Modeling Orthokinetic Coagulation in Spatially Varying Laminar Flow

An orthokinetic coagulation model including the effects of agglomeration and local stress-induced aggregate breakup was developed. This model was used to simulate coagulation in the flow between two eccentrically located and rotating cylinders. Four methods of modeling coagulation in the flow system...

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Veröffentlicht in:	Journal of colloid and interface science 2000-07, Vol.227 (2), p.251-261
Hauptverfasser:	Kramer, Timothy A., Clark, Mark M.
Format:	Artikel
Sprache:	eng
Schlagworte:	Chemistry coagulation coagulation modeling Colloidal state and disperse state Exact sciences and technology flocculation General and physical chemistry Physical and chemical studies. Granulometry. Electrokinetic phenomena spatially varying flow
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container_title	Journal of colloid and interface science
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creator	Kramer, Timothy A. Clark, Mark M.
description	An orthokinetic coagulation model including the effects of agglomeration and local stress-induced aggregate breakup was developed. This model was used to simulate coagulation in the flow between two eccentrically located and rotating cylinders. Four methods of modeling coagulation in the flow system were examined. The first technique used a volume-weighted average of the local strain rates, while a second method used an equivalent volume-weighted power (G). A third method treated each volume element as a separate batch reactor and determined a final volume-averaged floc population. The final modeling technique applied mass transfer between each of the elements. Results indicated that substantial differences in average particle diameters and populations were generated with each of the methods, especially where mass transfer between the elements was considered. It was concluded that mass transfer between regions of varying flow strain rate and/or velocity gradient should be included in accurate coagulation modeling.
doi_str_mv	10.1006/jcis.2000.6829
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This model was used to simulate coagulation in the flow between two eccentrically located and rotating cylinders. Four methods of modeling coagulation in the flow system were examined. The first technique used a volume-weighted average of the local strain rates, while a second method used an equivalent volume-weighted power (G). A third method treated each volume element as a separate batch reactor and determined a final volume-averaged floc population. The final modeling technique applied mass transfer between each of the elements. Results indicated that substantial differences in average particle diameters and populations were generated with each of the methods, especially where mass transfer between the elements was considered. 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This model was used to simulate coagulation in the flow between two eccentrically located and rotating cylinders. Four methods of modeling coagulation in the flow system were examined. The first technique used a volume-weighted average of the local strain rates, while a second method used an equivalent volume-weighted power (G). A third method treated each volume element as a separate batch reactor and determined a final volume-averaged floc population. The final modeling technique applied mass transfer between each of the elements. Results indicated that substantial differences in average particle diameters and populations were generated with each of the methods, especially where mass transfer between the elements was considered. It was concluded that mass transfer between regions of varying flow strain rate and/or velocity gradient should be included in accurate coagulation modeling.</description><subject>Chemistry</subject><subject>coagulation</subject><subject>coagulation modeling</subject><subject>Colloidal state and disperse state</subject><subject>Exact sciences and technology</subject><subject>flocculation</subject><subject>General and physical chemistry</subject><subject>Physical and chemical studies. Granulometry. 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subjects	Chemistry coagulation coagulation modeling Colloidal state and disperse state Exact sciences and technology flocculation General and physical chemistry Physical and chemical studies. Granulometry. Electrokinetic phenomena spatially varying flow
title	Modeling Orthokinetic Coagulation in Spatially Varying Laminar Flow
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