화학공학소재연구정보센터
로그인 로그아웃 연락처 사이트맵
Korean Journal of Chemical Engineering, Vol.16, No.6, 778-783, November, 1999
DOI10.1007/BF02698351  Export Citation
Mathematical Model of a Monolith Catalytic Incinerator
Soo Hyun Jang1, Wha Seung Ahn1, †, Jae Mok Ha1, 2, and Kwang Ja Park1, 2
  • 1School of Chemical Science and Engineering, Inha University, Inchon, Korea
  • 2Agency for Technology and Standards, Kwacheon, Korea
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A set of 1-dimensional mathematical models were developed to simulate both the steady state and transient performance of monolithic catalytic incinerators for VOC abatement. In modelling transient performance, quasi-steady state gas phase was assumed since transient response time is determined primarily by the thermal inertia of the monolith. Higher inlet gas temperatures and lower gas velocities were predicted to give higher conversion and faster response times. VOC concentration had little influence on the performance within the concentration ranges used. A catalytic incinerator is shown to operate typically under mass transfer limited conditions, and monolith channel density and shape have significant influence on the conversion and monolith heating time. The metallic monolith was predicted to show superior steady state and transient responses due to its lower thermal inertia generated by higher cell density and thinner wall.
Keywords:Catalytic Incinerator;Monolith;Mathematical Model;VOC
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