Journal of Korean Society of Environmental Engineers (대한환경공학회지)

Korean Society of Environmental Engineers (대한환경공학회)
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Removal Charateristics of Erythrosine by Activated Carbon Adsorption

활성탄 흡착에 의한 Erythrosine의 제거 특성

  • Lee, Jong-Jib (School of Chemical Engineering, Kongju National University) ;
  • Yoon, Sung-Wook (Innovation Center for Engineering Education, Dankook University)
  • 이종집 (공주대학교 화학공학부) ;
  • 윤성욱 (단국대학교 교육혁신센터)
  • Received : 2009.03.12
  • Accepted : 2009.07.01
  • Published : 2009.07.31
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Abstract

Erythrosine is used a food coloring, ink and dye, etc. but erithrosine is rarely used in United States due to its known hazards. The adsorption characteristics of erythrosine by granular activated carbon were investigated in the batch adsorber and the packed column. The adsorptivity of activated carbon for erythrosine were largely improved by pH control. When the pH was 11 in the sample, the erythrosine could be removed 98% of initial concentration. It was estabilished that the adsorption equilibrium of erythrosine on granular activated carbon was successfully fitted by Freundlich isotherm equation in the concentration range from 10mg/L to 1,000mg/L. The characteristics of breakthrough curve of activated carbon packed column depend on the design variables such as initial concentration, bed height, and flow rate.

Erythrosine은 식용색소와 염료로 사용되지만 독성 때문에 미국에서는 거의 사용되지 않는 물질이다. 본 연구에서는 입상활성탄에 의한 erythrosine의 흡착특성을 회분식 및 흡착칼럼실험을 통하여 조사하였다. erythrosine에 대한 활성탄의 흡착능은 pH조절에 의해 크게 개선되었으며 pH 11에서 초기농도 1,000 mg/L의 98%를 제거할 수 있었다. 회분식흡착실험을 통해 흡착등온선을 구한 결과 erythrosine의 평형흡착관계는 10~1,000 mg/L의 농도범위에서 Freundlich식이 잘 적용되었다. 고정층 실험을 통하여 얻은 파과곡선으로부터 초기유입농도, 유입속도, 충전층의 높이가 흡착탑 운전에 중요한 설계변수가 될 수 있음을 알았다.

Keywords

References

  1. 식품의약품안전청, “식품첨가물공전”, 동원출판사, pp. 182-212(2002)
  2. Yankell, S. L. and Loux, J. J., “Acute toxity testing of erythrosine and sodium fluorescein in mice and rats” J. Periodont, 48, 228-230(1977) https://doi.org/10.1902/jop.1977.48.4.228
  3. Collins, T. F. X., Black T. N., O-Donell M. W. jr., Shackelford M. E. and Bulhack, P., “Teratogenic potential of erythrosine when given in drinking water”Food. Chem. Toxicol., 31, 161-167(1993) https://doi.org/10.1016/0278-6915(93)90089-H
  4. 식약청 미공개연구보고서, 신동아, 590, pp. 198-205 (2008)
  5. 정엽, 권종원, 민신홍,“The Interaction of Erythrosine with several Phameceutical Gelatines”, 약제학회지, 14(1), 50-52 (1984)
  6. Vinod, K., Alock, M., Lisha, K. and Jyoti, M., “Adsorption of a hazardous dye, erythrosine, over hen feathers”, J. Colloidand Interface, 304, 52-57(2006) https://doi.org/10.1016/j.jcis.2006.08.032
  7. Budavari, S.,“ The Merck Index”. Merck & Co. Inc., 11th ed., p. 61(1989)
  8. Yanai Hiroshi, “흡착공학요론”, 공립출판주식회사, 1st ed., pp. 25-60(1977)
  9. Fukukawa 저, 박영태 역 활성탄 수처리기술과 관리” 동화기술, p. 69(2003)
  10. Lee, J. J. and Yoo, Y. H., “Study on Adsoption Characteristics of Tharonil on Activated Carbon Fixed Bed”, J. Korean Soc. Safety, 17(1), 54-62(2002)
  11. 이종집, 유용호, “입상활성탄에 의한 BEAM의 흡착특성 (II)”, 대한환경공학회지, 20(4), 509-518(1998)