▎ 摘　　要

NOVELTY - Graphene physical vapor deposition (PVD) coated coil material production device comprises reaction vessel. The reaction vessel comprises atomic geyser, field effect separator, atomic disperser, recombinator, Hall fine arranger, dose-effect fine assembly device, Fermi enhancer and quality inspection device are arranged in sequence according to a production process of a graphene physical vapor deposition coating coil material. The raw material used as the carbon source is acetylene in the graphene PVD coating film production equipment and process. The field effect separator is disposed at a lower portion of the reaction vessel. The field effect separator is disposed above the atomic fountain. The atomic disperser is disposed above the field effect separator. The recombiner is for guiding pure carbon atoms onto polyethylene terephthalate film and recrystallizing pure carbon atoms on the polyethylene terephthalate film into a primary scatter structure of graphene. USE - Used as graphene physical vapor deposition coated coil material production device. ADVANTAGE - The method: utilizes acetylene as the carbon source, and has small power consumption for about 24 degrees on daily power consumption basis. DETAILED DESCRIPTION - Graphene physical vapor deposition (PVD) coated coil material production device comprises reaction vessel. The reaction vessel comprises atomic geyser, field effect separator, atomic disperser, recombinator, Hall fine arranger, dose-effect fine assembly device, Fermi enhancer and quality inspection device are arranged in sequence according to a production process of a graphene physical vapor deposition coating coil material. The raw material used as the carbon source is acetylene in the graphene PVD coating film production equipment and process. The field effect separator is disposed at a lower portion of the reaction vessel. The field effect separator is disposed above the atomic fountain. The atomic disperser is disposed above the field effect separator. The recombiner is for guiding pure carbon atoms onto polyethylene terephthalate film and recrystallizing pure carbon atoms on the polyethylene terephthalate film into a primary scatter structure of graphene and disposed above the atomic disperser. The Hall finisher is configured to make a reciprocating lateral rolling of carbon atoms not arranged in graphene, and to find a void participation combination. The first-formed scatter structure graphene is arranged into an island-type graphene. The dose-effect precision assembler causes longitudinal rolling of carbon atoms which have not been incorporated into a combination to convert the graphene group of the island structure into the flaky structure of graphene. The fermion ferrite is used for rapidly grow the vagal structure graphene to a high-strength layered graphene film, which is disposed beside the Hall finisher. An INDEPENDENT CLAIM is also included for preparing graphene physical vapor deposition coated coil material comprising (1) installing the upper cover of the reaction kettle and sealing, (2) feeding nitrogen into the reaction vessel to displace the air in the kettle, (3) feeding carbon dioxide into the reaction vessel to displace the nitrogen in the kettle, (4) feeding the inert protective gas into the reaction vessel to displace the carbon dioxide in the kettle, (5) sending the inert protective gas out of the reaction vessel for circulation in the reaction kettle, removing the water vapor and impurities in the reaction kettle by the dehumidifier through the circulation of the inert protective gas to make the inside of the reaction vessel becomes a super clean kettle, (6) feeding oxygen into the reaction vessel, (7) sending the acetylene in to the atomic geyser through the separation in the atomic geyser and acetylene releases a large amount of mixed gas of carbon and impurities in the geyser, (8) separating and purifying the carbon from a mixture of carbon and impurities using field effect separator and then transporting the purified carbon element to the atomic disperser, (9) forming atom disperser after initial purification not to agglomerate in a certain time, (10) directing the purified carbon raw element gas onto the polyethylene terephthalate film by the reformer, and recombining the carbon element on the polyethylene terephthalate film to obtain a graphene having a primary scatter structure, (11) placing Hall finisher next to the recombiner to arrange the smectic structure of graphene finely formed on the polyethylene terephthalate film into island structure graphene, (12) forming the island structure graphene on the polyethylene terephthalate film into a vagus structure graphene by a mass-effect fine-tuner next to the Hall arrangement, (13) equipping the Fermion reinforcer with fermion structure to form a stable graphene film which has been formed on the polyethylene terephthalate film and rapidly growing into a high-strength layered growth state, (14) further turning the polyethylene terephthalate film tape by a guide shaft, disposing a cleaner above the guide shaft to peel off impurities, discharging the agglomerated carbon atoms in the carbonaceous gas during the layered growth process, collecting the stripped impurities by a collector inside the cleaner and delivering the collection of collector assemblies in to the outside of the kettle, (15) turning the polyethylene terephthalate film tape by the guide shaft, and placing a quality detector above the polyethylene terephthalate film tape to inspect the quality of the finished graphene layered growth, (16) guiding the polyethylene terephthalate film tape on the flattened shaft to flatten the polyethylene terephthalate film tape, pulling the polyethylene terephthalate film tape to the guide film shaft for turning onto the finished film assembly outside the kettle, using regardless of the method to produce the oversized graphene, it is necessary to first obtain an ultra-pure carbonaceous purity of 6.023x 1023.N without an impurity molecule or atom, if there are still one or two impurity molecules or atoms, and then designing an apparatus for structuring the extruding of impurity molecules or atoms remaining in the carbon gas during the layered growth process. DESCRIPTION OF DRAWING(S) - The drawing shows a schematic representation of the graphene physical vapor deposition coated coil material production device.