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This revision contains a strong focus on advanced wastewater treatment technologies and stresses the reuse aspects of wastewater and biosolids.
Wastewater Engineering: Treatment and Resource Recovery
by Tchobanoglous, George; Stensel, H; Tsuchihashi, Ryujiro; Burton, Franklin LEdition: 5th
Format: Hardcover
Pub. Date: 2013-09-03
Publisher(s): McGraw Hill
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Summary
Wastewater Engineering: Treatment and Resource Recovery, 5/e is a thorough update of McGraw-Hill's authoritative book on wastewater treatment. No environmental engineering professional or civil or environmental engineering major should be without a copy of this book - describing the rapidly evolving field of wastewater engineering technological and regulatory changes that have occurred over the last ten years in this discipline, including: a new view of a wastewater as a source of energy, nutrients and potable water; more stringent discharge requirements related to nitrogen and phosphorus; enhanced understanding of the fundamental microbiology and physiology of the microorganisms responsible for the removel of nitrogen and phosphorus and other constituents; an appreciation of the importance of the separate treatment of return flows with respect to meeting more stringent standards for nitrogen removal and opportunities for nutrient recovery; increased emphasis on the treatment of sludge and the management of biosolids; increased awareness of carbon footprints impacts and greenhouse gas emissions, and an emphasis on the development of energy neutral or energy positive wastewater plants through more efficient use of chemical and heat energy in wastewater.
Table of Contents
1. Introduction to Wastewater Treatment and Process Analysis2. Wastewater Characteristics3. Wastewater Flowrates and Constituent Loadings4. Wastewater Treatment Process Selection, Design, and Implementation5. Physical Unit Operations6. Chemical Unit Processes7. Fundamentals of Biological Treatment8. Suspended Growth Biological Treatment Processes9. Attached Growth and Combined Biological Treatment Processes10. Anaerobic Suspended and Attached Growth Biological Treatment Processes11. Separation Processes for Removal of Residual Constituents12. Disinfection Processes13. Processing and Treatment of Sludges14. Biosolids Processing, Resource Recovery and Beneficial Use15. Plant Recycle Flow Treatment and Nutrient Recovery16. Air Emissions from Wastewater Treatment Facilities and Their Control17. Energy Considerations in Wastewater Management18. Wastewater Management: Future Challenges and OpportuntiesAppendixesA Conversion FactorsB Physical Properties of Selected Gases and the Composition of AirC Physical Properties of WaterD Statistical Analysis of DataE Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric PressureF Carbonate EquilibriumG Moody Diagrams for the Analysis of Flow in PipesH Analysis of Nonideal Flow in Reactors Using TracersI Modeling Nonideal Flow in Reactors
3. Wastewater Flowrates and Constituent Loadings4. Wastewater Treatment Process Selection, Design, and Implementation5. Physical Unit Operations6. Chemical Unit Processes7. Fundamentals of Biological Treatment8. Suspended Growth Biological Treatment Processes9. Attached Growth and Combined Biological Treatment Processes10. Anaerobic Suspended and Attached Growth Biological Treatment Processes11. Separation Processes for Removal of Residual Constituents12. Disinfection Processes13. Processing and Treatment of Sludges14. Biosolids Processing, Resource Recovery and Beneficial Use15. Plant Recycle Flow Treatment and Nutrient Recovery16. Air Emissions from Wastewater Treatment Facilities and Their Control17. Energy Considerations in Wastewater Management18. Wastewater Management: Future Challenges and OpportuntiesAppendixesA Conversion FactorsB Physical Properties of Selected Gases and the Composition of AirC Physical Properties of WaterD Statistical Analysis of DataE Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric PressureF Carbonate EquilibriumG Moody Diagrams for the Analysis of Flow in PipesH Analysis of Nonideal Flow in Reactors Using TracersI Modeling Nonideal Flow in Reactors
5. Physical Unit Operations6. Chemical Unit Processes7. Fundamentals of Biological Treatment8. Suspended Growth Biological Treatment Processes9. Attached Growth and Combined Biological Treatment Processes10. Anaerobic Suspended and Attached Growth Biological Treatment Processes11. Separation Processes for Removal of Residual Constituents12. Disinfection Processes13. Processing and Treatment of Sludges14. Biosolids Processing, Resource Recovery and Beneficial Use15. Plant Recycle Flow Treatment and Nutrient Recovery16. Air Emissions from Wastewater Treatment Facilities and Their Control17. Energy Considerations in Wastewater Management18. Wastewater Management: Future Challenges and OpportuntiesAppendixesA Conversion FactorsB Physical Properties of Selected Gases and the Composition of AirC Physical Properties of WaterD Statistical Analysis of DataE Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric PressureF Carbonate EquilibriumG Moody Diagrams for the Analysis of Flow in PipesH Analysis of Nonideal Flow in Reactors Using TracersI Modeling Nonideal Flow in Reactors
7. Fundamentals of Biological Treatment8. Suspended Growth Biological Treatment Processes9. Attached Growth and Combined Biological Treatment Processes10. Anaerobic Suspended and Attached Growth Biological Treatment Processes11. Separation Processes for Removal of Residual Constituents12. Disinfection Processes13. Processing and Treatment of Sludges14. Biosolids Processing, Resource Recovery and Beneficial Use15. Plant Recycle Flow Treatment and Nutrient Recovery16. Air Emissions from Wastewater Treatment Facilities and Their Control17. Energy Considerations in Wastewater Management18. Wastewater Management: Future Challenges and OpportuntiesAppendixesA Conversion FactorsB Physical Properties of Selected Gases and the Composition of AirC Physical Properties of WaterD Statistical Analysis of DataE Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric PressureF Carbonate EquilibriumG Moody Diagrams for the Analysis of Flow in PipesH Analysis of Nonideal Flow in Reactors Using TracersI Modeling Nonideal Flow in Reactors
9. Attached Growth and Combined Biological Treatment Processes10. Anaerobic Suspended and Attached Growth Biological Treatment Processes11. Separation Processes for Removal of Residual Constituents12. Disinfection Processes13. Processing and Treatment of Sludges14. Biosolids Processing, Resource Recovery and Beneficial Use15. Plant Recycle Flow Treatment and Nutrient Recovery16. Air Emissions from Wastewater Treatment Facilities and Their Control17. Energy Considerations in Wastewater Management18. Wastewater Management: Future Challenges and OpportuntiesAppendixesA Conversion FactorsB Physical Properties of Selected Gases and the Composition of AirC Physical Properties of WaterD Statistical Analysis of DataE Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric PressureF Carbonate EquilibriumG Moody Diagrams for the Analysis of Flow in PipesH Analysis of Nonideal Flow in Reactors Using TracersI Modeling Nonideal Flow in Reactors
11. Separation Processes for Removal of Residual Constituents12. Disinfection Processes13. Processing and Treatment of Sludges14. Biosolids Processing, Resource Recovery and Beneficial Use15. Plant Recycle Flow Treatment and Nutrient Recovery16. Air Emissions from Wastewater Treatment Facilities and Their Control17. Energy Considerations in Wastewater Management18. Wastewater Management: Future Challenges and OpportuntiesAppendixesA Conversion FactorsB Physical Properties of Selected Gases and the Composition of AirC Physical Properties of WaterD Statistical Analysis of DataE Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric PressureF Carbonate EquilibriumG Moody Diagrams for the Analysis of Flow in PipesH Analysis of Nonideal Flow in Reactors Using TracersI Modeling Nonideal Flow in Reactors
13. Processing and Treatment of Sludges14. Biosolids Processing, Resource Recovery and Beneficial Use15. Plant Recycle Flow Treatment and Nutrient Recovery16. Air Emissions from Wastewater Treatment Facilities and Their Control17. Energy Considerations in Wastewater Management18. Wastewater Management: Future Challenges and OpportuntiesAppendixesA Conversion FactorsB Physical Properties of Selected Gases and the Composition of AirC Physical Properties of WaterD Statistical Analysis of DataE Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric PressureF Carbonate EquilibriumG Moody Diagrams for the Analysis of Flow in PipesH Analysis of Nonideal Flow in Reactors Using TracersI Modeling Nonideal Flow in Reactors
15. Plant Recycle Flow Treatment and Nutrient Recovery16. Air Emissions from Wastewater Treatment Facilities and Their Control17. Energy Considerations in Wastewater Management18. Wastewater Management: Future Challenges and OpportuntiesAppendixesA Conversion FactorsB Physical Properties of Selected Gases and the Composition of AirC Physical Properties of WaterD Statistical Analysis of DataE Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric PressureF Carbonate EquilibriumG Moody Diagrams for the Analysis of Flow in PipesH Analysis of Nonideal Flow in Reactors Using TracersI Modeling Nonideal Flow in Reactors
17. Energy Considerations in Wastewater Management18. Wastewater Management: Future Challenges and OpportuntiesAppendixesA Conversion FactorsB Physical Properties of Selected Gases and the Composition of AirC Physical Properties of WaterD Statistical Analysis of DataE Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric PressureF Carbonate EquilibriumG Moody Diagrams for the Analysis of Flow in PipesH Analysis of Nonideal Flow in Reactors Using TracersI Modeling Nonideal Flow in Reactors
AppendixesA Conversion FactorsB Physical Properties of Selected Gases and the Composition of AirC Physical Properties of WaterD Statistical Analysis of DataE Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric PressureF Carbonate EquilibriumG Moody Diagrams for the Analysis of Flow in PipesH Analysis of Nonideal Flow in Reactors Using TracersI Modeling Nonideal Flow in Reactors
B Physical Properties of Selected Gases and the Composition of AirC Physical Properties of WaterD Statistical Analysis of DataE Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric PressureF Carbonate EquilibriumG Moody Diagrams for the Analysis of Flow in PipesH Analysis of Nonideal Flow in Reactors Using TracersI Modeling Nonideal Flow in Reactors
D Statistical Analysis of DataE Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric PressureF Carbonate EquilibriumG Moody Diagrams for the Analysis of Flow in PipesH Analysis of Nonideal Flow in Reactors Using TracersI Modeling Nonideal Flow in Reactors
F Carbonate EquilibriumG Moody Diagrams for the Analysis of Flow in PipesH Analysis of Nonideal Flow in Reactors Using TracersI Modeling Nonideal Flow in Reactors
H Analysis of Nonideal Flow in Reactors Using TracersI Modeling Nonideal Flow in Reactors
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