Journal of the Korea Organic Resources Recycling Association (유기물자원화)

Korea Organic Resources Recycling Association (유기성자원학회)
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Optimal Operation of Medium Sized Incinerator to Minimize PCDD/Fs Emission

중형 소각로 다이옥신 배출 저감을 위한 최적 운전인자

  • Yoo, Dong-Joon (Ministry of Defence, MND USFK Base Relocation Office) ;
  • Koo, Ja-Kong (Departments of Renewable Energy, Jung-won University) ;
  • Jeong, Seung-Ik (Departments of Renewable Energy, Jung-won University)
  • 유동준 (국방부 주한미군기지 이전사업단) ;
  • 구자공 (중원대학교 신재생에너지학과) ;
  • 정승익 (중원대학교 신재생에너지학과)
  • Received : 2013.10.29
  • Accepted : 2013.12.02
  • Published : 2013.12.30
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Abstract

An establishment of dioxin-reduction operating skill for medium sized incineration facility is urgently needed in Korea with nearly 90% of medium sized incineration. Using lattice stoker incineration processing the capacity of 20 tons industrial general waste per day, similar properties of the household waste, dioxin-reduction is derived in optimum operating condition and parameters. As a result, CO haunting which is the minimization of frequency is found as the major parameter to minimize dioxin.

한국의 중형 소각시설이 전체 소각로 개수의 약 90% 차지하는 실정에서 중형 소각시설의 다이옥신 저감운전기술을 확립하는 것은 매우 시급하다. 생활폐기물과 성상이 유사한 사업장 일반폐기물을 일 20톤 처리용량의 중형규모 구동화격자 스토커 소각시설에서 운전하면서, 각 공정별로 다이옥신 저감을 위한 최적 운전 인자를 도출하였다. CO튀는 현상의 최소가 다이옥신 배출저감에 운전최선책임이 밝혀졌다.

Keywords

References

  1. [환경부, 환경백서] Ministry of Environment, White paper of Environment, p.260, (2011).
  2. [환경부, 2012년 잔류성 유기오염물질배출 시설 다이옥신 측정.분석 결과] Ministry of Environment, POPs emissions measurement and analysis, pp.7-9 (2013).
  3. [환경부, 전국 폐기물 발생 및 처리현황] Ministry of Environment, 2011 The National Waste Generation and Treatment, p.34-36, (2012).
  4. Kari Tuppurainen, Ismo Halonen, Paivi Ruokojarvi, Juhani Tarhanen, and Juhani Ruskanen, "Formation of PCDDs and PCDFs in municipal waste incineration and its inhibition mechanisms a review", Chemosphere, 36(7), pp.1493-1511, (1988).
  5. Park, S.I. "A Study on flow and heat transfer in rapid cooling type heat recovery system for dioxin reduction", J. of Environmental Societies Joint Conference, pp.17-18, (2007).
  6. Blumenstock, M. Zimmermann, R., Schramm, K. W., and Kettrup, A, "Influence of combustion conditions on the PCDD/F-, PCB-, PCBz- and PAHconcentration In the post-combustion chamber of waste incineration pilot plant", Chemosphere, Vol.40, pp.987-993, (1999).
  7. Choi, J. S., Development of catalytic filter system for removing both dust and dioxin in combustion facilities, Poasen, pp.13-14. (2007).
  8. Kim, Y. M. Jang, S. W. and Hong, J. P. "Patent Technology for the Elimination of Dioxin", Environmental Engineering Research, 29(10), pp.1079-1082, (2007).
  9. [환경부, 생활 및 사업장폐기물 소각여열 회수 및 이용실태 조사결과] Ministry of Environment, Survey of Using and Heat Recovery of Waste Incineration, pp.1-2, (2009).
  10. [환경부, 2008년 생활폐기물 소각시설 설치.운영 현황] Ministry of Environment, Installation and Operation of Waste Incinerators, pp. 23-25, (2009).
  11. Jung, B.J., "Study of Incineration BAT, BEP", NIER, pp.102-116, (2005)
  12. LEE, E.S., "Waste incineration Plant Emissions of Dioxin Practical Research Advanced Treatment Processes" AGEC, pp. 215-216, (2003)
  13. KIWRMA, "Private Companies Charge Processing of Waste Incineration Feasibility Study", pp.74-82 (2011).