화학공학소재연구정보센터
로그인 로그아웃 연락처 사이트맵
Korean Journal of Materials Research, Vol.22, No.12, 643-649, December, 2012
DOI10.3740/MRSK.2012.22.12.643  Export Citation
알루미나-불소 복합 코팅제로 습식코팅된 스텐레스 강판의 화학 내식성 평가
Chemical Evaluation of Corrosion Resistance for Stainless-Steel Plate Wet-Coated by Alumina-Fluoro Composite Coatings
정하영, 김대성, 이승호, 임형미, 김건1, 정민규1
  • 한국세라믹기술원 에너지환경소재본부 에코복합소재센터
  • 1(주)세미라인
Ha-Young Jung, Dae Sung Kim, Seung-Ho Lee, Hyung Mi Lim, Kun Kim1, and Min-Kyu Jung1
  • Eco-Composite Materials Center, Korea Institute of Ceramic Engineering & Technology(KICET), Seoul 153-801, Korea
  • 1Semiline Co., Hawsung City, Kyungki-Do, Korea
E-mail:
Coatings composited with alumina and Perfluoro alkoxyalkane (PFA) resin were deposited on stainless steel plate (SUS304) to further improve corrosion resistance. Plate (ca. 10 μm) and/or nanosize (27~43 nm) alumina used as inorganic additives were mixed in PFA resin to make alumina-fluoro composite coatings. These coatings were deposited on SUS304 plate with wet spray coating and then the film was cured thermally. According to the amount and ratio of the two kinds of alumina having plate morphology and nano size, corrosion resistance of the film was evaluated under strong acids (HF, HCl) and a strong base (NaOH). The film prepared with the addition of 5~10 wt% alumina powders in PFA resin showed corrosion resistance superior to that of pure PFA resin film. However, for the film prepared with alumina content above 10 wt%, the corrosion resistance did not improve with the physical properties, such as surface hardness and adhesion. The film prepared with plate/nanosize (weight ratio = 1/2) alumina especially enhanced the surface hardness and corrosion resistance. This can be explained as showing that the plate and the nanosize alumina dispersed in PFA resin effectively suppressed the penetration of cations and anions due to the long penetration length and fewer defects that accompany the improved surface hardness under a serious environment of 10% HF solution for over 120 hrs.
Keywords:alumina-fluoro composite;coatings;plate and nanosize alumina;corrosion resistance;HF
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