CN113979239A - Data line - Google Patents

Abstract

The invention relates to the field of data transmission, in particular to a data line, which comprises a storage cavity, storage mechanisms, limiting mechanisms and a data line body, wherein two storage mechanisms are arranged in the storage cavity, four limiting mechanisms are arranged in the storage cavity and are respectively positioned at the upper side and the lower side of the two storage mechanisms, the data line body passes through the storage cavity and is wound on the two storage mechanisms, the storage cavity comprises a storage support, a connecting pipe and an elastic cavity, the storage mechanisms comprise storage support cylinders, storage rotating wheels, inclined protrusions and threading holes, and the limiting mechanisms comprise limiting supports and sliding cylinders, so that the data line body can be stored automatically.

Description

Data line

Technical Field

The invention relates to the field of data transmission, in particular to a data line.

Background

The data line charger is a device used for charging a mobile phone or other electronic equipment, brings convenience to power utilization, realizes power transmission and facilitates use of the electronic equipment; for example, in the prior art, a data line charger for preventing a data line from falling includes a charger main body, one end of the charger main body is provided with a charger plug, the middle of the other end of the charger main body is provided with a data line interface, the outer side of the data line interface is provided with a data line, one end of the data line is provided with a first data line plug, the other end of the data line is provided with a second data line plug corresponding to the data line interface, and the outer side of one end of the second data line plug is provided with a protective shell; the prior art has the defects that the data wire cannot be stored by itself and is easy to self-wind or wind with other wires.

Disclosure of Invention

The invention aims to provide a data line which can be stored automatically.

The purpose of the invention is realized by the following technical scheme:

a data line comprises a containing cavity, containing mechanisms, limiting mechanisms and a data line body, wherein two containing mechanisms are arranged in the containing cavity, four limiting mechanisms are arranged in the containing cavity and are respectively positioned at the upper side and the lower side of the two containing mechanisms, and the data line body penetrates through the containing cavity and is wound on the two containing mechanisms;

the storage cavity comprises two storage supports, two connecting pipes and two elastic cavities, the two storage supports are fixedly connected with the elastic cavities, the connecting pipes are fixedly connected between the two storage supports, two ends of each connecting pipe are respectively and fixedly connected to the two elastic cavities, and the two elastic cavities are communicated with the connecting pipes;

the storage mechanism comprises a storage support cylinder, a storage rotating wheel, an inclined bulge and a threading hole, the storage rotating wheel is rotatably connected to the storage support cylinder, a torsion spring is fixedly connected between the storage rotating wheel and the storage support cylinder, the inclined bulge is arranged at the upper end of the storage rotating wheel, the threading hole is formed in the inclined bulge, and the storage support cylinders are fixedly connected to the two storage supports;

the limiting mechanism comprises a limiting support and a plurality of sliding cylinders, the plurality of sliding cylinders are connected to the limiting support in a sliding mode, compression springs are fixedly connected between the sliding cylinders and the limiting support, the limiting support is fixedly connected to the upper end and the lower end of the inner side of each of the two containing supports, the data line body penetrates through the two elastic cavities and the connecting pipe, and the data line body is wound on the two containing rotating wheels;

a data line processing device comprises a supporting mechanism, clamping mechanisms, a cutting mechanism I and a cutting mechanism II, wherein the supporting mechanism is connected with the two clamping mechanisms;

the supporting mechanism comprises a supporting bracket, a transverse screw I, a transverse screw II, a transverse screw III and a transverse screw IV, the transverse screw I, the transverse screw II, the transverse screw III and the transverse screw IV are rotatably connected to the supporting bracket, the lengths of the transverse screw I and the transverse screw IV are longer than those of the transverse screw II and the transverse screw III, power mechanisms for driving the transverse screw I, the transverse screw II, the transverse screw III and the transverse screw IV to rotate are arranged on the transverse screw I, the transverse screw II, the transverse screw III and the transverse screw IV, and the power mechanisms are preferably servo motors;

the clamping mechanism comprises a telescopic mechanism I, a telescopic mechanism II, a clamping motor, a clamping disc, a threaded disc and clamping side plates, wherein the telescopic end of the telescopic mechanism I is fixedly connected with the telescopic mechanism II, the telescopic end of the telescopic mechanism II is fixedly connected with the clamping motor, the output shaft of the clamping motor is fixedly connected with the clamping disc, the clamping disc is rotatably connected with the threaded disc, the threaded disc is provided with a power mechanism I for driving the threaded disc to rotate, the power mechanism I is preferably a servo motor, the threaded disc is connected with the four clamping side plates through threads, the four clamping side plates are all slidably connected onto the clamping disc, and the transverse screw I and the transverse screw IV are both connected with the telescopic mechanism I through threads;

the cutting mechanism I comprises a telescopic mechanism III, a telescopic mechanism IV and a cutting tool I, the telescopic end of the telescopic mechanism III is fixedly connected with the telescopic mechanism IV, the telescopic end of the telescopic mechanism IV is fixedly connected with the cutting tool I, and the telescopic mechanism III is connected to the transverse screw II through threads;

the cutting mechanism II comprises a telescopic mechanism V, a telescopic mechanism VI, a cutting support and a cutting tool II, the telescopic mechanism V is connected to the transverse screw III through threads, the telescopic end of the telescopic mechanism V is fixedly connected with the telescopic mechanism VI, the telescopic end of the telescopic mechanism VI is connected with the cutting support in a rotating mode, the cutting support is provided with a power mechanism II for driving the cutting support to rotate, the power mechanism II is preferably a servo motor, the cutting support is connected with the cutting tool II in a rotating mode, the cutting tool II is provided with a power mechanism III for driving the cutting tool to rotate, and the power mechanism III is preferably a servo motor.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a first schematic diagram of a data line structure according to the present invention;

FIG. 2 is a cross-sectional view of a data line configuration of the present invention;

FIG. 3 is a second schematic diagram of the data line structure of the present invention;

FIG. 4 is a third schematic diagram of the data line structure of the present invention;

FIG. 5 is a schematic view of the receiving mechanism of the present invention;

FIG. 6 is a schematic cross-sectional view of the receiving mechanism of the present invention;

FIG. 7 is a schematic view of the structure of the receiving chamber of the present invention;

FIG. 8 is a schematic structural view of a spacing mechanism of the present invention;

FIG. 9 is a schematic view of the data line processing apparatus of the present invention;

FIG. 10 is a schematic structural view of the support mechanism of the present invention;

FIG. 11 is a schematic structural view of a clamping mechanism of the present invention;

FIG. 12 is a schematic view of the cutting mechanism I of the present invention;

FIG. 13 is a schematic structural view of a cutting mechanism II of the present invention;

FIG. 14 is a schematic view of a receiving wheel manufacturing process according to the present invention.

In the figure:

a receiving cavity 10; a storage holder 11; a connecting tube 12; an elastic cavity 13;

a storage mechanism 20; a storage branch tube 21; a take-in reel 22; the inclined protrusion 23; a threading hole 24;

a limiting mechanism 30; a limit bracket 31; a slide cylinder 32;

a data wire body 40;

a support mechanism 50; a support bracket 51; a transverse screw I52; a transverse screw II 53; a transverse screw III 54; a screw IV 55 is transversely moved;

a clamping mechanism 60; a telescoping mechanism I61; a telescoping mechanism II 62; a clamping motor 63; a chucking plate 64; a threaded disk 65; clamping the side plates 66;

a cutting mechanism I70; a telescoping mechanism III 71; a telescoping mechanism IV 72; a cutting tool I73;

a cutting mechanism II 80; a telescoping mechanism V81; a telescoping mechanism VI 82; the cutting support 83; and a cutting tool II 84.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

In order to solve the technical problem of realizing automatic storage, the structure and function of a data line are explained in detail below;

a data line comprises a containing cavity 10, containing mechanisms 20, limiting mechanisms 30 and a data line body 40, wherein two containing mechanisms 20 are arranged in the containing cavity 10, four limiting mechanisms 30 are arranged in the containing cavity 10, the four limiting mechanisms 30 are respectively positioned at the upper side and the lower side of the two containing mechanisms 20, and the data line body 40 penetrates through the containing cavity 10 and is wound on the two containing mechanisms 20;

as shown in fig. 1 to 8, the data line body 40 is wound around the two receiving mechanisms 20, after the use of the data line body 40 is completed, the two receiving mechanisms 20 receive the data line body 40 under the action of the torsion spring, so that the data line body 40 is wound around the two receiving mechanisms 20, the two receiving mechanisms 20 can receive the data line body 40 into the receiving cavity 10, the four limiting mechanisms 30 limit the data line body 40 at the upper and lower sides of the two receiving mechanisms 20, and it is ensured that the data line body 40 does not separate from the two receiving mechanisms 20;

further, the following describes the structure and function of the receiving cavity 10, the receiving mechanism 20, the limiting mechanism 30 and the data wire 40 in detail;

the storage cavity 10 comprises two storage brackets 11, a connecting pipe 12 and two elastic cavities 13, the two storage brackets 11 are fixedly connected with the elastic cavities 13, the connecting pipe 12 is fixedly connected between the two storage brackets 11, two ends of the connecting pipe 12 are respectively fixedly connected to the two elastic cavities 13, and the two elastic cavities 13 are communicated with the connecting pipe 12;

the storage mechanism 20 comprises a storage support tube 21, a storage rotating wheel 22, an inclined bulge 23 and a threading hole 24, the storage rotating wheel 22 is rotatably connected to the storage support tube 21, a torsion spring is fixedly connected between the storage rotating wheel 22 and the storage support tube 21, the inclined bulge 23 is arranged at the upper end of the storage rotating wheel 22, the threading hole 24 is arranged on the inclined bulge 23, and the storage support tubes 21 are fixedly connected to the two storage supports 11;

the limiting mechanism 30 comprises a limiting support 31 and a sliding barrel 32, the limiting support 31 is connected with a plurality of sliding barrels 32 in a sliding mode, a compression spring is fixedly connected between the sliding barrel 32 and the limiting support 31, the upper end and the lower end of the inner side of each of the two containing supports 11 are fixedly connected with the limiting support 31, the data line body 40 penetrates through the two elastic cavities 13 and the connecting pipe 12, and the data line body 40 is wound on the two containing rotating wheels 22;

as shown in fig. 3, 4 and 7, the winding manner of the data line 40 is explained in detail, the data line 40 passes through the two elastic cavities 13 and the connecting pipe 12, the portion of the data line 40 located in the elastic cavity 13 is wound on the receiving wheel 22, the data line 40 passes through the threading hole 24 arranged on the inclined protrusion 23, and the portion of the data line 40 passing through the threading hole 24 is fixedly connected in the threading hole 24, so that the receiving wheel 22 can drive the data line 40 to move when rotating, and further wind the data line 40, and meanwhile, because the data line 40 passes through the threading hole 24 arranged on the inclined protrusion 23, the receiving wheel 22 cannot wind the upper portion of the inclined protrusion 23 when rotating, and it is ensured that the portion between the two receiving mechanisms 20 is not pulled;

furthermore, the inclined protrusion 23 is arranged obliquely, so that the data line body 40 is prevented from being wound on the inclined protrusion 23 when the storage rotating wheel 22 drives the data line body 40 to rotate, and further, the part between the two storage mechanisms 20 is prevented from being pulled;

as shown in fig. 1 to 8, the following detailed description of the use mode of the data line describes that, when in use, the data line body 40 is pulled, the data line body 40 pulls the storage wheel 22 to rotate, the storage wheel 22 extrudes the torsion spring when rotating, so that the torsion spring deforms, the data line body 40 is pulled out from the elastic cavity 13, and thus the use is facilitated, the pulled-out length of the data line body 40 is adjusted according to different use requirements, and different use requirements are met;

furthermore, two elastic cavities 13 are provided, and two corresponding accommodating mechanisms 20 are provided, so that two ends of the data line body 40 can be pulled out by different lengths according to different use requirements;

after the use is finished, two ends of the data line body 40 are loosened, the accommodating rotating wheel 22 rotates under the action of the torsion spring, and the accommodating rotating wheel 22 drives the data line body 40 to move, so that the data line body 40 is accommodated on the accommodating rotating wheel 22 to finish self-accommodation;

further, in order to ensure that the data line body 40 can be stably wound on the accommodating mechanism 20, the upper side and the lower side of the accommodating mechanism 20 are both provided with a limiting mechanism 30 for limiting the data line body 40, as shown in fig. 2, the data line body 40 is located between the two limiting mechanisms 30, and the plurality of sliding cylinders 32 on the two limiting mechanisms 30 limit the data line body 40, so that the data line body 40 is located between the two limiting mechanisms 30 no matter when extending out or accommodating, and the data line body 40 can be stably wound on the accommodating rotating wheel 22;

furthermore, in order to ensure that the data line is convenient to carry, the elastic cavity 13 is made of an elastic material, the elastic cavity 13 is preferably made of a rubber material, the elastic cavity 13 is deformed to a certain extent when being subjected to an external force, and the occupied space is reduced, meanwhile, a compression spring is fixedly connected between the limiting support 31 and the sliding cylinder 32, so that the sliding cylinder 32 can slide on the limiting support 31, further, the sliding cylinder 32 can slide on the limiting support 31 when the elastic cavity 13 is deformed, so that the occupied space is further reduced, meanwhile, the limiting support 31 still limits the sliding cylinder 32, so that the sliding cylinder 32 can only slide transversely, and the data line body 40 can still be stably wound on the storage rotating wheel 22 when the elastic cavity 13 is deformed;

furthermore, the storage rotor 22 is an important component of the present invention, and the storage rotor 22 has many small structures, so that a data line processing device is designed for facilitating the processing of the storage rotor 22, and the structure and function of the data line processing device will be described in detail below;

a data line processing device comprises a supporting mechanism 50, clamping mechanisms 60, a cutting mechanism I70 and a cutting mechanism II 80, wherein the two clamping mechanisms 60 are connected to the supporting mechanism 50, and the cutting mechanism I70 and the cutting mechanism II 80 are connected to the supporting mechanism 50;

as shown in fig. 9 to 14, one of the clamping mechanisms 60 clamps one end of a pipe to be machined, the cutting mechanism i 70 performs a first cutting process on the pipe, in the machining process, the clamping mechanism 60 in the clamping state and the cutting mechanism i 70 move together, a step is formed on the pipe after the machining is completed, the other clamping mechanism 60 clamps the other end of the pipe, the cutting mechanism ii 80 performs a second cutting process on the pipe, in the machining process, the clamping mechanism 60 and the cutting mechanism ii 80 move together, an inclined protrusion 23 is formed on the pipe after the machining is completed, the clamping mechanism 60 in the clamping state is released and clamped, the accommodating rotating wheel 22 is machined, the pipe is cut to a designated position, and the device moves repeatedly, so that the machining is completed efficiently;

the structure and function of the supporting mechanism 50, the clamping mechanism 60, the cutting mechanism I70 and the cutting mechanism II 80 are explained in detail below;

the supporting mechanism 50 comprises a supporting bracket 51, a transverse screw I52, a transverse screw II 53, a transverse screw III 54 and a transverse screw IV 55, the transverse screw I52, the transverse screw II 53, the transverse screw III 54 and the transverse screw IV 55 are all rotatably connected to the supporting bracket 51, the lengths of the transverse screw I52 and the transverse screw IV 55 are longer than those of the transverse screw II 53 and the transverse screw III 54, power mechanisms for driving the transverse screws I52, the transverse screw II 53, the transverse screw III 54 and the transverse screw IV 55 to rotate are arranged on the transverse screw I52, the transverse screw II 53, the transverse screw III 54 and the transverse screw IV 55, and the power mechanisms are preferably servo motors;

the clamping mechanism 60 comprises a telescopic mechanism I61, a telescopic mechanism II 62, a clamping motor 63, a clamping disc 64, a threaded disc 65 and clamping side plates 66, the telescopic end of the telescopic mechanism I61 is fixedly connected with the telescopic mechanism II 62, the telescopic end of the telescopic mechanism II 62 is fixedly connected with the clamping motor 63, the output shaft of the clamping motor 63 is fixedly connected with the clamping disc 64, the clamping disc 64 is rotatably connected with the threaded disc 65, the threaded disc 65 is provided with a power mechanism I for driving the threaded disc to rotate, the power mechanism I is preferably a servo motor, the threaded disc 65 is connected with the four clamping side plates 66 through threads, the four clamping side plates 66 are all slidably connected to the clamping disc 64, and the transverse screw I52 and the transverse screw IV 55 are both connected with the telescopic mechanism I61 through threads;

the cutting mechanism I70 comprises a telescopic mechanism III 71, a telescopic mechanism IV 72 and a cutting tool I73, the telescopic end of the telescopic mechanism III 71 is fixedly connected with the telescopic mechanism IV 72, the telescopic end of the telescopic mechanism IV 72 is fixedly connected with the cutting tool I73, and the telescopic mechanism III 71 is connected to the transverse screw II 53 through threads;

the cutting mechanism II 80 comprises a telescopic mechanism V81, a telescopic mechanism VI 82, a cutting support 83 and a cutting tool II 84, the telescopic mechanism V81 is connected to the transverse screw III 54 through threads, the telescopic end of the telescopic mechanism V81 is fixedly connected with the telescopic mechanism VI 82, the telescopic end of the telescopic mechanism VI 82 is rotatably connected with the cutting support 83, a power mechanism II for driving the cutting support 83 to rotate is arranged on the cutting support 83, the power mechanism II is preferably a servo motor, the cutting support 83 is rotatably connected with the cutting tool II 84, the cutting tool II 84 is provided with a power mechanism III for driving the cutting tool II to rotate, and the power mechanism III is preferably a servo motor;

as shown in fig. 9 to 14, a pipe to be processed is placed on a clamping mechanism 60 located on the front side, a corresponding power mechanism i is started, the power mechanism i drives a threaded disc 65 to rotate, the threaded disc 65 drives four clamping side plates 66 to move through threads when rotating, the four clamping side plates 66 extrude and clamp the pipe, a clamping motor 63 is started, an output shaft of the clamping motor 63 drives a clamping disc 64, the threaded disc 65 and the clamping side plates 66 to rotate, the pipe rotates, a telescopic mechanism iv 72 is started, a telescopic mechanism i 61, a telescopic mechanism ii 62, a telescopic mechanism iii 71, a telescopic mechanism iv 72, a telescopic mechanism v 81 and a telescopic mechanism vi 82 can be hydraulic cylinders or electric push rods, a telescopic end of the telescopic mechanism iv 72 drives a cutting tool i 73 to move, and the cutting tool i 73 moves transversely to cut the pipe to form a step;

furthermore, the power mechanisms on the transverse moving screw I52 and the transverse moving screw II 53 are started, the rotating speeds of the transverse moving screw I52 and the transverse moving screw II 53 are the same, then the clamping mechanism 60 in the clamping state and the cutting mechanism I70 move together, after the clamping mechanism 60 and the cutting mechanism I70 move to the rear side, the clamping mechanism 60 continues to move, after the clamping mechanism 60 on the traverse screw I52 moves to the position corresponding to the weight of the traverse screw IV 55, a power mechanism on the transverse screw IV 55 is started, the transverse screw IV 55 rotates to drive the clamping mechanisms 60 to move, the two clamping mechanisms 60 move simultaneously, the moving speeds of the two clamping mechanisms 60 are the same, the telescopic mechanism II 62 and the power mechanism I are started, the two clamping mechanisms 60 clamp the pipe simultaneously, the clamping mechanism 60 on the transverse screw I52 releases clamping, and the clamping mechanism 60 on the transverse screw IV 55 clamps the other end of the pipe;

starting a power mechanism on the traverse screw III 54, driving a cutting mechanism II 80 to move through threads by the traverse screw III 54, enabling the cutting mechanism II 80 to have the same speed as the clamping mechanism 60 in a clamping state, starting the power mechanism III and the clamping motor 63 in advance, driving a cutting tool II 84 to rotate by an output shaft of the power mechanism III, and cutting the end part of the accommodating rotating wheel 22 by the cutting tool II 84 to form the inclined bulge 23;

further, start power unit II, power unit II can drive cutting support 83 and rotate, and then adjusts the inclination of cutting support 83, and then adjusts the inclination of cutting tool II 84, and then satisfies different cutting demands.

Claims (10)

1. A data line, including accomodating cavity (10) and data line body (40), its characterized in that: two accommodating mechanisms (20) used for winding the data line body (40) are arranged in the accommodating cavity (10).

2. A data line as claimed in claim 1, wherein: accomodate cavity (10) including two accomodate support (11) and fixed connection connecting pipe (12) between two accomodate support (11), two accomodate equal fixedly connected with elasticity cavity (13) on support (11), two elasticity cavities (13) all communicate with connecting pipe (12).

3. A data line as claimed in claim 2, wherein: the storage mechanism (20) comprises a storage branch cylinder (21) and a storage rotating wheel (22) rotatably connected to the storage branch cylinder (21), a torsion spring is fixedly connected between the storage rotating wheel (22) and the storage branch cylinder (21), and the storage branch cylinders (21) are fixedly connected to the two storage supports (11).

4. A data line as claimed in claim 3, wherein: the storage rotating wheel (22) is provided with an inclined bulge (23), and the inclined bulge (23) is provided with a threading hole (24).

5. A data line as claimed in claim 2, wherein: the storage rack is characterized by further comprising a limiting mechanism (30), wherein the limiting mechanism (30) comprises a limiting support (31) and a plurality of sliding cylinders (32) which are connected to the limiting support (31) in a sliding mode, compression springs are fixedly connected between the sliding cylinders (32) and the limiting support (31), and the upper end and the lower end of the inner side of each of the two storage supports (11) are fixedly connected with the limiting support (31).

6. A data line as claimed in claim 1, wherein: the data line also uses a data processing device, which comprises a supporting mechanism (50), a clamping mechanism (60) connected to the supporting mechanism (50), a cutting mechanism I (70) connected to the supporting mechanism (50) and a cutting mechanism II (80).

7. A data line according to claim 6, wherein: the supporting mechanism (50) comprises a supporting bracket (51), and a transverse screw I (52), a transverse screw II (53), a transverse screw III (54) and a transverse screw IV (55) which are rotatably connected to the supporting bracket (51).

8. A data line according to claim 6, wherein: clamping machine constructs (60) and includes telescopic machanism I (61) and fixed connection telescopic machanism II (62) on the flexible end, fixedly connected with clamping motor (63) are served in the flexible of telescopic machanism II (62), fixedly connected with clamping dish (64) on the output shaft of clamping motor (63), rotate on clamping dish (64) and be connected with thread disc (65), there are four clamping curb plates (66) through threaded connection on thread disc (65), four equal sliding connection of clamping curb plate (66) are on clamping dish (64).

9. A data line according to claim 6, wherein: the cutting mechanism I (70) comprises a telescopic mechanism III (71) and a telescopic mechanism IV (72) fixedly connected to the telescopic end of the telescopic mechanism III (71), and a cutting tool I (73) is fixedly connected to the telescopic end of the telescopic mechanism IV (72).

10. A data line according to claim 6, wherein: the cutting mechanism II (80) comprises a telescopic mechanism V (81) and a telescopic mechanism VI (82) fixedly connected to the telescopic end of the telescopic mechanism V (81), the telescopic end of the telescopic mechanism VI (82) is rotatably connected with a cutting support (83), and the cutting support (83) is rotatably connected with a cutting tool II (84).

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