▎ 摘　　要

NOVELTY - Device comprises cabin body, which is orderly provided with atomic concentrator, field-effect separator by graphene film coiled material production process, reformer, hall discharging unit (7), weight efficient fine unit, fischer-tropsch enhancer (9), tension shaft (4) and guide shaft (13). The atom concentrator is set on the upper part in the cabin body (16), and atom concentrator is provided with an atomic fountain apparatus. The atomic fountain apparatus (18) is provided with graphite electrode for igniting magnesium wire. USE - Device for producing graphene thin film coiled material (claimed). ADVANTAGE - The device helps in reducing emission of carbon dioxide, atmospheric greenhouse effect, has small power consumption of about 5 degrees and is eco-friendly. DETAILED DESCRIPTION - Device comprises cabin body, which is orderly provided with atomic concentrator, field-effect separator by graphene film coiled material production process, reformer, hall discharging unit, weight efficient fine unit, fischer-Tropsch enhancer, tension shaft and guide shaft. The atom concentrator is set on the upper part in the cabin body, and atom concentrator is provided with an atomic fountain apparatus. The atomic fountain apparatus is provided with graphite electrode for igniting magnesium wire. The field-effect separator (5) used for separating impurities and mixed gas of atomic carbon and magnesium oxide is separated into pure atomic carbon gas and impurity gas, which is arranged below the atom concentrator, and reformer for the pure carbon atom gas guided to the polyethylene terephthalate film (1). An INDEPENDENT CLAIM is included for a method for producing graphene film, involves: (A) installing cabin after the cover seal; (B) introducing nitrogen into the space capsule to replace the air inside the cabin; (C) adding carbon dioxide into the space tank to replace the nitrogen inside the cabin; (D) supplying helium into the space tank to replace the carbon dioxide within the cabin; (E) circulating helium in the capsule to the outside of the tank, then removing moisture and impurities in the capsule from the tank by helium dehumidification tank to obtain capsule super clean room; (F) adding carbon dioxide into the atomic fountain; (G) adding magnesium wire into the carbon atom fountain, through the atom fountain inside the igniter for igniting magnesium wire in the fountain and releasing a large number of atomic carbon and magnesium oxide mixed gas; (H) feeding mixed gas of the atomic carbon and the magnesium oxide from atomic concentrator to field effect separator; (I) separating atomic carbon and magnesium oxide mixed gas into pure atomic carbon gas and impurity gas; (J) directing pure atomic carbon gas onto the polyethylene terephthalate film film by recombinator forming primary small graphene; (K) reorganizing the obtained primary small graphene into fine row of large graphene with Hall fins; (L) forming complete graphene belt then directing the graphene belt to the fermion enhancer for strengthening the strength of the graphene zone; (M) pulling the graphene belt to the film tension axis to adjust the tensile strength of the finished film; and (N) passing then obtained finished film through the guide shaft, next to the quality inspection axis for testing the quality of the obtained desired graphene. DESCRIPTION OF DRAWING(S) - The drawing shows a schematic view of a graphene thin film coiled material producing device Polyethylene terephthalate film (1) Tension shaft (4) Field-effect separator (5) Hall discharging unit (7) Fischer-tropsch enhancer (9) Guide shaft (13) Cabin body (16) Atomic fountain apparatus (18)