Philadelphia Mixing Solutions Ltd, Palmyra, PA 17078, USA. bwu@philamixers.com
Bioresource technology 2011 AprA computational fluid dynamics (CFD) model that integrates physical and biological processes for anaerobic lagoons is presented. In the model development, turbulence is represented using a transition k-ω model, heat conduction and solar radiation are included in the thermal model, biological oxygen demand (BOD) reduction is characterized by first-order kinetics, and methane yield rate is expressed as a linear function of temperature. A test of the model applicability is conducted in a covered lagoon digester operated under tropical climate conditions. The commercial CFD software, ANSYS-Fluent, is employed to solve the integrated model. The simulation procedures include solving fluid flow and heat transfer, predicting local resident time based on the converged flow fields, and calculating the BOD reduction and methane production. The simulated results show that monthly methane production varies insignificantly, but the time to achieve a 99% BOD reduction in January is much longer than that in July. Copyright © 2011 Elsevier Ltd. All rights reserved.
Binxin Wu, Zhenbin Chen. An integrated physical and biological model for anaerobic lagoons. Bioresource technology. 2011 Apr;102(8):5032-8
PMID: 21339067
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