Modelling aerobic biodegradation in vertical flow sand filters: Impact of operational considerations on oxygen transfer and bacterial activity
- 作者:A. Petitjeana ; alain.petitjean@irstea.fr ; julien.laurent@engees.unistra.fr ; N. Forquetb ; nicolas.forquet@irstea.fr ; A. Wankoa ; J. Laurenta ; P. Molleb ; R. Mosé ; a ; A. Sadowskia
- 关键词:Vertical Flow Constructed Wetland ; Modelling ; Oxygen transfer ; Diphasic flow ; Bacterial kinetics
- 刊名:Water Research
- 出版年:2012
- 期刊代码:57_00431354
- 类别:civ
- 出版时间:1 May, 2012
- 卷:46
- 期:7
- 页码:2270-2280
- 文件大小:866 K
摘要
Oxygen renewal, as a prominent phenomenon for aerobic bacterial activity, deeply impacts Vertical Flow Constructed Wetland (VFCW) treatment efficiency. We introduce a multiphase model able to simulate multi-component transfer in VFCWs. It is based on a two-phase flow module, and a transport module. The flow module can quantify both water and air velocities throughout the filter during operation. The reactive transport module follows dissolved and gaseous oxygen concentrations, and the transport of solutes such as ammonium and readily biodegradable COD (Chemical Oxygen Demand). The consumption of components is governed by Monod-type kinetics. Heterotrophic and autotrophic bacteria, which are responsible for COD and ammonium degradation respectively, are part of the model components. The kinetics are based on the Constructed Wetlands Model 1. The results from the simulation tool were compared with existing experimental data, and two kinds of operation with VFCWs were investigated.
The authors show strong interplay between oxygen renewal and bacterial consumption in case of sequential batch feeding with transient flooding of surface. Oxygen renewal is essentially convection mediated in such operation, while convection is not significant in non-flooding operation. Simulated bacterial patterns are impacted by the operation, both quantitatively and spatially. From a modelling point of view, the authors highlight some limitations of the biological model: the description of bacterial lysis processes needs to be enhanced, as well as ammonium adsorption to organic matter.