Biofouling in spiral wound membrane systems: Three-dimensional CFD model based evaluation of experimental data
暂无分享,去创建一个
Johannes S. Vrouwenvelder | Cristian Picioreanu | M. Loosdrecht | C. Picioreanu | J. Kruithof | J. Vrouwenvelder | M.C.M. van Loosdrecht | Joop C. Kruithof
[1] Dianne E. Wiley,et al. CFD simulations of net-type turbulence promoters in a narrow channel , 2001 .
[2] Viriato Semiao,et al. Flow management in nanofiltration spiral wound modules with ladder-type spacers , 2002 .
[3] Sandeep K. Karode,et al. Flow visualization through spacer filled channels by computational fluid dynamics I. , 2001 .
[4] Cristian Picioreanu,et al. Constrained discounted Markov decision processes and Hamiltonian cycles , 1997, Proceedings of the 36th IEEE Conference on Decision and Control.
[5] Keith Scott,et al. Model based evaluation of the effect of pH and electrode geometry on microbial fuel cell performance. , 2010, Bioelectrochemistry.
[6] M. Elimelech,et al. Biofouling of reverse osmosis membranes: Role of biofilm-enhanced osmotic pressure , 2007 .
[7] Robert W. Field,et al. Critical and sustainable fluxes: Theory, experiments and applications , 2006 .
[8] P. Callaghan. Principles of Nuclear Magnetic Resonance Microscopy , 1991 .
[9] Alkiviades C. Payatakes,et al. Hierarchical simulator of biofilm growth and dynamics in granular porous materials , 2007 .
[10] J J Heijnen,et al. Two-dimensional model of biofilm detachment caused by internal stress from liquid flow. , 2001, Biotechnology and bioengineering.
[11] R. Schneider,et al. Dynamics of organic carbon and of bacterial populations in a conventional pretreatment train of a reverse osmosis unit experiencing severe biofouling , 2005 .
[12] Vivek V. Ranade,et al. Comparison of flow structures in spacer-filled flat and annular channels⁎ , 2006 .
[13] M. V. van Loosdrecht,et al. Molecular Characterization of the Bacterial Communities in the Different Compartments of a Full-Scale Reverse-Osmosis Water Purification Plant , 2008, Applied and Environmental Microbiology.
[14] O. Holm‐Hansen,et al. THE MEASUREMENT OF ADENOSINE TRIPHOSPHATE IN THE OCEAN AND ITS ECOLOGICAL SIGNIFICANCE1 , 1966 .
[15] A. B. de Haan,et al. Optimization of commercial net spacers in spiral wound membrane modules , 2002 .
[16] S. G. Yiantsios,et al. A numerical and experimental study of mass transfer in spacer-filled channels: Effects of spacer geometrical characteristics and Schmidt number , 2009 .
[17] B. Hamrouni,et al. RO membrane autopsy of Zarzis brackish water desalination plant , 2008 .
[18] Howland D. T. Jones,et al. Analysis of micromixers to reduce biofouling on reverse‐osmosis membranes , 2008 .
[19] J.L.C. Santos,et al. Investigation of flow patterns and mass transfer in membrane module channels filled with flow-aligned spacers using computational fluid dynamics (CFD) , 2007 .
[20] B. Gros,et al. Membrane mass transport modeling with the periodic boundary condition , 2009, Computers and Chemical Engineering.
[21] Albert S Kim,et al. EPS biofouling in membrane filtration: an analytic modeling study. , 2006, Journal of colloid and interface science.
[22] M. V. van Loosdrecht,et al. The membrane fouling simulator: a suitable tool for prediction and characterisation of membrane fouling. , 2007, Water science and technology : a journal of the International Association on Water Pollution Research.
[23] W. Casey,et al. New generation of low fouling nanofiltration membranes , 2008 .
[24] Kuo-Lun Tung,et al. Mitigating the curvature effect of the spacer-filled channel in a spiral-wound membrane module , 2009 .
[25] M. Loosdrecht,et al. A critical flux to avoid biofouling of spiral wound nanofiltration and reverse osmosis membranes: Fact or fiction? , 2009 .
[26] Kuo-Lun Tung,et al. CFD simulation of fluid flow through spacer-filled membrane module : selecting suitable cell types for periodic boundary conditions , 2008 .
[27] J. Howell,et al. Sub-critical flux operation of microfiltration , 1995 .
[28] J. Georgiadis,et al. Science and technology for water purification in the coming decades , 2008, Nature.
[29] M. V. van Loosdrecht,et al. Pressure drop increase by biofilm accumulation in spiral wound RO and NF membrane systems: role of substrate concentration, flow velocity, substrate load and flow direction , 2009, Biofouling.
[30] Johannes S. Vrouwenvelder,et al. Three-dimensional modeling of biofouling and fluid dynamics in feed spacer channels of membrane devices , 2009 .
[31] William B. Suratt,et al. Biofouling of PVD-1 reverse osmosis elements in the water treatment plant of the City of Dunedin, Florida , 1995 .
[32] Johannes S. Vrouwenvelder,et al. Nuclear magnetic resonance microscopy studies of membrane biofouling , 2008 .
[33] David F. Fletcher,et al. Spiral wound modules and spacers - Review and analysis , 2004 .
[34] S. G. Yiantsios,et al. Numerical simulation of the flow in a plane-channel containing a periodic array of cylindrical turbulence promoters , 2004 .
[35] David F. Fletcher,et al. Simulation of the Flow around Spacer Filaments between Narrow Channel Walls. 1. Hydrodynamics , 2002 .
[36] Grietje Zeeman,et al. The role of anaerobic digestion of domestic sewage in closing the water and nutrient cycle at community level , 1999 .
[37] J. J. Heijnen,et al. A three-dimensional numerical study on the correlation of spatial structure, hydrodynamic conditions, and mass transfer and conversion in biofilms , 2000 .
[38] L. Y. Dudley,et al. Biofouling in membrane systems — A review☆ , 1998 .
[39] Wen-Tso Liu,et al. Biofilm formation characteristics of bacterial isolates retrieved from a reverse osmosis membrane. , 2005, Environmental science & technology.
[40] M. Shakaib,et al. Study on the effects of spacer geometry in membrane feed channels using three-dimensional computational flow modeling , 2007 .
[41] F. Volke,et al. Measuring local flow velocities and biofilm structure in biofilm systems with Magnetic Resonance Imaging (MRI) , 2003, Biotechnology and bioengineering.
[42] J J Heijnen,et al. Mathematical modeling of biofilm structure with a hybrid differential-discrete cellular automaton approach. , 1998, Biotechnology and bioengineering.
[43] Y. Kamiyama,et al. Analysis of RO elements operated at more than 80 plants in Japan , 1994 .
[44] Satish Kumar,et al. Predicting the effect of membrane spacers on mass transfer , 2008 .
[45] M. V. van Loosdrecht,et al. Biofouling of spiral-wound nanofiltration and reverse osmosis membranes: a feed spacer problem. , 2009, Water research.
[46] H. Winters,et al. Twenty years experience in seawater reverse osmosis and how chemicals in pretreatment affect fouling of membranes , 1997 .
[47] J J Heijnen,et al. A theoretical study on the effect of surface roughness on mass transport and transformation in biofilms. , 2000, Biotechnology and bioengineering.
[48] Johannes S. Vrouwenvelder,et al. The Membrane Fouling Simulator: A practical tool for fouling prediction and control , 2006 .
[49] Pierre Aimar,et al. Model for colloidal fouling of membranes , 1995 .
[50] R. Field,et al. Critical flux concept for microfiltration fouling , 1995 .
[51] H. As,et al. 1H NMR characterisation of the diffusional properties of methanogenic granular sludge , 1999 .
[52] J. Hofman,et al. Biofouling of membranes for drinking water production , 1998 .
[53] David F. Fletcher,et al. Simulation of the Flow around Spacer Filaments between Channel Walls. 2. Mass-Transfer Enhancement , 2002 .
[54] M. Shakaib,et al. CFD modeling for flow and mass transfer in spacer-obstructed membrane feed channels , 2009 .
[55] M C M van Loosdrecht,et al. Quantitative biofouling diagnosis in full scale nanofiltration and reverse osmosis installations. , 2008, Water research.
[56] Johannes S. Vrouwenvelder,et al. Sensitive pressure drop measurements of individual lead membrane elements for accurate early biofouling detection , 2009 .
[57] Mei-Ling Chong,et al. Community structure of microbial biofilms associated with membrane-based water purification processes as revealed using a polyphasic approach , 2004, Applied Microbiology and Biotechnology.
[58] M. Elimelech,et al. Physiology and genetic traits of reverse osmosis membrane biofilms: a case study with Pseudomonas aeruginosa , 2008, The ISME Journal.
[59] Dianne E. Wiley,et al. Numerical study of mass transfer in three-dimensional spacer-filled narrow channels with steady flow , 2007 .
[60] Wen-Tso Liu,et al. Community structure analysis of reverse osmosis membrane biofilms and the significance of Rhizobiales bacteria in biofouling. , 2007, Environmental science & technology.
[61] Anthony G. Fane,et al. The effect of imposed flux on biofouling in reverse osmosis: Role of concentration polarisation and biofilm enhanced osmotic pressure phenomena , 2008 .
[62] S. G. Yiantsios,et al. Direct numerical simulation of flow in spacer-filled channels: Effect of spacer geometrical characteristics , 2007 .
[63] P. Lens,et al. Use of 1H NMR to study transport processes in porous biosystems , 2001, Journal of Industrial Microbiology and Biotechnology.
[64] M. Loosdrecht,et al. Three‐dimensional simulations of biofilm growth in porous media , 2009 .