Antherobacter sp.에 의한 납 제거

Removal of Lead by Anherobacter sp.

  • 안갑환 (지산전문대 환경관리과) ;
  • 서근학 (부경대학교 화학공학과)
  • 발행 : 1998.02.01

초록

중금속 폐수를 처리하는 활성슬러지로 부터 Arthrobactor sp.를 부터 분리하여 생체흡착 실험에 사용하였다. Aythrobactor sp.의 납 흡착량은 초기농도 500 mg/L에서 146.9 mg Pb/g dry biomass로 Sacchuomyces ceieuslae와 Sacchuomyces uvuum보다 약 4배 더 많은 흡착량을 보여주었다. pH가 1.8, 3.0 및 4.0으로 골아 질수록 납의 홉착량은 증가하였고, biomass의 양이 많아질수록 단위 미생물당 납 흡착량은 감소하였다. Biomass에 0.1M KOH, $CaCl_2$및 NaOH로 4시간 동안 전 처리하여 흡착실험을 수행한 결과 KOH로 전 처리된 biomass의 납 흡착량은 1.26배 증가하였으나 NaOH로 처리한 것은 납의 흡착량이 감소하였다. Polyacrylamide에 고정화된 biomass를 반응기에 충진한 연속실험에서, 유속 2.12 $m^3/m^2/$day 에서 15시간 동안 납 제거효율이 99%이상 되었다.

The biosorption of heavy metals has received a lot of attraction for application of metal ions treatment. In this work, we studied with Arthrobactor sp., screening from a wastewater containing heavy metals. The Pb uptake capacity of Arthrobactor sp. was nearly 146.9 mg Pb/g dry biomass(initial concentration, 500 may L), whereas the Pb uptake capacity of Sacchuomyces cerevisiae and Sacchuomyces uvuum were only around 39.40 and 35.65 mg Pb yg dry biomass, respectively. The Pb and Cr were removed from metal solution much more effeciently than were the other metals(Cd and Cu). The Pb uptake capacity of Aythrobactor sp. increased with increasing in pH(1.8, 3.0 and 4.0) and decreased with Increaslng of biomass concentration. At pH 4.0, the Pb uptake capacity reached 244 mg Pb/g dry biomass in Pb initial concentration of 1000 mg/L. The Pb uptake capacity of Ayhol)actor sp. treated by KOH and $CaCl_2$ were increased above values obtained with untreated Ayurobactor sp. However, the Pb uptake capacity fore the breakthrough points were reached.

키워드

참고문헌

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