CN111405692B - Graphene heating wire processing system and method - Google Patents

Abstract

The invention relates to a graphene heating wire, in particular to a system and a method for processing the graphene heating wire, which comprises a device bracket, a graphite mechanism, a moving mechanism, an adhesion mechanism I, an adhesion mechanism II, a wire forming mechanism I and a wire forming mechanism II, wherein a graphite barrel can be clamped between two conical rotating wheels I, and the adhesion mechanism I is used for preliminarily adhering graphite on the graphite barrel; the moving mechanism drives the adhesion mechanism I to move, and the adhesion mechanism I and the adhesion mechanism II are contacted for multiple times to further adhere graphite on the adhesion mechanism I; the moving mechanism drives the adhesion mechanism I to move, and the filamentation mechanism I is contacted with the adhesion mechanism I, so that graphene is formed on the filamentation mechanism I; the filamentation mechanism II contacts with the filamentation mechanism I, differential motion is carried out between the filamentation mechanism II and the filamentation mechanism I, the filamentation mechanism II and the filamentation mechanism I generate relative motion, and graphene is coiled into graphene wires.

Description

Graphene heating wire processing system and method

Technical Field

The invention relates to a graphene heating wire, in particular to a system and a method for processing the graphene heating wire.

Background

For example, publication No. CN110034356A discloses a graphene heating layer storage battery heating heat-insulating sheath and a preparation method thereof, and relates to a graphene heating layer storage battery heating heat-insulating sheath and a preparation method thereof, which are used in military storage batteries and energy storage fields of electric vehicles, solar power generation, wind power generation, power valley energy storage, uninterrupted power supplies and the like. The graphene storage battery heating and heat-insulating sheath is formed by mutually connecting an upper cover surface layer, a right side surface layer, a front side surface layer, a left side surface layer, a rear side surface layer and a bottom surface layer to form a hexahedron, and the storage battery is wrapped in the hexahedron of the graphene heating layer storage battery heating and heat-insulating sheath; the invention has the defect that the graphene heating wire cannot be efficiently prepared.

Disclosure of Invention

The invention aims to provide a graphene heating wire processing system and method, which can be used for efficiently preparing a graphene heating wire.

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

the utility model provides a graphite alkene heater system of processing and method, includes device support, graphite mechanism, moving mechanism, adhesion mechanism I, adhesion mechanism II, filamentation mechanism I and filamentation mechanism II, the front end of device support is connected with graphite mechanism, and the upper end fixedly connected with moving mechanism of device support is connected with adhesion mechanism I on the moving mechanism, and the middle part of device support is connected with adhesion mechanism II, and the downside fixedly connected with filamentation mechanism I of device support rear end, the middle part fixedly connected with filamentation mechanism II of device support rear end.

According to the further optimization of the technical scheme, the graphene heating wire processing system comprises a device frame, a mounting support I and a sliding rail, wherein the mounting support I is fixedly connected to the middle of the device frame, and the sliding rail is fixedly connected to the front end of the device frame. As a further optimization of the technical scheme, the graphene heating wire processing system provided by the invention comprises

According to the further optimization of the technical scheme, the graphene heating wire processing system comprises a graphite mechanism, wherein the graphite mechanism comprises a bidirectional threaded rod I, a sliding cylinder I, sliding columns I, conical rotating wheels I and a graphite cylinder, the bidirectional threaded rod I is rotatably connected to a device frame, two ends of the bidirectional threaded rod I are respectively connected with the sliding cylinder I through threads, the thread turning directions of two ends of the bidirectional threaded rod I are opposite, the sliding columns I are respectively and slidably connected into the two sliding cylinders I, compression springs I are fixedly connected between the sliding columns I and the sliding cylinders I, the conical rotating wheels I are rotatably connected between the two sliding columns I, the graphite cylinder is clamped between the two conical rotating wheels I, and the two sliding cylinders I are respectively and slidably connected to a sliding track.

According to the further optimization of the technical scheme, the graphene heating wire processing system comprises a moving mechanism, a moving motor, a telescopic mechanism I and a mounting support II, wherein the moving mechanism is fixedly connected to the upper end of a device frame, the moving motor is fixedly connected to the moving frame, an output shaft of the moving motor is connected with the telescopic mechanism I through threads, the telescopic mechanism I is connected to the moving frame in a sliding mode, and the telescopic end of the telescopic mechanism I is fixedly connected with the mounting support II.

As a further optimization of the technical scheme, the graphene heating wire processing system comprises an adhesion mechanism I, two bidirectional threaded rods II, two sliding cylinders II, two sliding columns II, two conical rotating wheels II, a rubber belt cylinder I, a rubber belt cylinder II, a storage motor I, a telescopic mechanism II and a supporting bottom plate I, wherein the two bidirectional threaded rods II are rotatably connected to a mounting bracket II, the thread turning directions of two ends of each bidirectional threaded rod II are opposite, two ends of each two bidirectional threaded rod II are respectively connected with the corresponding sliding cylinder II through threads, the sliding column II is slidably connected in each sliding cylinder II, a compression spring II is fixedly connected between each sliding column II and each sliding cylinder II, each sliding column II is rotatably connected with a conical rotating wheel II, the rubber belt cylinder I and the rubber belt cylinder II are respectively clamped between the corresponding two conical rotating wheels II, and the rubber belt cylinder I and the rubber belt cylinder II are connected through the rubber belt I, accomodate output shaft fixed connection of motor I and take turns II on one of them toper, fixedly connected with supporting baseplate I is served in the flexible of telescopic machanism II, and II fixed connections of telescopic machanism are on installing support II, and I tops of supporting baseplate are on sticky tape I.

As a further optimization of the technical scheme, the graphene heating wire processing system comprises an adhesion mechanism II, two bidirectional threaded rods III, two sliding cylinders III, two sliding columns III, two conical rotating wheels III, a rubber belt cylinder IV, a storage motor II, a telescopic mechanism III and a supporting base plate II, wherein the two bidirectional threaded rods III are respectively connected to a mounting bracket I in a rotating mode, the rotating directions of threads at two ends of each bidirectional threaded rod III are opposite, two ends of each bidirectional threaded rod III are respectively connected with the corresponding sliding cylinder III through threads, the sliding column III is respectively connected to each sliding cylinder III in a sliding mode, a compression spring II is fixedly connected between each sliding column III and each sliding cylinder III, each sliding column III is respectively connected to each conical rotating wheel III in a rotating mode, the rubber belt cylinder III and the rubber belt cylinder IV are respectively clamped between the two corresponding conical rotating wheels, and the rubber belt cylinder III and the rubber belt cylinder IV are connected through the rubber belt II, accomodate output shaft fixed connection of motor II and rotate on wheel III at one of them toper, fixedly connected with supporting baseplate II is served in telescopic machanism III's flexible, and telescopic machanism III fixed connection is on installing support I, and II tops of supporting baseplate are on sticky tape II.

According to the further optimization of the technical scheme, the graphene heating wire processing system comprises a wire forming frame I, a wire forming motor I, a telescopic mechanism IV, a clamping frame I, a clamping plate I, a clamping threaded rod I and a base I, wherein the wire forming frame I is fixedly connected to a device frame, the wire forming frame I is fixedly connected with the wire forming motor I, an output shaft of the wire forming motor I is connected with the telescopic mechanism IV through threads, a telescopic end of the telescopic mechanism IV is fixedly connected with the clamping frame I, the clamping frame I is internally slidably connected with two clamping plates I, the two clamping threaded rods I are rotatably connected to the two clamping plates I, the two clamping threaded rods I are connected to the clamping frame I through threads, and the base I is clamped between the two clamping plates I.

According to the further optimization of the technical scheme, the graphene heating wire processing system comprises a wire forming frame II, a wire forming motor II, a telescopic mechanism V, a clamping frame II, a clamping plate II, a clamping threaded rod II and a substrate II, wherein the wire forming frame II is fixedly connected to a device frame, the wire forming frame II is fixedly connected with the wire forming motor II, an output shaft of the wire forming motor II is connected with the telescopic mechanism V through a thread, a telescopic end of the telescopic mechanism V is fixedly connected with the clamping frame II, the clamping frame II is connected with the two clamping plates II in a sliding mode, the two clamping threaded rods II are rotatably connected to the two clamping plates II, the two clamping threaded rods II are connected to the clamping frame II through threads, and the substrate II is clamped between the two clamping plates II.

A graphene heating wire processing method comprises the following steps:

the method comprises the following steps: the graphite barrel is clamped between the two conical rotating wheels I, and the adhesion mechanism I is used for preliminarily adhering graphite on the graphite barrel;

step two: the moving mechanism drives the adhesion mechanism I to move, and the adhesion mechanism I and the adhesion mechanism II are contacted for multiple times to further adhere graphite on the adhesion mechanism I;

step three: the moving mechanism drives the adhesion mechanism I to move, and the filamentation mechanism I is contacted with the adhesion mechanism I, so that graphene is formed on the filamentation mechanism I;

step four: the filamentation mechanism II contacts with the filamentation mechanism I, differential motion is carried out between the filamentation mechanism II and the filamentation mechanism I, the filamentation mechanism II and the filamentation mechanism I generate relative motion, and graphene is coiled into graphene wires.

The graphene heating wire processing system and method have the beneficial effects that:

according to the graphene heating wire processing system and method, a graphite barrel can be clamped between two conical rotating wheels I, and an adhesion mechanism I is used for preliminarily adhering graphite on the graphite barrel; the moving mechanism drives the adhesion mechanism I to move, and the adhesion mechanism I and the adhesion mechanism II are contacted for multiple times to further adhere graphite on the adhesion mechanism I; the moving mechanism drives the adhesion mechanism I to move, and the filamentation mechanism I is contacted with the adhesion mechanism I, so that graphene is formed on the filamentation mechanism I; the filamentation mechanism II contacts with the filamentation mechanism I, differential motion is carried out between the filamentation mechanism II and the filamentation mechanism I, the filamentation mechanism II and the filamentation mechanism I generate relative motion, and graphene is coiled into graphene wires.

Drawings

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

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "top", "bottom", "inner", "outer" and "upright", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, directly or indirectly connected through an intermediate medium, and may be a communication between two members. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, in the description of the present invention, the meaning of "a plurality", and "a plurality" is two or more unless otherwise specified.

Fig. 1 is a schematic view of the overall structure of a graphene heating wire processing system according to the present invention;

FIG. 2 is a schematic diagram of the overall structure of the graphene heating wire processing system according to the invention;

FIG. 3 is a schematic view of the device support structure of the present invention;

FIG. 4 is a schematic structural view of the graphite mechanism of the present invention;

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

FIG. 6 is a schematic view of the structure of the adhering means I of the present invention;

FIG. 7 is a schematic structural view of the adhesion mechanism II of the present invention;

FIG. 8 is a schematic structural view of a filamentation mechanism I of the invention;

FIG. 9 is a schematic structural diagram of a filamentation mechanism II of the invention.

In the figure: a device holder 1; a device frame 101; a mounting bracket I102; a slide rail 103; a graphite mechanism 2; a bidirectional threaded rod I201; a sliding cylinder I202; a sliding column I203; a conical rotating wheel I204; a graphite cylinder 205; a moving mechanism 3; a moving frame 301; a moving motor 302; a telescoping mechanism I303; a mounting bracket II 304; an adhesion mechanism I4; a bidirectional threaded rod II 401; a sliding cylinder II 402; a sliding column II 403; a conical rotating wheel II 404; a tape cartridge I405; a tape cartridge II 406; a storage motor I407; a telescoping mechanism II 408; a support base plate I409; an adhesion mechanism II 5; a bidirectional threaded rod III 501; a sliding cylinder III 502; a sliding column III 503; a conical rotating wheel III 504; a tape cartridge III 505; a tape cartridge IV 506; a storage motor II 507; a telescoping mechanism III 508; a support base plate II 509; a filamentation mechanism I6; a filament forming frame I601; a filamentation motor I602; a telescoping mechanism IV 603; a clamping frame I604; a clamping plate I605; clamping a threaded rod I606; a substrate I607; a filamentation mechanism II 7; a filament forming frame II 701; a filamentation motor II 702; a telescoping mechanism V703; a clamping frame II 704; a clamping plate II 705; clamping a threaded rod II 706; substrate II 707.

Detailed Description

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

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 9, and a graphene heating wire processing system includes a device support 1, a graphite mechanism 2, a moving mechanism 3, an adhesion mechanism i 4, an adhesion mechanism ii 5, a wire forming mechanism i 6, and a wire forming mechanism ii 7, wherein the front end of the device support 1 is connected with the graphite mechanism 2, the upper end of the device support 1 is fixedly connected with the moving mechanism 3, the adhesion mechanism i 4 is connected to the moving mechanism 3, the middle part of the device support 1 is connected with the adhesion mechanism ii 5, the lower side of the rear end of the device support 1 is fixedly connected with the wire forming mechanism i 6, and the middle part of the rear end of the device support 1 is fixedly connected with the wire forming mechanism ii 7; clamping a graphite cylinder 205 between two conical rotating wheels I204, and carrying out primary adhesion on graphite on the graphite cylinder 205 by an adhesion mechanism I4; the moving mechanism 3 drives the adhesion mechanism I4 to move, and the adhesion mechanism I4 and the adhesion mechanism II 5 are contacted for multiple times to further adhere graphite on the adhesion mechanism I4; the moving mechanism 3 drives the adhesion mechanism I4 to move, and the wire forming mechanism I6 is contacted with the adhesion mechanism I4, so that graphene is formed on the wire forming mechanism I6; the filamentation mechanism II 7 contacts with the filamentation mechanism I6, the filamentation mechanism II 7 and the filamentation mechanism I6 do differential motion, the filamentation mechanism II 7 and the filamentation mechanism I6 generate relative motion, and graphene is coiled into graphene wires.

The second embodiment is as follows:

the present embodiment is described below with reference to fig. 1 to 9, and the present embodiment further describes the first embodiment, where the apparatus frame 1 includes an apparatus frame 101, a mounting bracket i 102, and a sliding rail 103, the mounting bracket i 102 is fixedly connected to the middle of the apparatus frame 101, and the sliding rail 103 is fixedly connected to the front end of the apparatus frame 101.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 9, and the embodiment further describes an embodiment two, where the graphite mechanism 2 includes a bidirectional threaded rod i 201, a sliding cylinder i 202, a sliding column i 203, a conical rotating wheel i 204, and a graphite cylinder 205, the bidirectional threaded rod i 201 is rotatably connected to the device frame 101, both ends of the bidirectional threaded rod i 201 are respectively connected to the sliding cylinder i 202 through threads, the thread directions of both ends of the bidirectional threaded rod i 201 are opposite, the sliding columns i 203 are respectively and slidably connected to the two sliding cylinders i 202, a compression spring i is fixedly connected between the sliding column i 203 and the sliding cylinder i 202, the conical rotating wheel i 204 is rotatably connected between the two sliding columns i 203, the graphite cylinder 205 is clamped between the two conical rotating wheels i 204, and the two sliding cylinders i 202 are both and slidably connected to the sliding rail 103.

The fourth concrete implementation mode:

the third embodiment is further described with reference to fig. 1 to 9, where the moving mechanism 3 includes a moving frame 301, a moving motor 302, a telescopic mechanism i 303 and a mounting bracket ii 304, the moving frame 301 is fixedly connected to the upper end of the apparatus frame 101, the moving frame 301 is fixedly connected to the moving motor 302, an output shaft of the moving motor 302 is connected to the telescopic mechanism i 303 through a thread, the telescopic mechanism i 303 is slidably connected to the moving frame 301, and the telescopic end of the telescopic mechanism i 303 is fixedly connected to the mounting bracket ii 304.

The fifth concrete implementation mode:

the fourth embodiment is further described with reference to fig. 1-9, wherein the adhering mechanism i 4 comprises two bidirectional threaded rods ii 401, two sliding cylinders ii 402, two sliding columns ii 403, two conical rotating wheels ii 404, two adhesive tape cylinders i 405, two adhesive tape cylinders ii 406, a storage motor i 407, a telescopic mechanism ii 408 and a support base plate i 409, the two bidirectional threaded rods ii 401 are rotatably connected to the mounting bracket ii 304, the two ends of the bidirectional threaded rods ii 401 have opposite screw directions, the two ends of the two bidirectional threaded rods ii 401 are respectively connected to the sliding cylinders ii 402 through screws, the sliding columns ii are slidably connected to the inside of each sliding cylinder ii 402, a compression spring ii is fixedly connected between the sliding columns ii 403 and the sliding cylinders ii 402, each sliding column ii 403 is rotatably connected to a conical rotating wheel ii 404, the adhesive tape cylinder i 405 and the adhesive tape cylinder 406 ii are respectively clamped between the two corresponding conical rotating wheels ii 404, connect through sticky tape I between a sticky tape section of thick bamboo I405 and a sticky tape section of thick bamboo II 406, take in output shaft fixed connection of motor I407 on one of them toper rotation wheel II 404, fixedly connected with supporting baseplate I409 on the flexible end of telescopic machanism II 408, and telescopic machanism II 408 fixed connection is on II 304 of installing support, and supporting baseplate I409 pushes up on sticky tape I.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1 to 9, and the embodiment further describes the fifth embodiment, the adhesion mechanism ii 5 includes two bidirectional threaded rods iii 501, two sliding cylinders iii 502, two sliding columns iii 503, a conical rotating wheel iii 504, a tape cylinder iii 505, a tape cylinder iv 506, a storage motor ii 507, a telescopic mechanism iii 508 and a support base plate ii 509, the two bidirectional threaded rods iii 501 are provided, the two bidirectional threaded rods iii 501 are both rotatably connected to the mounting bracket i 102, the thread directions of the two ends of the bidirectional threaded rods iii 501 are opposite, the two ends of the two bidirectional threaded rods iii 501 are both connected to the sliding cylinders iii 502 through threads, the sliding columns iii 503 are slidably connected to the inside of each sliding cylinder iii 502, a compression spring ii is fixedly connected between the sliding columns iii 503 and the sliding cylinders iii 502, the conical rotating wheel iii 504 is rotatably connected to each sliding column iii 503, the tape cylinder iii 505 and the tape cylinder iv 506 are respectively clamped between the two corresponding conical rotating wheels iii 504, an adhesive tape barrel III 505 and an adhesive tape barrel IV 506 are connected through an adhesive tape II, an output shaft of a storage motor II 507 is fixedly connected onto one of the conical rotating wheels III 504, a telescopic end of a telescopic mechanism III 508 is fixedly connected with a supporting base plate II 509, the telescopic mechanism III 508 is fixedly connected onto the mounting support I102, and the supporting base plate II 509 abuts against the adhesive tape II.

The seventh embodiment:

the embodiment is described below with reference to fig. 1 to 9, and the sixth embodiment is further described, where the filamentation mechanism i 6 includes a filamentation frame i 601, a filamentation motor i 602, a telescopic mechanism iv 603, a clamping frame i 604, a clamping plate i 605, a clamping threaded rod i 606 and a base i 607, the filamentation frame i 601 is fixedly connected to the device frame 101, the filamentation frame i 601 is fixedly connected to the filamentation motor i 602, an output shaft of the filamentation motor i 602 is connected to the telescopic mechanism iv 603 through a thread, a telescopic end of the telescopic mechanism iv 603 is fixedly connected to the clamping frame i 604, the clamping frame i 604 is slidably connected to two clamping plates i 605, the two clamping threaded rods i 606 are rotatably connected to the two clamping plates i 605, both the two clamping threaded rods i 606 are connected to the clamping frame i 604 through a thread, and the base i 607 is clamped between the two clamping plates i 605.

The specific implementation mode is eight:

the following describes the present embodiment with reference to fig. 1 to 9, and the seventh embodiment is further described in the present embodiment, where the filamentation mechanism ii 7 includes a filamentation frame ii 701, a filamentation motor ii 702, a telescopic mechanism v 703, a clamping frame ii 704, a clamping plate ii 705, a clamping threaded rod ii 706 and a base ii 707, the filamentation frame ii 701 is fixedly connected to the apparatus frame 101, the filamentation frame ii 701 is fixedly connected to the filamentation motor ii 702, an output shaft of the filamentation motor ii 702 is connected to the telescopic mechanism v 703 through a thread, a telescopic end of the telescopic mechanism v 703 is fixedly connected to the clamping frame ii 704, two clamping plates ii 705 are slidably connected to the clamping frame ii 704, two clamping threaded rods ii 706 are rotatably connected to the two clamping plates ii 705, both the two clamping threaded rods ii 706 are connected to the clamping frame ii 704 through a thread, and the base ii 707 is clamped between the two clamping plates ii 705.

A graphene heating wire processing method comprises the following steps:

the method comprises the following steps: clamping a graphite cylinder 205 between two conical rotating wheels I204, and carrying out primary adhesion on graphite on the graphite cylinder 205 by an adhesion mechanism I4;

step two: the moving mechanism 3 drives the adhesion mechanism I4 to move, and the adhesion mechanism I4 and the adhesion mechanism II 5 are contacted for multiple times to further adhere graphite on the adhesion mechanism I4;

step three: the moving mechanism 3 drives the adhesion mechanism I4 to move, and the wire forming mechanism I6 is contacted with the adhesion mechanism I4, so that graphene is formed on the wire forming mechanism I6;

step four: the filamentation mechanism II 7 contacts with the filamentation mechanism I6, the filamentation mechanism II 7 and the filamentation mechanism I6 do differential motion, the filamentation mechanism II 7 and the filamentation mechanism I6 generate relative motion, and graphene is coiled into graphene wires.

The invention relates to a graphene heating wire processing system and a method, which have the working principle that:

when the graphite barrel is used, the graphite barrel 205 is placed between the two conical rotating wheels I204, the bidirectional threaded rod I201 is rotated, the thread turning directions of two ends of the bidirectional threaded rod I201 are opposite, the bidirectional threaded rod I201 drives the two sliding barrels I202 to be close to each other through threads when rotating, the two sliding barrels I202 drive the two sliding columns I203 to be close to each other, the two sliding columns I203 drive the two conical rotating wheels I204 to be close to each other, and the two conical rotating wheels I204 clamp the graphite barrel 205; the adhesive tape barrel I405 and the adhesive tape barrel II 406 are respectively placed between the two corresponding conical rotating wheels II 404, as shown in FIG. 6, the adhesive tape I on the adhesive tape barrel I405 is wound on the adhesive tape barrel II 406, the lower end face of the adhesive tape I is an adhesive surface, the two-way threaded rods II 401 on two sides are rotated, the thread turning directions of two ends of each two-way threaded rod II 401 are opposite, the two sliding barrels II 402 are driven to mutually approach through threads when the two-way threaded rods II 401 rotate, the two sliding barrels II 402 respectively drive the two sliding columns II 403 to mutually approach, the two sliding columns II 403 respectively drive the two conical rotating wheels II 404 to mutually approach, and the two conical rotating wheels II 404 clamp the corresponding adhesive tape barrel I405 or the adhesive tape barrel II 406; similarly, a tape cylinder III 505 and a tape cylinder IV 506 are placed between the two corresponding conical rotating wheels III 504, the two bidirectional threaded rods III 501 are rotated, the tape cylinder III 505 and the tape cylinder IV 506 are clamped, a tape II on the tape cylinder IV 506 is wound on the tape cylinder III 505, and the upper end face of the tape II is a glue face; the substrate I607 is placed between two clamping plates I605, the substrate I607 and the substrate II 707 can be SiO₂The clamping threaded rod I606 is rotated, the clamping threaded rod I606 drives the clamping plate I605 to slide on the clamping frame I604 through threads to clamp the substrate I607; placing the substrate II 707 between the two clamping plates II 705, rotating the clamping threaded rod II 706, and driving the clamping plates II 705 to slide on the clamping frame II 704 through the threads by the clamping threaded rod II 706 to clamp the substrate II 707; starting I303 of telescopic machanism, I303 of telescopic machanism can be pneumatic cylinder or electric putter, and the flexible end of I303 of telescopic machanism promotes II 304 of installing support and moves downwards, and II 304 of installing support drive I4 of adhesion mechanism and move downwards, the lower terminal surface of sticky tape I andgraphite barrel 205, simultaneously starting storage motor I407, the output shaft of storage motor I407 begins to rotate, the output shaft of storage motor I407 drives adhesive tape barrel II 406 to rotate, adhesive tape barrel II 406 drives adhesive tape I to move, adhesive tape I adheres to the graphite on graphite barrel 205, mobile motor 302 is started, the output shaft of mobile motor 302 begins to rotate, the output shaft of mobile motor 302 drives telescoping mechanism I303 to move, telescoping mechanism I303 drives adhesion mechanism I4 to move, adhesion mechanism I4 is moved to the upper end of adhesion mechanism II 5, telescoping mechanism I303 is started, the lower end face of adhesive tape I is in contact with the upper end face of adhesive tape II, the graphite on adhesive tape I is preliminarily adhered, telescoping mechanism I is started, the first telescoping mechanism I303 is started, adhesion mechanism I4 is pulled upwards to move, storage motor II 507 is started, the output shaft of storage motor II 507 drives the corresponding adhesive tape barrel III 505 to rotate, the adhesive tape barrel III 505 drives the adhesive tape II to move, the adhesive surface of the adhesive tape II is replaced, the telescopic mechanism I303 is started again, the lower end face of the adhesive tape I is contacted with the upper end face of the adhesive tape II to be adhered again, the adhesive mechanism I4 is contacted with the adhesive mechanism II 5 for multiple times, and graphite on the adhesive mechanism I4 is further adhered; the moving motor 302 is started, the moving motor 302 drives the adhesion mechanism I4 to move, the adhesion mechanism I4 moves to the upper end of the filamentation mechanism I6, the telescopic mechanism I303 is started, the telescopic mechanism I303 drives the adhesion mechanism I4 to move downwards, the lower end face of the adhesive tape I is contacted with the substrate I607, after a period of time, the telescopic mechanism I303 is started, the telescopic mechanism I303 drives the adhesion mechanism I4 to move upwards, and graphene is formed on the substrate I607; starting a filamentation motor I602, enabling an output shaft of the filamentation motor I602 to start rotating, enabling an output shaft of the filamentation motor I602 to drive a telescopic mechanism IV 603 to move, enabling the telescopic mechanism IV 603 to drive a substrate I607 to move, enabling the substrate I607 to move to the lower end of a substrate II 707, starting the telescopic mechanism IV 603 and a telescopic mechanism V703, enabling the telescopic mechanism IV 603 and the telescopic mechanism V703 to be hydraulic cylinders or electric push rods, enabling the substrate I607 to be in contact with the substrate II 707, simultaneously starting the filamentation motor II 702 and the filamentation motor I602, enabling the filamentation motor II 702 and the filamentation motor I602 to rotate at different speeds, and enabling the filamentation motor I602 to rotate at different speedsDifferential motion between II 7 of mechanism and the I6 of filamentation mechanism, filamentation mechanism II 7 and the I6 production relative motion of filamentation mechanism, graphite alkene on the I607 of basement is rolled into the graphite alkene silk, I409 of supporting baseplate and II 509 can support sticky tape I and sticky tape II, prevent because the slope that sticky tape I produced when sticky tape section of thick bamboo I405 and sticky tape section of thick bamboo II 406 or sticky tape section of thick bamboo III 505 and sticky tape section of thick bamboo IV 506 are accomodate sticky tape I and sticky tape II.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (2)

1. The utility model provides a graphite alkene heater system of processing, includes device support (1), graphite mechanism (2), moving mechanism (3), adhesion mechanism I (4), adhesion mechanism II (5), filamentation mechanism I (6) and filamentation mechanism II (7), its characterized in that: the device comprises a device support (1), a graphite mechanism (2) and a moving mechanism (3), wherein the front end of the device support (1) is connected with the graphite mechanism, the upper end of the device support (1) is fixedly connected with the moving mechanism (3), the moving mechanism (3) is connected with an adhesion mechanism I (4), the middle part of the device support (1) is connected with an adhesion mechanism II (5), the lower side of the rear end of the device support (1) is fixedly connected with a wire forming mechanism I (6), and the middle part of the rear end of the device support (1) is fixedly connected with a wire forming mechanism II (7);

the device support (1) comprises a device frame (101), a mounting support I (102) and a sliding track (103), the mounting support I (102) is fixedly connected to the middle of the device frame (101), and the sliding track (103) is fixedly connected to the front end of the device frame (101);

the graphite mechanism (2) comprises a bidirectional threaded rod I (201), sliding cylinders I (202), sliding columns I (203), conical rotating wheels I (204) and graphite cylinders (205), the bidirectional threaded rod I (201) is rotatably connected to the device frame (101), the two ends of the bidirectional threaded rod I (201) are respectively in threaded connection with the sliding cylinders I (202), the two ends of the bidirectional threaded rod I (201) are opposite in thread rotating direction, the sliding columns I (203) are respectively and slidably connected in the two sliding cylinders I (202), a compression spring I is fixedly connected between the sliding columns I (203) and the sliding cylinders I (202), the conical rotating wheels I (204) are rotatably connected between the two sliding columns I (203), the graphite cylinders (205) are clamped between the two conical rotating wheels I (204), and the two sliding cylinders I (202) are both slidably connected to the sliding track (103);

the moving mechanism (3) comprises a moving frame (301), a moving motor (302), a telescopic mechanism I (303) and a mounting bracket II (304), the moving frame (301) is fixedly connected to the upper end of the device frame (101), the moving frame (301) is fixedly connected with the moving motor (302), an output shaft of the moving motor (302) is connected with the telescopic mechanism I (303) through threads, the telescopic mechanism I (303) is slidably connected to the moving frame (301), and the telescopic end of the telescopic mechanism I (303) is fixedly connected with the mounting bracket II (304);

the adhering mechanism I (4) comprises two bidirectional threaded rods II (401), two sliding cylinders II (402), two sliding columns II (403), two conical rotating wheels II (404), two adhesive tape cylinders I (405), two adhesive tape cylinders II (406), a storage motor I (407), a telescopic mechanism II (408) and a supporting base plate I (409), the two bidirectional threaded rods II (401) are rotatably connected to the mounting bracket II (304), the screw threads at the two ends of the two bidirectional threaded rods II (401) are opposite in rotating direction, the two ends of the two bidirectional threaded rods II (401) are respectively connected with the sliding cylinders II (402) through screw threads, the sliding columns II (403) are respectively and slidably connected in each sliding cylinder II (402), a compression spring II is fixedly connected between each sliding column II (403) and each sliding cylinder II (402), the conical rotating wheels II (404) are respectively and rotatably connected on each sliding column II (403), an adhesive tape cylinder I (405) and an adhesive tape cylinder II (406) are respectively clamped between two corresponding conical rotating wheels II (404), the adhesive tape cylinder I (405) and the adhesive tape cylinder II (406) are connected through an adhesive tape I, an output shaft of a storage motor I (407) is fixedly connected to one conical rotating wheel II (404), a support base plate I (409) is fixedly connected to a telescopic end of a telescopic mechanism II (408), the telescopic mechanism II (408) is fixedly connected to a mounting bracket II (304), and the support base plate I (409) is propped against the adhesive tape I;

the adhesion mechanism II (5) comprises two bidirectional threaded rods III (501), sliding cylinders III (502), sliding columns III (503), conical rotating wheels III (504), adhesive tape cylinders III (505), adhesive tape cylinders IV (506), a storage motor II (507), a telescopic mechanism III (508) and a supporting base plate II (509), wherein the two bidirectional threaded rods III (501) are rotationally connected to the mounting bracket I (102), the thread turning directions of the two ends of the bidirectional threaded rods III (501) are opposite, the two ends of the two bidirectional threaded rods III (501) are respectively connected with the sliding cylinders III (502) through threads, the sliding columns III (503) are respectively and slidably connected in each sliding cylinder III (502), a compression spring II is fixedly connected between each sliding column III (503) and each sliding cylinder (502), and the conical rotating wheels III (504) are respectively and rotatably connected on each sliding column III (503), a rubber belt cylinder III (505) and a rubber belt cylinder IV (506) are respectively clamped between the two corresponding conical rotating wheels III (504), the rubber belt cylinder III (505) and the rubber belt cylinder IV (506) are connected through a rubber belt II, an output shaft of a storage motor II (507) is fixedly connected to one conical rotating wheel III (504), a support base plate II (509) is fixedly connected to the telescopic end of a telescopic mechanism III (508), the telescopic mechanism III (508) is fixedly connected to the mounting bracket I (102), and the support base plate II (509) abuts against the rubber belt II;

the filamentation mechanism I (6) comprises a filamentation frame I (601), a filamentation motor I (602), a telescopic mechanism IV (603), a clamping frame I (604), a clamping plate I (605), a clamping threaded rod I (606) and a base I (607), the device comprises a device frame (101), a wire forming frame I (601), a wire forming motor I (602), a telescopic mechanism IV (603) connected to an output shaft of the wire forming motor I (602) through threads, a clamping frame I (604) fixedly connected to a telescopic end of the telescopic mechanism IV (603), two clamping plates I (605) slidably connected to the clamping frame I (604), clamping threaded rods I (606) rotatably connected to the two clamping plates I (605), the two clamping threaded rods I (606) are both connected to the clamping frame I (604) through threads, and a base I (607) is clamped between the two clamping plates I (605);

the filamentation mechanism II (7) comprises a filamentation frame II (701), a filamentation motor II (702), a telescopic mechanism V (703), a clamping frame II (704), a clamping plate II (705), a clamping threaded rod II (706) and a base II (707), become a silk frame II (701) fixed connection on device frame (101), fixedly connected with filamentation motor II (702) on filamentation frame II (701), there are telescopic machanism V (703) through threaded connection on the output shaft of filamentation motor II (702), fixedly connected with clamping frame II (704) on the flexible end of telescopic machanism V (703), sliding connection has two clamping boards II (705) in clamping frame II (704), all rotate on two clamping boards II (705) and be connected with clamping threaded rod II (706), two clamping threaded rod II (706) all through threaded connection on clamping frame II (704), the clamping has base II (707) between two clamping boards II (705).

2. The method for processing the graphene heating wire by using the graphene heating wire processing system as claimed in claim 1, is characterized in that: the method comprises the following steps:

the method comprises the following steps: clamping a graphite cylinder (205) between two conical rotating wheels I (204), and preliminarily adhering graphite on the graphite cylinder (205) by an adhering mechanism I (4);

step two: the moving mechanism (3) drives the adhesion mechanism I (4) to move, the adhesion mechanism I (4) and the adhesion mechanism II (5) are contacted for multiple times, and graphite on the adhesion mechanism I (4) is further adhered;

step three: the moving mechanism (3) drives the adhesion mechanism I (4) to move, and the wire forming mechanism I (6) is contacted with the adhesion mechanism I (4), so that graphene is formed on the wire forming mechanism I (6);

step four: the filamentation mechanism II (7) is contacted with the filamentation mechanism I (6), the filamentation mechanism II (7) and the filamentation mechanism I (6) do differential motion, the filamentation mechanism II (7) and the filamentation mechanism I (6) generate relative motion, and graphene is coiled into graphene wires.

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