“Oxygen Effects in Anaerobic Digestion - II”

Authors: Deshai Botheju, Bernt Lie and Rune Bakke,
Affiliation: Telemark University College
Reference: 2010, Vol 31, No 2, pp. 55-65.

Keywords: ADM 1-Ox model, simulation, anaerobic digestion, oxygen effects, optimum oxygenation

Abstract: Standard models describing bio-gasification using anaerobic digestion do not include necessary processes to describe digester dynamics under the conditions of oxygen presence. Limited oxygenation in anaerobic digestion can sometimes be beneficial. The oxygen effects included anaerobic digestion model, ADM 1-Ox, was simulated against experimental data obtained from laboratory scale anaerobic digesters operated under different oxygenation conditions. ADM 1-Ox predictions are generally in good agreement with the trends of the experimental data.

PDF PDF (1392 Kb)        DOI: 10.4173/mic.2010.2.2

DOI forward links to this article:
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References:
[1] Batstone, D.J., Keller, J., Angelidaki, I., Kalyuzhnyi, S., Pavlostathis, S.G., Rozzi, A., Sanders, W., Siegrist, H., Vavilin, V. (2002). Anaerobic digestion Model No, 1. IWA publishing.
[2] Botheju, D., Lie, B., Bakke, R. (2009). Oxygen effects in anaerobic digestion, Modeling, Identification and Control, 3.4:191--201 doi:10.4173/mic.2009.4.1
[3] Botheju, D., Samarakoon, G., Chen, C., Bakke, R. (2010). An experimental study on the effects of oxygen in bio-gasification; part 1, In Proceedings of the International Conference on Renewable Energies and Power Quality (ICREPQ 10), Granada (Spain), 23-25 March.
[4] Botheju, D., Samarakoon, G., Chen, C., Bakke, R. (2010). An experimental study on the effects of oxygen in bio-gasification; part 2, In Proceedings of the International Conference on Renewable Energies and Power Quality (ICREPQ 10), Granada (Spain), 23-25 March.
[5] Johansen, J.E. Bakke, R. (2006). Enhancing hydrolysis with microaeration, Water science and Technology, 5.8:43 -- 50 doi:10.2166/wst.2006.234
[6] Polanco, M.F., Diaz, I., Pérez, S.I., Lopes, A.C., Polanco, F.F. (2009). Hydrogen sulphide removal in the anaerobic digestion of sludge by micro-aerobic processes: pilot plant experience, Water Science and Technology, 6.12:3045 -- 3050 doi:10.2166/wst.2009.738


BibTeX:
@article{MIC-2010-2-2,
  title={{Oxygen Effects in Anaerobic Digestion - II}},
  author={Botheju, Deshai and Lie, Bernt and Bakke, Rune},
  journal={Modeling, Identification and Control},
  volume={31},
  number={2},
  pages={55--65},
  year={2010},
  doi={10.4173/mic.2010.2.2},
  publisher={Norwegian Society of Automatic Control}
};