Fundamentals of Biological Wastewater TreatmentWiley, 2007 - 362 páginas This concise introduction to the fundamentals of biological treatment of wastewater describes how to model and integrate biological steps into industrial processes. The book first covers the chemical, physical and biological basics, including wastewater characteristics, microbial metabolism, determining stoichiometric equations for catabolism and anabolism, measurements of mass transfer and respiration rates and the aerobic treatment of wastewater loaded with dissolved organics. It the moves on to deal with such applications and technologies as nitrogen and phosphorus removal, membrane technology, the assessment and selection of aeration systems, simple models for biofilm reactors and the modeling of activated sludge processes. A final section looks at the processing of water and the treatment of wastewater integrated into the production process. Essential reading for chemists, engineers, microbiologists, environmental officers, agencies and consultants, in both academia and industry. |
Índice
Historical Development of Wastewater Collection and Treatment | 1 |
Wastewater Characterization and Regulations | 25 |
2 | 36 |
Página de créditos | |
Otras 16 secciones no se muestran.
Otras ediciones - Ver todo
Fundamentals of Biological Wastewater Treatment Udo Wiesmann,In Su Choi,Eva-Maria Dombrowski Vista previa restringida - 2007 |
Fundamentals of Biological Wastewater Treatment Udo Wiesmann,In Su Choi,Eva-Maria Dombrowski No hay ninguna vista previa disponible - 2007 |
Fundamentals of Biological Wastewater Treatment Udo Wiesmann,In Su Choi,Eva-Maria Dombrowski No hay ninguna vista previa disponible - 2007 |
Términos y frases comunes
acetate activated sludge aeration aerobic aerobic zone amino acids ammonium anaerobic anoxic autotrophic azo dyes bacteria balance Berlin biodegradable biofilm biomass bubbles calculated carbon catabolism cell chemical Chemostat CO₂ completely mixed compounds consumption CSTR degradation denitrification diffusion dimensionless dissolved oxygen effluent energy enzymes equation flow rate g m³ g MLSS growth rate H₂ H₂O HCO3 heterotrophs hydrogen industry influence K₁ K₁a kinetics mass transfer mean retention measured membrane methanogenic mg L-¹ COD MLVSS molecule N₂ nitrate nitrification nitrifying bacteria Nitrobacter nitrogen O₂ obtain organic oxidation oxygen concentration oxygen transfer parameters phosphorus phosphorus removal production protein reaction reactor recycle reduced removal rate sludge age specific growth rate substrate surface Table tank temperature tion transfer rate trickling filter uptake Wiesmann WWTP yield coefficients Yx/s Yxc/sc µmax