MANUFACTURING METHOD OF CATHODE OF MICROBIAL FUEL CELL AND CATHODE OF MICROBIAL FUEL CELL MANUFACTURED BY THE SAME

MANUFACTURING METHOD OF CATHODE OF MICROBIAL FUEL CELL AND CATHODE OF MICROBIAL FUEL CELL MANUFACTURED BY THE SAME

The present invention relates to a cathode of a microbial fuel cell (MFC) and a method for manufacturing the same, wherein the method for manufacturing a cathode of an MFC comprises the steps of: mixing sodium dodecyl sulfate (SDS), multi walled carbon nanotube (MWCNT), FePC and CuPc with distilled...

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Bibliographische Detailangaben
Hauptverfasser: KIM, JUNG RAE, JANG, HOON, CHA, JAE HWAN, MIN, BOO KI, PARK, SEUNG KOOK, SONG, YOUNG CHAE, CHOI, HAN NA, LEE, TAE HO, SHIN, JUNG HUN, KIM, BYUNG GOON, KIM, HONG SUCK, KIM, JI YEON, SHIN, KYUNG SOOK, SEO, IN SEOK, KIM, DAE HYUN, KIM, YOUN KWON
Format: Patent
Sprache:eng ; kor
Schlagworte:
BASIC ELECTRIC ELEMENTS
ELECTRICITY
PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSIONOF CHEMICAL INTO ELECTRICAL ENERGY
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Zusammenfassung:The present invention relates to a cathode of a microbial fuel cell (MFC) and a method for manufacturing the same, wherein the method for manufacturing a cathode of an MFC comprises the steps of: mixing sodium dodecyl sulfate (SDS), multi walled carbon nanotube (MWCNT), FePC and CuPc with distilled water to prepare a mixed solution (Step 1); stirring the mixed solution (Step 2); performing microwave processing to the stirred mixed solution (Step 3); separating the mixed solution processed with microwaves by a centrifuge and then removing a supernatant to obtain a catalyst (Step 4); adding an ethanol to the catalyst to wash SDS (Step 5); separating the washed catalyst and the ethanol by a centrifuge and removing a supernatant to obtain the washed catalyst (Step 6); adding a nafion solution to the washed catalyst and stirring the mixture to prepare a catalyst for a cathode (Step 7); and screen printing the catalyst for a cathode on the surface of a cathode to prepare an MFC cathode (Step 8), wherein the maximum power density of an MFC using an MFC cathode including a Cu-Fe catalyst is very higher than the maximum power density of an MFC using an MFC cathode including a platinum catalyst. Therefore, the MFC cathode of the present invention is advantageously moderate in price and has excellent performance, compared with a conventional MFC cathode using a platinum catalyst. 본 발명은 미생물연료전지 환원전극의 제조방법 및 이에 의해 제조된 미생물연료전지 환원전극에 관한 것으로서, SDS(Sodium dodecyl sulfate), MWCNT(Multi walled carbon nanotube), FePC 및 CuPc를 증류수에 혼합하여 혼합액을 만드는 단계(단계 1); 상기 혼합액을 교반하는 단계(단계 2); 상기 교반한 혼합액을 마이크로파 처리하는 단계(단계 3); 상기 마이크로파 처리된 혼합액을 원심분리한 후 상등액을 제거하고 촉매를 수득하는 단계(단계 4); 상기 촉매에 에탄올을 넣어 SDS(Sodium dodecyl sulfate)를 세척하는 단계(단계 5); 상기 세척된 촉매와 에탄올을 원심분리한 후 상등액을 제거하고 세척된 촉매를 수득하는 단계(단계 6); 상기 세척된 촉매에 nafion 용액을 넣고 교반하여 환원전극용 촉매를 제조하는 단계(단계 7); 및 상기 환원전극용 촉매를 환원전극 표면에 스크린 프린팅하여 미생물연료전지 환원전극을 제조하는 단계(단계 8); 를 포함하여 제조하는 것을 기술적 특징으로 하며, Cu-Fe 촉매를 포함한 미생물연료전지 환원전극을 사용한 MFC의 최대전력밀도는 백금촉매를 포함한 미생물연료전지 환원전극을 사용한 MFC의 최대전력밀도 보다 매우 높은 전력밀도를 나타내므로, 본 발명의 미생물연료전지 환원전극은 백금촉매를 사용하는 종래의 미생물연료전지 환원전극에 비해 가격도 저렴하면서 성능도 우수한 장점이 있다.