Wastewater Engineering: Treatment and Resource Recovery
5th EditionISBN10: 0073401188
ISBN13: 9780073401188
Copyright: 2014
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ISBN10: 0073401188 | ISBN13: 9780073401188
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The estimated amount of time this product will be on the market is based on a number of factors, including faculty input to instructional design and the prior revision cycle and updates to academic research-which typically results in a revision cycle ranging from every two to four years for this product. Pricing subject to change at any time.
The estimated amount of time this product will be on the market is based on a number of factors, including faculty input to instructional design and the prior revision cycle and updates to academic research-which typically results in a revision cycle ranging from every two to four years for this product. Pricing subject to change at any time.
Program Details
1. Introduction to Wastewater Treatment and Process Analysis
2. Wastewater Characteristics
3. Wastewater Flowrates and Constituent Loadings
4. Wastewater Treatment Process Selection, Design, and Implementation
5. Physical Unit Operations
6. Chemical Unit Processes
7. Fundamentals of Biological Treatment
8. Suspended Growth Biological Treatment Processes
9. Attached Growth and Combined Biological Treatment Processes
10. Anaerobic Suspended and Attached Growth Biological Treatment Processes
11. Separation Processes for Removal of Residual Constituents
12. Disinfection Processes
13. Processing and Treatment of Sludges
14. Biosolids Processing, Resource Recovery and Beneficial Use
15. Plant Recycle Flow Treatment and Nutrient Recovery
16. Air Emissions from Wastewater Treatment Facilities and Their Control
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
3. Wastewater Flowrates and Constituent Loadings
4. Wastewater Treatment Process Selection, Design, and Implementation
5. Physical Unit Operations
6. Chemical Unit Processes
7. Fundamentals of Biological Treatment
8. Suspended Growth Biological Treatment Processes
9. Attached Growth and Combined Biological Treatment Processes
10. Anaerobic Suspended and Attached Growth Biological Treatment Processes
11. Separation Processes for Removal of Residual Constituents
12. Disinfection Processes
13. Processing and Treatment of Sludges
14. Biosolids Processing, Resource Recovery and Beneficial Use
15. Plant Recycle Flow Treatment and Nutrient Recovery
16. Air Emissions from Wastewater Treatment Facilities and Their Control
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
5. Physical Unit Operations
6. Chemical Unit Processes
7. Fundamentals of Biological Treatment
8. Suspended Growth Biological Treatment Processes
9. Attached Growth and Combined Biological Treatment Processes
10. Anaerobic Suspended and Attached Growth Biological Treatment Processes
11. Separation Processes for Removal of Residual Constituents
12. Disinfection Processes
13. Processing and Treatment of Sludges
14. Biosolids Processing, Resource Recovery and Beneficial Use
15. Plant Recycle Flow Treatment and Nutrient Recovery
16. Air Emissions from Wastewater Treatment Facilities and Their Control
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
7. Fundamentals of Biological Treatment
8. Suspended Growth Biological Treatment Processes
9. Attached Growth and Combined Biological Treatment Processes
10. Anaerobic Suspended and Attached Growth Biological Treatment Processes
11. Separation Processes for Removal of Residual Constituents
12. Disinfection Processes
13. Processing and Treatment of Sludges
14. Biosolids Processing, Resource Recovery and Beneficial Use
15. Plant Recycle Flow Treatment and Nutrient Recovery
16. Air Emissions from Wastewater Treatment Facilities and Their Control
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
9. Attached Growth and Combined Biological Treatment Processes
10. Anaerobic Suspended and Attached Growth Biological Treatment Processes
11. Separation Processes for Removal of Residual Constituents
12. Disinfection Processes
13. Processing and Treatment of Sludges
14. Biosolids Processing, Resource Recovery and Beneficial Use
15. Plant Recycle Flow Treatment and Nutrient Recovery
16. Air Emissions from Wastewater Treatment Facilities and Their Control
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
11. Separation Processes for Removal of Residual Constituents
12. Disinfection Processes
13. Processing and Treatment of Sludges
14. Biosolids Processing, Resource Recovery and Beneficial Use
15. Plant Recycle Flow Treatment and Nutrient Recovery
16. Air Emissions from Wastewater Treatment Facilities and Their Control
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
13. Processing and Treatment of Sludges
14. Biosolids Processing, Resource Recovery and Beneficial Use
15. Plant Recycle Flow Treatment and Nutrient Recovery
16. Air Emissions from Wastewater Treatment Facilities and Their Control
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
15. Plant Recycle Flow Treatment and Nutrient Recovery
16. Air Emissions from Wastewater Treatment Facilities and Their Control
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
1. Introduction to Wastewater Treatment and Process Analysis
2. Wastewater Characteristics
3. Wastewater Flowrates and Constituent Loadings
4. Wastewater Treatment Process Selection, Design, and Implementation
5. Physical Unit Operations
6. Chemical Unit Processes
7. Fundamentals of Biological Treatment
8. Suspended Growth Biological Treatment Processes
9. Attached Growth and Combined Biological Treatment Processes
10. Anaerobic Suspended and Attached Growth Biological Treatment Processes
11. Separation Processes for Removal of Residual Constituents
12. Disinfection Processes
13. Processing and Treatment of Sludges
14. Biosolids Processing, Resource Recovery and Beneficial Use
15. Plant Recycle Flow Treatment and Nutrient Recovery
16. Air Emissions from Wastewater Treatment Facilities and Their Control
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
3. Wastewater Flowrates and Constituent Loadings
4. Wastewater Treatment Process Selection, Design, and Implementation
5. Physical Unit Operations
6. Chemical Unit Processes
7. Fundamentals of Biological Treatment
8. Suspended Growth Biological Treatment Processes
9. Attached Growth and Combined Biological Treatment Processes
10. Anaerobic Suspended and Attached Growth Biological Treatment Processes
11. Separation Processes for Removal of Residual Constituents
12. Disinfection Processes
13. Processing and Treatment of Sludges
14. Biosolids Processing, Resource Recovery and Beneficial Use
15. Plant Recycle Flow Treatment and Nutrient Recovery
16. Air Emissions from Wastewater Treatment Facilities and Their Control
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
5. Physical Unit Operations
6. Chemical Unit Processes
7. Fundamentals of Biological Treatment
8. Suspended Growth Biological Treatment Processes
9. Attached Growth and Combined Biological Treatment Processes
10. Anaerobic Suspended and Attached Growth Biological Treatment Processes
11. Separation Processes for Removal of Residual Constituents
12. Disinfection Processes
13. Processing and Treatment of Sludges
14. Biosolids Processing, Resource Recovery and Beneficial Use
15. Plant Recycle Flow Treatment and Nutrient Recovery
16. Air Emissions from Wastewater Treatment Facilities and Their Control
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
7. Fundamentals of Biological Treatment
8. Suspended Growth Biological Treatment Processes
9. Attached Growth and Combined Biological Treatment Processes
10. Anaerobic Suspended and Attached Growth Biological Treatment Processes
11. Separation Processes for Removal of Residual Constituents
12. Disinfection Processes
13. Processing and Treatment of Sludges
14. Biosolids Processing, Resource Recovery and Beneficial Use
15. Plant Recycle Flow Treatment and Nutrient Recovery
16. Air Emissions from Wastewater Treatment Facilities and Their Control
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
9. Attached Growth and Combined Biological Treatment Processes
10. Anaerobic Suspended and Attached Growth Biological Treatment Processes
11. Separation Processes for Removal of Residual Constituents
12. Disinfection Processes
13. Processing and Treatment of Sludges
14. Biosolids Processing, Resource Recovery and Beneficial Use
15. Plant Recycle Flow Treatment and Nutrient Recovery
16. Air Emissions from Wastewater Treatment Facilities and Their Control
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
11. Separation Processes for Removal of Residual Constituents
12. Disinfection Processes
13. Processing and Treatment of Sludges
14. Biosolids Processing, Resource Recovery and Beneficial Use
15. Plant Recycle Flow Treatment and Nutrient Recovery
16. Air Emissions from Wastewater Treatment Facilities and Their Control
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
13. Processing and Treatment of Sludges
14. Biosolids Processing, Resource Recovery and Beneficial Use
15. Plant Recycle Flow Treatment and Nutrient Recovery
16. Air Emissions from Wastewater Treatment Facilities and Their Control
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
15. Plant Recycle Flow Treatment and Nutrient Recovery
16. Air Emissions from Wastewater Treatment Facilities and Their Control
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
17. Energy Considerations in Wastewater Management
18. Wastewater Management: Future Challenges and Opportunties
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
Appendixes
A Conversion Factors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
B Physical Properties of Selected Gases and the Composition of Air
C Physical Properties of Water
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
D Statistical Analysis of Data
E Dissolved Oxygen Concentration in Water as a Function of Temperature, Salinity and Barometric Pressure
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
F Carbonate Equilibrium
G Moody Diagrams for the Analysis of Flow in Pipes
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
H Analysis of Nonideal Flow in Reactors Using Tracers
I Modeling Nonideal Flow in Reactors
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