CLC number: X7
On-line Access:
Received: 2004-09-25
Revision Accepted: 2004-12-05
Crosschecked: 0000-00-00
Cited: 4
Clicked: 6414
MIAO Jian-yu, ZHENG Lian-ying, GUO Xiao-fen. Restaurant emissions removal by a biofilter with immobilized bacteria[J]. Journal of Zhejiang University Science B, 2005, 6(5): 433-437.
@article{title="Restaurant emissions removal by a biofilter with immobilized bacteria",
author="MIAO Jian-yu, ZHENG Lian-ying, GUO Xiao-fen",
journal="Journal of Zhejiang University Science B",
volume="6",
number="5",
pages="433-437",
year="2005",
publisher="Zhejiang University Press & Springer",
doi="10.1631/jzus.2005.B0433"
}
%0 Journal Article
%T Restaurant emissions removal by a biofilter with immobilized bacteria
%A MIAO Jian-yu
%A ZHENG Lian-ying
%A GUO Xiao-fen
%J Journal of Zhejiang University SCIENCE B
%V 6
%N 5
%P 433-437
%@ 1673-1581
%D 2005
%I Zhejiang University Press & Springer
%DOI 10.1631/jzus.2005.B0433
TY - JOUR
T1 - Restaurant emissions removal by a biofilter with immobilized bacteria
A1 - MIAO Jian-yu
A1 - ZHENG Lian-ying
A1 - GUO Xiao-fen
J0 - Journal of Zhejiang University Science B
VL - 6
IS - 5
SP - 433
EP - 437
%@ 1673-1581
Y1 - 2005
PB - Zhejiang University Press & Springer
ER -
DOI - 10.1631/jzus.2005.B0433
Abstract: Pseudomonas sp. ZD8 isolated from contaminated soil was immobilized with platane wood chips to produce packing materials for a novel biofilter system utilized to control restaurant emissions. The effects of operational parameters including retention time, temperature, and inlet gas concentration on the removal efficiency and elimination capacity were evaluated. Criteria necessary for a scale-up design of the biofilter was established. High and satisfactory level of rapeseed oil smoke removal efficiency was maintained during operation and the optimal retention time was found to be 18 s corresponding to smoke removal efficiency greater than 97%. The optimal inlet rapeseed oil smoke loading was 120 mg/(m3·h) at the upper end of the linear correlation between inlet loading and elimination capacity.
[1] Bohn, H.L., 1992. Consider biofiltration for decontaminating gases. Chem Eng Progress, 88(4):34-40.
[2] Chen, H., Ye, S.H., 1991. The impact of restaurant oil smoke on the health of human body. Shanghai Enviromental Science, 10(8):48 (in Chinese).
[3] Gupta, D., Boffetta, P., Gaborieau, V., Jindal, S.K., 2001. Risk factors of lung cancer in Chandigarh, India. India J Med Research, 113:142-150.
[4] Kleinerman, R.A., Wang, Z.Y., Lubin, J.H., Zhang, S.Z., Metayer, C., Brenner, A.V., 1999. Lung cancer and indoor air pollution in rural China. Epidemiology, 10(5):488-494.
[5] Koh, L.H., David, C.S., Kuhn, M., Mohseni, D., Grant, A., 2004. Pre-treatment of volatile organic compounds upstream of biological gas cleaning operation. Journal of Chemical Technology and Biotechnology, 79:619-625.
[6] Leson, G., Winer, A., 1991. Biofiltration: an innovative air pollution control technology for VOC emissions. Air Waste Manage Assoe, 41(8):1045-1054.
[7] Liu, Z.Q., Zhu, Z.G., Wang, X.Z., 1987. Study on mutagenicity of oil smoke from kitchen. Journal of Environment and Health, 4(6):10.
[8] Lu, Z.J., Sologar, V.S., Allen, D.G., 2003. Biofilteration of Concentrated Mixtures of Hydrogen Sulfide and Methanol. Environmental Progress, 22(2):129-136.
[9] Lutz, D., 1982. Structure-mutagenicity relationship in α,β-unsaturated compounds and their corresponding allylic alcohols. Journal of Mutant Research, 93:305.
[10] Neal, A.B., Loehr, R.C., 2000. Use of biofilters and suspended-growth reactors to treat VOCs. Waste management, 20:59-68.
[11] Pedersen, A.R., Arvin, E., 1995. Removal of toluene in waste gases using a biological trickling filter. Biodegradation, 6(2):109-118.
[12] Zhang, H., Wang, G.X., Tan, W.J., 2002. Study on the effects of cooking oil fume condensate on the DNA integrality. Journal of Hygiene Research, 31(4):238-240.
Open peer comments: Debate/Discuss/Question/Opinion
<1>