Journal
WATER SCIENCE AND TECHNOLOGY
Volume 87, Issue 8, Pages 1945-1960Publisher
IWA PUBLISHING
DOI: 10.2166/wst.2023.096
Keywords
computational fluid dynamics; flocculation; geometry structures; operational conditions; phosphorus removal
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This study aims to numerically investigate the inner states and overall performance of industrial-scale mechanical flocculators in series. The effects of the number and locations of flocculation chambers, sizes of the flocculation chamber connection, and operational combinations of impeller speeds are studied. With a decreasing number of flocculation chambers, the main vortexes and chemical reactions weaken, while small flocs form. The connection location of flocculation chambers directly determines the turbulent flow, thus influencing the key performance indicators.
A mechanical flocculation system with multi-chambers in series is commonly used as the advanced phosphorus removal technology for wastewater treatment. This work aims to numerically investigate the inner states and overall performance of industrial-scale mechanical flocculators in series. This is based on our previously developed computational fluid dynamics (CFD) flocculation model which is extended to consider the key chemical reactions of phosphorus removal. The effects of the number of flocculation chambers, locations, and sizes of the flocculation chamber connection as well as operational combinations of impeller speeds are investigated. With a decreasing number of flocculation chambers, the main vortexes and chemical reactions are weakened, while the small flocs form. Both the phosphorus removal efficiency ? and the average floc size d(p) reduce as the number of flocculation chambers decreases. The connection location of flocculation chambers directly determines the turbulent flow, thus influencing the key performance indicators. However, the phosphorus removal efficiency ? and average particle size d(p) are little affected by the size of the flocculation chamber connection. As the impeller speeds in series gradually increase, the gradient of floc size distribution in each chamber is enlarged and the chemical reaction is enhanced over the working volume. It provides a deeper understanding of control, design, and optimization in the scaling-up of the coagulation-flocculation process.
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