SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2058967325> ?p ?o ?g. }

Showing items 1 to 100 of ±115 with 100 items per page.

W2058967325 endingPage "844" @default.
W2058967325 startingPage "831" @default.
W2058967325 abstract "Single phase flows in stirred tanks have been extensively characterized using different experimental techniques like Hot Wire Anemometry1, Laser Doppler Anemometry2, and Digital Particle Imaging Velocimetry3. None of these techniques however, show much promise for the interrogation of opaque multiphase flows. Hence, little or no information of the local fluid dynamics of multiphase flows in stirred tanks is available. Non-optical techniques like Computer Automated Radioactive Particle Tracking (CARPT) and Computed Tomography (CT) have been successfully applied to probe a variety of multiphase reactors4–5 such as bubble columns6–7, risers8 etc., over a range of dispersed phase holdups. CARPT provides the local fluid dynamic information such as velocities and the turbulence parameters throughout the system that is investigated. CT provides time averaged local dispersed phase holdup profiles in various planes of the entire reactor. In this study, it is proposed to extend these techniques to characterize gas-liquid flows in stirred tank reactors. As a first step, CARPT is implemented in characterization of single phase flows in stirred tanks. CARPT experiments have been performed with water at 150 rpm in a 0.20m cylindrical tank quipped with a six bladed Rushton turbine (0.067m dia) conforming to the standard Holland and Chapman9 configuration. The CARPT technique is shown to capture some of the important flow phenomena observed in such flows, like the two recirculating loops above and below the impeller and the dead zones at the bottom of the tank. Radial pumping numbers determined by CARPT (0.67 near the impeller tip) compare reasonably well with data reported in the literature. Comparison of the complete three dimensional mean velocity profiles from CARPT with similar PIV, LDA and other data reported in the literature reveals that CARPT captures the right order of magnitude of the radial and the tangential velocities. Comparisons of the fluctuating velocity components, like the root mean squared (rms) velocity and the turbulent kinetic energy, suggest that the CARPT experiments were limited by large tracer particle size (dp = 2.3 mm) from sampling the high frequency fluctuations of the fluid. In addition, the three dimensional profiles of the components of the Reynolds stress tensor are measured. The detailed comparisons, even with the large tracer particle, indicate that CARPT measurements capture all the important qualitative features of the flow and quantitatively capture the right order of magnitude of the mean flow parameters. The quantitative comparisons suggest that the current size of the tracer particle restricts it from responding completely to the fluid phase fluctuations. Some Lagrangian measures of the fluid dynamics like the ‘Sojourn’ time distributions (STDs) in different zones of the reactor, Circulation Time Distributions (CTDs), Particle Return Maps to specific planes, Poincarre sections and Hurst exponents are evaluated from the collected CARPT data." @default.
W2058967325 created "2016-06-24" @default.
W2058967325 creator A5011870890 @default.
W2058967325 creator A5049094092 @default.
W2058967325 creator A5059448682 @default.
W2058967325 creator A5087985247 @default.
W2058967325 date "2001-11-01" @default.
W2058967325 modified "2023-10-16" @default.
W2058967325 title "Characterization of Single Phase Flows in Stirred Tanks via Computer Automated Radioactive Particle Tracking (CARPT)" @default.
W2058967325 cites W1982830259 @default.
W2058967325 cites W1984607804 @default.
W2058967325 cites W1994721614 @default.
W2058967325 cites W2002303224 @default.
W2058967325 cites W2006687898 @default.
W2058967325 cites W2015714729 @default.
W2058967325 cites W2020592851 @default.
W2058967325 cites W2028684094 @default.
W2058967325 cites W2038403865 @default.
W2058967325 cites W2045657353 @default.
W2058967325 cites W2050413442 @default.
W2058967325 cites W2052734200 @default.
W2058967325 cites W2054674045 @default.
W2058967325 cites W2071983932 @default.
W2058967325 cites W2073750108 @default.
W2058967325 cites W2076516855 @default.
W2058967325 cites W2085663159 @default.
W2058967325 cites W2087971682 @default.
W2058967325 cites W2088921160 @default.
W2058967325 cites W2091387896 @default.
W2058967325 cites W2125488849 @default.
W2058967325 cites W2152267869 @default.
W2058967325 cites W2155658877 @default.
W2058967325 cites W2164803679 @default.
W2058967325 doi "https://doi.org/10.1205/02638760152721343" @default.
W2058967325 hasPublicationYear "2001" @default.
W2058967325 type Work @default.
W2058967325 sameAs 2058967325 @default.
W2058967325 citedByCount "24" @default.
W2058967325 countsByYear W20589673252012 @default.
W2058967325 countsByYear W20589673252013 @default.
W2058967325 countsByYear W20589673252014 @default.
W2058967325 countsByYear W20589673252016 @default.
W2058967325 countsByYear W20589673252017 @default.
W2058967325 countsByYear W20589673252018 @default.
W2058967325 countsByYear W20589673252021 @default.
W2058967325 countsByYear W20589673252022 @default.
W2058967325 countsByYear W20589673252023 @default.
W2058967325 crossrefType "journal-article" @default.
W2058967325 hasAuthorship W2058967325A5011870890 @default.
W2058967325 hasAuthorship W2058967325A5049094092 @default.
W2058967325 hasAuthorship W2058967325A5059448682 @default.
W2058967325 hasAuthorship W2058967325A5087985247 @default.
W2058967325 hasConcept C111368507 @default.
W2058967325 hasConcept C121332964 @default.
W2058967325 hasConcept C127313418 @default.
W2058967325 hasConcept C138777275 @default.
W2058967325 hasConcept C153005164 @default.
W2058967325 hasConcept C15744967 @default.
W2058967325 hasConcept C157915830 @default.
W2058967325 hasConcept C1633027 @default.
W2058967325 hasConcept C177274176 @default.
W2058967325 hasConcept C192562407 @default.
W2058967325 hasConcept C19417346 @default.
W2058967325 hasConcept C196558001 @default.
W2058967325 hasConcept C207857233 @default.
W2058967325 hasConcept C2775936607 @default.
W2058967325 hasConcept C2778517922 @default.
W2058967325 hasConcept C2778912791 @default.
W2058967325 hasConcept C2779379648 @default.
W2058967325 hasConcept C38349280 @default.
W2058967325 hasConcept C44280652 @default.
W2058967325 hasConcept C57879066 @default.
W2058967325 hasConcept C62520636 @default.
W2058967325 hasConceptScore W2058967325C111368507 @default.
W2058967325 hasConceptScore W2058967325C121332964 @default.
W2058967325 hasConceptScore W2058967325C127313418 @default.
W2058967325 hasConceptScore W2058967325C138777275 @default.
W2058967325 hasConceptScore W2058967325C153005164 @default.
W2058967325 hasConceptScore W2058967325C15744967 @default.
W2058967325 hasConceptScore W2058967325C157915830 @default.
W2058967325 hasConceptScore W2058967325C1633027 @default.
W2058967325 hasConceptScore W2058967325C177274176 @default.
W2058967325 hasConceptScore W2058967325C192562407 @default.
W2058967325 hasConceptScore W2058967325C19417346 @default.
W2058967325 hasConceptScore W2058967325C196558001 @default.
W2058967325 hasConceptScore W2058967325C207857233 @default.
W2058967325 hasConceptScore W2058967325C2775936607 @default.
W2058967325 hasConceptScore W2058967325C2778517922 @default.
W2058967325 hasConceptScore W2058967325C2778912791 @default.
W2058967325 hasConceptScore W2058967325C2779379648 @default.
W2058967325 hasConceptScore W2058967325C38349280 @default.
W2058967325 hasConceptScore W2058967325C44280652 @default.
W2058967325 hasConceptScore W2058967325C57879066 @default.
W2058967325 hasConceptScore W2058967325C62520636 @default.
W2058967325 hasIssue "8" @default.
W2058967325 hasLocation W20589673251 @default.
W2058967325 hasOpenAccess W2058967325 @default.
W2058967325 hasPrimaryLocation W20589673251 @default.