Abstract: The present invention relates to a method for producing porous carbon materials comprising the following steps: (S1) forming carbon coatings on surfaces of ceramic nanoparticles; (S2) mixing carbon precursors and ceramic nanoparticles on which carbon coatings are formed in the step (S1); (S3) heat-treating the mixture of the ceramic nanoparticles having carbon coatings thereon and carbon precursors, prepared in the step (S2) to carbonize the mixture; and (S4) removing the ceramic nanoparticles from the material obtained in the step (S3). The method for producing porous carbon materials according to the present invention enables porous carbon materials in which mesopores are uniformly distributed, to be mass produced with low costs. The porous carbon materials having mesopores may be used as catalyst supports for fuel cells, and thus may be used in producing electrodes for fuel cells.

Abstract: The present invention relates to a method for producing porous carbon materials comprising the following steps: (S1) forming carbon coatings on surfaces of ceramic nanoparticles; (S2) mixing carbon precursors and ceramic nanoparticles on which carbon coatings are formed in the step (S1); (S3) heat-treating the mixture of the ceramic nanoparticles having carbon coatings thereon and carbon precursors, prepared in the step (S2) to carbonize the mixture; and (S4) removing the ceramic nanoparticles from the material obtained in the step (S3). The method for producing porous carbon materials according to the present invention enables porous carbon materials in which mesopores are uniformly distributed, to be mass produced with low costs. The porous carbon materials having mesopores may be used as catalyst supports for fuel cells, and thus may be used in producing electrodes for fuel cells.

Abstract: A rotary type microwave heating furnace of the present disclosure includes a cavity configured to form an airtight space to which the microwave is radiated, a microwave generation apparatus configured to radiate the microwave to the inside of the cavity, a heating element rotatably installed within the cavity in a tilted posture and configured to have the target heating subject received therein, a target heating subject supply apparatus configured to sequentially supply the target heating subjects to the heating element, a heating element rotation apparatus configured to supply power for rotating the heating element, and a control unit configured to control the amount of the target heating subject, supplied from the target heating subject supply apparatus, and the rotary velocity of the heating element performed by the heating element rotation apparatus.

Abstract: A method for fabricating an electrode and membrane assembly (MEA) for polymer electrolyte membrane fuel cells. The MEA comprises a polymer electrolyte membrane on each side of which an electrocatalyst layer is provided in a melted state. A perfluorosulfonyl fluoride copolymer powder ranging, in particle size distribution, from 20 to 200 &mgr;m is hot-pressed at 200-250° C. to give a pre-formed sheet whose opposite sides are then coated with a catalyst ink consisting of Pt/C powder, glycerol and water. This catalyst ink-coated preformed sheet is again subjected to hot pressing at 200-250° C. to embed the catalyst ink into the pre-formed sheet. Hydrolysis in NaOH/methanol or H2SO4 solution converts the membrane of the sheet from a non-ionized form to an ionized form.