Characterizing Mechanisms of Simultaneous Biological Nutrient Removal During Wastewater Treatment Contributor(s): Strom, P. F. (Author), Littleton, H. X. (Author) |
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ISBN: 1843397056 ISBN-13: 9781843397052 Publisher: Water Environment Research Foundation OUR PRICE: $159.60 Product Type: Paperback - Other Formats Published: July 2004 * Not available - Not in print at this time * |
Additional Information |
BISAC Categories: - Science | Environmental Science (see Also Chemistry - Environmental) - Technology & Engineering | Environmental - General - Science | Applied Sciences |
Dewey: 628.35 |
LCCN: 2003115459 |
Series: Werf Research Report |
Physical Information: 0.22" H x 8.25" W x 11" (0.56 lbs) 102 pages |
Descriptions, Reviews, Etc. |
Publisher Description: Simultaneous biological nutrient removal (SBNR) is the removal of nitrogen and/or phosphorus in excess of that required for biomass synthesis in biological wastewater treatment systems where there are no defined anaerobic and/or anoxic zones. The hypothesis is that one or more of three mechanisms is responsible within individual systems: variations in the bioreactor macroenvironment created by the mixing pattern, gradients within the floc microenvironment, and/or novel microorganism activity. Understanding of the mechanisms of SBNR can be expected to lead to improved efficiency and reliability in its application. Preliminary work documented SBNR in 7 full-scale OrbalTM closed loop bioreactors. A batch assay demonstrated that novel microorganism activity was of little importance in SBNR at the three plants tested. While the floc microenvironment likely plays an important role in nitrogen removal in such plants, it cannot explain phosphorus removal. A computational fluid dynamics (CFD) model was developed to elucidate the role of the bioreactor macroenvironment in SBNR. This is the first reported application of CFD to activated sludge biological wastewater treatment. Although the software and computational requirements limited model complexity, it still simulated the creation of dissolved oxygen gradients within the system, demonstrating that the anaerobic zones required for SBNR could occur. |