flexible insulating material. A protective layer 10 is provided on the surface of the optical fiber 4 to protect... The sheath 10 is made of aramid fiber to improve the bending resistance of the optical fiber 4 cable. A filling layer 11 is provided in the gap between the outer sheath 8 and the insulation layer 9 and the protective layer 10. The filling layer 11 is made of tensile fiber material. The power line 3 and the optical fiber 4 are evenly arranged in a straight line, and the positive and negative wires of the power line 3 are respectively set on both sides of the optical fiber 4, making the cable 1 flat. This avoids the problem of easy knotting of traditional round cables, and can be easily wound and stored. The positive and negative wires are separated to reduce the occurrence of short circuits.
[0035] Interface section 2: Both ends of the cable 1 are provided with interface section 2. Each interface section 2 contains a connector 5 and a photoelectric conversion module 6 that are electrically connected to each other. The photoelectric conversion module 6 is connected to the optical fiber 4, and both the connector 5 and the photoelectric conversion module 6 are electrically connected to the power cord 3. The power cord 3 and connector 5 enable charging. The photoelectric conversion module 6 converts optical and electrical signals. When necessary, the power cord 3 can supply power to the photoelectric conversion module 6. The interface section 2 includes a housing 12. The connector 5 and the photoelectric conversion module 6 are placed inside the housing 12, with the insertion end of the connector 5 penetrating through the surface of the housing 12 and extending outwards. The end of the cable 1 extends through the surface of the housing 12 away from the connector 5 and into its interior. Simultaneously, a reinforcing frame 13 is provided inside the housing 12 to support it. The reinforcing frame 13 is tightly fitted to the surface of the inner cavity of the housing 12. The metal reinforcing frame 13 supports the hard plastic housing 12, improving the structural strength of the interface section 2.
[0036] The binding part 7 is disposed on the thread body 1. The thread body 1 can be wound into a roll and fixed by the binding part 7. The flat thread body 1 is easy to wind up and is easy to carry after being fixed by the binding part 7, avoiding the problems of easy tangling and knotting during carrying and inconvenience of use. The binding part 7 includes a winding part 16 and a flexible fixing strap 17. There are two winding parts 16, which are cylindrical and are disposed on both sides of the thread body 1. Each end of the winding part 16 is provided with a fixing pin 18. The surface of the flexible fixing strap 17 has fixing holes 19 arranged along the length direction. The fixing pins 18 can be inserted into and fixed in the fixing holes 19. The flat thread body 1 can be wound around the two winding parts 16. After winding, it is fixed by the flexible fixing strap 17. The installation is simple and the carrying is convenient.
[0037] Specifically, to solve the problem of easy damage to the wire at the connection point due to bending, a spring 14 with different widths at both ends is provided on the outer surface of the housing 12 away from the connector 5. The wider end of the spring 14 is attached to the outer surface of the housing 12, and the narrower end of the spring 14 extends outward and is attached to the surface of the wire 1. The outer side of the spring 14 is wrapped with a flexible outer sleeve 15. The addition of the spring 14 and the flexible outer sleeve 15 made of flexible material at the connection between the housing 12 and the wire 1 disperses the bending pressure.
[0038] Specifically, the connector 5 is one of the following interfaces: USB-A, USB-C, Lightning, Micro-USB, and Type-C.
[0039] The working principle of one embodiment of this utility model is as follows: The cable body 1 of this utility model adopts a flat cable body, avoiding the problem of easy knotting of traditional round cables. It can be easily wound and stored along the winding part 16 and fixed by the flexible fixing strap 17, improving portability. At the same time, the cable body 1 is composed of a mixture of optical fiber 4 and copper power line 3. The embedded optical fiber 4 improves the data transmission speed, while the copper power line 3 is retained for power supply. The power line 3 uses high-purity annealed copper and the wire diameter is reduced by a stretching process while maintaining conductivity. The optical fiber 4 uses bend-resistant optical fiber (such as G.657.A2 bend-insensitive optical fiber), reducing the minimum bending radius from 30mm to 5mm, avoiding signal loss due to winding or folding. The ultra-thin copper wire and flexible optical fiber reduce the weight of the cable. Multiple power lines can also be used in the design, which is compatible with PD 3.1 and QC. The device supports fast charging protocols such as 4+, enabling high-current and high-power fast charging. This invention not only solves the problems of traditional cables being bulky, easily damaged, and having poor compatibility, but also achieves breakthroughs in lightweight design, durability, and adaptability to various scenarios. The improved structure significantly enhances the portability, reliability, and user experience of the device.
Claims
1. A high performance data transmission electronic product data line, characterized in that, include: Line body (1), the line body (1) is flat and has a power line (3) and an optical fiber (4) inside; Interface section (2): Both ends of the line body (1) are provided with interface section (2). The interface section (2) is provided with a connector (5) and a photoelectric conversion module (6) that are electrically connected to each other. The photoelectric conversion module (6) is connected to the optical fiber (4), and both the connector (5) and the photoelectric conversion module (6) are electrically connected to the power line (3). A binding part (7) is provided on the thread (1), and the thread (1) can be wound into a roll and fixed by the binding part (7).
2. The high performance data transmission electronic product data line of claim 1, wherein, The line body (1) includes an outer sheath (8), the power line (3) and the optical fiber (4) are placed inside the outer sheath (8), the surface of the power line (3) is provided with an insulating layer (9), the surface of the optical fiber (4) is provided with a protective layer (10), and a filling layer (11) is provided between the interior of the outer sheath (8) and the gap between the insulating layer (9) and the protective layer (10).
3. The high-performance data transmission electronic product data cable according to claim 2, characterized in that, The power line (3) and the optical fiber (4) are arranged in a straight line in a row, and the positive and negative lines of the power line (3) are respectively set on both sides of the optical fiber (4).
4. The high-performance data transmission electronic product data cable according to claim 1, characterized in that, The interface part (2) includes a housing (12), the connector (5) and the photoelectric conversion module (6) are placed inside the housing (12), and the plug end of the connector (5) extends through the surface of the housing (12) and extends into it, and the end of the wire (1) extends through the surface of the housing (12) away from the connector (5) and into it.
5. A high-performance data transmission electronic product data cable according to claim 4, characterized in that, The inner cavity of the shell (12) is provided with a reinforcing frame (13) to support the shell (12), and the reinforcing frame (13) is closely fitted to the inner cavity surface of the shell (12).
6. A high-performance data transmission electronic product data cable according to claim 4, characterized in that, The outer surface of the housing (12) away from the connector (5) is provided with springs (14) with different widths at both ends. The wider end of the spring (14) is attached to the outer surface of the housing (12). The spring (14) is sleeved on the outside of the wire body (1) and the narrower end of the spring (14) extends outward and is attached to the surface of the wire body (1). The outside of the spring (14) is wrapped with a flexible outer sleeve (15).
7. A high-performance data transmission electronic product data cable according to claim 1, characterized in that, The binding part (7) includes a winding part (16) and a flexible fixing band (17). There are two winding parts (16) and they are cylindrical. The winding parts (16) are located on both sides of the line body (1). Both ends of the winding parts (16) are provided with fixing pins (18). The surface of the flexible fixing band (17) is provided with fixing holes (19) arranged along the length direction. The fixing pins (18) can be inserted and fixed in the fixing holes (19).
8. A high-performance data transmission electronic product data cable according to claim 1, characterized in that, The connector (5) is one of the following interfaces: USB-A, USB-C, Lightning, Micro-USB, or Type-C.