A combination structure of a Type-C connector and a data line

Abstract

The utility model relates to data line technical field discloses a kind of combination structure of Type-C connector and data line, including USB plug outer mould, plug inner membrane is inserted in USB plug outer mould inside, cable is inserted in plug inner membrane middle end, the sheath that the cable includes is inserted in plug inner membrane middle end, the sheath middle end is inserted with multiple groups of conductor and ground wire, the sheath inner cavity is filled with graphene, and the conductor and ground wire front end are equipped with connecting assembly.USB plug outer mould material is TPE-70A, TPE-70A can have better ultraviolet resistance, ozone resistance and chemical corrosion resistance, so that the service life of data line is longer in outdoor or harsh environment, TPE is easy to process, can be recycled, production efficiency is high, cost is lower, the hardness of 70A can provide good flexibility while maintaining certain strength, not easy to break or deformation.

Description

Technical Field

[0001] This utility model relates to the field of data cable technology, and in particular to a combination structure of a Type-C connector and a data cable. Background Technology

[0002] With the popularization of electronic devices, the Type-C connector, as a new type of data transmission interface, is being used more and more widely. The Type-C connector is an industry-standard connector used to transmit data and power over a single cable. It is characterized by its compact size, ease of use, and high transmission speed, and can connect to various electronic devices.

[0003] Existing Type-C connectors have poor protection, and they wear out significantly with prolonged use, which can lead to poor contact. In addition, the data cables have poor abrasion resistance and are prone to breakage after long-term use. Utility Model Content

[0004] Given that the existing Type-C connectors have poor protective performance and wear and tear during prolonged use, which can easily lead to poor contact, this utility model is proposed.

[0005] To solve the above technical problems, this utility model provides the following technical solution: a combined structure of a Type-C connector and a data cable, including a USB plug outer mold, a plug inner membrane inserted inside the USB plug outer mold, a cable inserted in the middle of the plug inner membrane, the cable including a sheath inserted in the middle of the plug inner membrane, multiple sets of conductors and ground wires inserted in the middle of the sheath, graphene filling the inner cavity of the sheath, a connecting component at the front end of the conductors and ground wires, the connecting component including a connector at the front end of the conductors and ground wires, a ground wire interface connected to the ground wire on the outer wall of the connector, a wire interface that mates with the conductors on the outer wall of the connector, a protective component covering the conductors and ground wires passing through the outer wall of the sheath, the protective component including a tinplate upper cover and a tinplate lower cover covering the upper and lower ends of the outer wall of the conductors and ground wires, tinplate corners and a cover plate respectively fixed at the same end of the tinplate lower cover and the tinplate upper cover, and copper foil inserted in the inner wall of the tinplate corners.

[0006] As a preferred embodiment of the combination structure of the Type-C connector and data cable of this utility model, the outer wall of the USB plug outer mold is provided with a USB plug body, and the end of the USB plug outer mold away from the connecting component is provided with a USB plug tail.

[0007] As a preferred embodiment of the combination structure of the Type-C connector and data cable of this utility model, the sheath material is flame-retardant silicone, the conductor is composed of tin-plated copper and insulating FEP material, and the graphene material is graphene.

[0008] As a preferred embodiment of the combination structure of the Type-C connector and data cable of this utility model, the lower tinplate cover has four protruding buckle positions at the upper corners, the lower tinplate cover has through hole buckle positions corresponding to the protruding buckle positions, the upper tinplate cover has a stop area, both sides of the outer wall of the lower and upper tinplate covers have clearance areas, and the lower tinplate cover has a baffle area at the end away from the corner of the tinplate.

[0009] As a preferred embodiment of the combination structure of the Type-C connector and data cable of this utility model, the bottom of the back of the connector is provided with PTC over-temperature protection.

[0010] As a preferred embodiment of the combination structure of the Type-C connector and data cable of this utility model, the USB plug outer mold is wrapped around the outer wall of the plug inner membrane, and the USB plug outer mold is made of TPE-70A.

[0011] Compared with the prior art, the present invention has at least the following beneficial effects:

[0012] 1. In this utility model, the outer mold material of the USB plug is TPE-70A. TPE-70A may have good resistance to ultraviolet rays, ozone and chemical corrosion, so the data cable has a longer service life in outdoor or harsh environments. TPE is easy to process, can be recycled, has high production efficiency and low cost. The hardness of 70A may provide good flexibility while maintaining a certain strength, making it not easy to break or deform.

[0013] 2. In this utility model, the conductor is composed of insulating FEP material and tin-plated copper, which reduces mutual interference between conductors while ensuring the transmission efficiency of the conductor. The sheath material is flame-retardant silicone, which effectively prevents leakage and short circuit, ensures the stability of signal transmission, reduces signal attenuation, and is suitable for high-frequency data transmission. Attached Figure Description

[0014] Figure 1 This is a three-dimensional structural diagram of the combined structure of the Type-C connector and data cable of this utility model;

[0015] Figure 2 This is an exploded three-dimensional structural diagram of the combined structure of the Type-C connector and data cable of this utility model;

[0016] Figure 3This is a schematic diagram of the front view of the cable structure for the combination of the Type-C connector and the data cable of this utility model;

[0017] Figure 4 This is a top view of the connection assembly of the Type-C connector and data cable of this utility model.

[0018] Figure 5 This is a bottom view of the connection component of the Type-C connector and data cable combination structure of this utility model;

[0019] Figure 6 This is an exploded perspective view of the protective component of the combined structure of the Type-C connector and data cable of this utility model.

[0020] Explanation of reference numerals in the attached figures:

[0021] 1. USB plug outer mold; 2. Plug inner mold; 3. Cable; 31. Conductor; 32. Ground wire; 33. Sheath; 34. Graphene; 4. Protective components; 41. Tinplate lower cover; 42. Convex buckle; 43. Tinplate corner; 44. Baffle area; 45. Clearance area; 46. Tinplate upper cover; 47. Cover plate; 48. Stop area; 49. Through hole buckle; 5. Copper foil; 6. Connecting components; 61. Connector; 62. Ground wire interface; 63. Wire interface; 64. PTC over-temperature protection; 7. USB plug body; 8. USB plug tail. Detailed Implementation

[0022] To make the above-mentioned objectives, features and advantages of this utility model more apparent and understandable, the specific embodiments of this utility model will be described in detail below with reference to the accompanying drawings.

[0023] Example 1

[0024] Reference Figure 1 and Figure 6This is the first embodiment of the present invention, providing a combined structure of a Type-C connector and a data cable, including a USB plug outer mold 1, a plug inner membrane 2 inserted inside the USB plug outer mold 1, a cable 3 inserted at the middle of the plug inner membrane 2, the cable 3 including a sheath 33 inserted at the middle of the plug inner membrane 2, multiple sets of conductors 31 and ground wires 32 inserted at the middle of the sheath 33, graphene 34 filling the inner cavity of the sheath 33, and a connecting component 6 provided at the front ends of the conductors 31 and ground wires 32. The connector 61 has a ground wire interface 62 on its outer wall that connects to the ground wire 32, and a wire interface 63 on its outer wall that mates with the conductor 31. The conductor 31 and the ground wire 32 pass through the outer wall of the sheath 33 and are fitted with a protective component 4. The protective component 4 includes a tinplate upper cover 46 and a tinplate lower cover 41 fitted on the upper and lower ends of the outer wall of the conductor 31 and the ground wire 32. Tinplate corner 43 and cover plate 47 are fixed at the same end of the tinplate lower cover 41 and the tinplate upper cover 46, respectively. Copper foil 5 is inserted into the inner wall of the tinplate corner 43.

[0025] The outer wall of the USB plug outer mold 1 is provided with the USB plug body 7. The end of the USB plug outer mold 1 away from the connecting component 6 is provided with the USB plug tail 8. The sheath 33 is made of flame-retardant silicone. The conductor 31 is composed of tin-plated copper and insulating FEP material. The graphene 34 is made of graphene. The upper corner of the tinplate lower cover 41 is provided with convex buckle positions 42. The lower end of the tinplate upper cover 46 is provided with through hole buckle positions 49 corresponding to the convex buckle positions 42. The upper end of the tinplate upper cover 46 is provided with a stop area 48. Both sides of the outer wall of the tinplate lower cover 41 and the tinplate upper cover 46 are provided with clearance areas 45. The end of the tinplate lower cover 41 away from the tinplate corner 43 is provided with a baffle area 44. The bottom of the back of the connector 61 is provided with PTC over-temperature protection 64. The USB plug outer mold 1 is wrapped around the outer wall of the plug inner membrane 2. The USB plug outer mold 1 is made of TPE-70A.

[0026] The USB plug outer mold 1 is made of TPE-70A. TPE-70A likely has good resistance to ultraviolet rays, ozone, and chemical corrosion, thus extending the lifespan of the data cable in outdoor or harsh environments. TPE is easy to process, recyclable, and has high production efficiency and low cost. The hardness of 70A provides good flexibility while maintaining a certain strength, making it less prone to breakage or deformation. In addition, TPE has good elasticity and can return to its original shape after bending, making it suitable for applications requiring frequent bending. Conductor 31 is composed of insulating FEP material and tin-plated copper, ensuring the transmission efficiency of conductor 31 while reducing mutual interference between conductors 31. The sheath 33 is made of flame-retardant silicone, which effectively prevents leakage and short circuits, ensuring signal transmission stability and reducing signal attenuation, making it suitable for high-frequency data transmission. The tinplate lower cover 41 and tinplate upper cover 46 support the interior of the connecting component 6, increasing the overall structural strength of the connecting component 6 and preventing deformation during long-term use, thus avoiding contact problems caused by deformation of the connecting component 6.

[0027] It should be noted that the above embodiments are only used to illustrate the technical solution of this utility model and are not intended to limit it. Although this utility model has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solution of this utility model without departing from the spirit and scope of the technical solution of this utility model, and all such modifications or substitutions should be covered within the scope of the claims of this utility model.

Claims

1. A combination structure of a Type-C connector and a data cable, comprising a USB plug outer mold (1), characterized in that: The USB plug outer mold (1) is fitted with a plug inner membrane (2), and a cable (3) is inserted into the middle of the plug inner membrane (2). The cable (3) includes a sheath (33) inserted into the middle of the plug inner membrane (2). Multiple sets of conductors (31) and ground wires (32) are inserted into the middle of the sheath (33). The inner cavity of the sheath (33) is filled with graphene (34). A connecting component (6) is provided at the front end of the conductors (31) and the ground wires (32). The connecting component (6) includes a connector (61) provided at the front end of the conductors (31) and the ground wires (32). The outer wall of the connector (61) is provided with a connection to the ground wires (31) and the ground wires (32). 32) The ground wire interface (62) is connected. The outer wall of the connector (61) is provided with a wire interface (63) that cooperates with the conductor (31). The conductor (31) and the ground wire (32) pass through the outer wall of the sheath (33) and are fitted with a protective component (4). The protective component (4) includes a tinplate upper cover (46) and a tinplate lower cover (41) fitted on the upper and lower ends of the outer wall of the conductor (31) and the ground wire (32). The tinplate lower cover (41) and the tinplate upper cover (46) are respectively fixed with a tinplate corner (43) and a cover plate (47) at the same end. The inner wall of the tinplate corner (43) is filled with copper foil (5).

2. The combination structure of the Type-C connector and data cable according to claim 1, characterized in that: The outer wall of the USB plug outer mold (1) is provided with a USB plug body (7), and the end of the USB plug outer mold (1) away from the connecting component (6) is provided with a USB plug tail (8).

3. The combination structure of the Type-C connector and data cable according to claim 1, characterized in that: The sheath (33) is made of flame-retardant silicone, the conductor (31) is composed of tin-plated copper and insulating FEP material, and the graphene (34) is made of graphene.

4. The combination structure of the Type-C connector and data cable according to claim 1, characterized in that: The tinplate lower cover (41) has protruding buckle positions (42) at the four corners of its upper end. The tinplate upper cover (46) has through hole buckle positions (49) corresponding to the protruding buckle positions (42) at its lower end. The tinplate upper cover (46) has a stop area (48) at its upper end. Both sides of the outer walls of the tinplate lower cover (41) and the tinplate upper cover (46) have clearance areas (45). The end of the tinplate lower cover (41) away from the tinplate corner (43) has a baffle area (44).

5. The combination structure of the Type-C connector and data cable according to claim 1, characterized in that: The connector (61) is equipped with a PTC over-temperature protection (64) at the bottom of its back side.

6. The combination structure of the Type-C connector and data cable according to claim 1, characterized in that: The USB plug outer mold (1) is wrapped around the outer wall of the plug inner film (2), and the USB plug outer mold (1) is made of TPE-70A.

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