Experimental and computational investigation of mixing with contra-rotating, baffle-free impellers

© 2017 Institution of Chemical Engineers This work experimentally and numerically investigates the intersection of two fields: (1) single axis, contra-rotating impellers and (2) buoyancy of solid suspensions. The main goals of this study are to (1) create a working model to quantitatively understand...

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Main Authors: P. Satjaritanun, E. Bringley, J. R. Regalbuto, J. A. Regalbuto, J. Register, J. W. Weidner, Y. Khunatorn, S. Shimpalee
Format: Journal
Published: 2018
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http://cmuir.cmu.ac.th/jspui/handle/6653943832/58409
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Institution: Chiang Mai University
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spelling th-cmuir.6653943832-584092018-09-05T04:24:50Z Experimental and computational investigation of mixing with contra-rotating, baffle-free impellers P. Satjaritanun E. Bringley J. R. Regalbuto J. A. Regalbuto J. Register J. W. Weidner Y. Khunatorn S. Shimpalee Chemical Engineering Chemistry © 2017 Institution of Chemical Engineers This work experimentally and numerically investigates the intersection of two fields: (1) single axis, contra-rotating impellers and (2) buoyancy of solid suspensions. The main goals of this study are to (1) create a working model to quantitatively understand particle mixing, (2) characterize and compare contra-rotating single shaft impellers to single shaft co-rotating dual impellers, (3) improve quantification of particle mixing through image processing for both computational and experimental techniques, and (4) make design decisions with the computational analysis. Twelve cases were studied by changing the direction of impeller rotation, impeller pumping direction, and the presence of baffles. Particles with specific gravities (SG) of 0.866 and 1.050 were introduced into the experimental and computational systems in a finite and countable number. The numerical solution was obtained using the Lattice Boltzmann method and the Discrete Particle method. A commercial LBM solver, XFlow, was used for the simulation. The input torques and mixing efficiency with various flow configurations and specific gravities was used to find an optimal design. For the mixing of the lighter particles, the contra configuration with inward opposing flow gave optimal performance of highest mixing efficiency at lowest required torque. Co-rotating impellers with baffles gave the best performance of high mixing efficiency at lowest power input for the heavier particles. 2018-09-05T04:23:43Z 2018-09-05T04:23:43Z 2018-02-01 Journal 02638762 2-s2.0-85038423449 10.1016/j.cherd.2017.12.010 https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=85038423449&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/58409
institution Chiang Mai University
building Chiang Mai University Library
country Thailand
collection CMU Intellectual Repository
topic Chemical Engineering
Chemistry
spellingShingle Chemical Engineering
Chemistry
P. Satjaritanun
E. Bringley
J. R. Regalbuto
J. A. Regalbuto
J. Register
J. W. Weidner
Y. Khunatorn
S. Shimpalee
Experimental and computational investigation of mixing with contra-rotating, baffle-free impellers
description © 2017 Institution of Chemical Engineers This work experimentally and numerically investigates the intersection of two fields: (1) single axis, contra-rotating impellers and (2) buoyancy of solid suspensions. The main goals of this study are to (1) create a working model to quantitatively understand particle mixing, (2) characterize and compare contra-rotating single shaft impellers to single shaft co-rotating dual impellers, (3) improve quantification of particle mixing through image processing for both computational and experimental techniques, and (4) make design decisions with the computational analysis. Twelve cases were studied by changing the direction of impeller rotation, impeller pumping direction, and the presence of baffles. Particles with specific gravities (SG) of 0.866 and 1.050 were introduced into the experimental and computational systems in a finite and countable number. The numerical solution was obtained using the Lattice Boltzmann method and the Discrete Particle method. A commercial LBM solver, XFlow, was used for the simulation. The input torques and mixing efficiency with various flow configurations and specific gravities was used to find an optimal design. For the mixing of the lighter particles, the contra configuration with inward opposing flow gave optimal performance of highest mixing efficiency at lowest required torque. Co-rotating impellers with baffles gave the best performance of high mixing efficiency at lowest power input for the heavier particles.
format Journal
author P. Satjaritanun
E. Bringley
J. R. Regalbuto
J. A. Regalbuto
J. Register
J. W. Weidner
Y. Khunatorn
S. Shimpalee
author_facet P. Satjaritanun
E. Bringley
J. R. Regalbuto
J. A. Regalbuto
J. Register
J. W. Weidner
Y. Khunatorn
S. Shimpalee
author_sort P. Satjaritanun
title Experimental and computational investigation of mixing with contra-rotating, baffle-free impellers
title_short Experimental and computational investigation of mixing with contra-rotating, baffle-free impellers
title_full Experimental and computational investigation of mixing with contra-rotating, baffle-free impellers
title_fullStr Experimental and computational investigation of mixing with contra-rotating, baffle-free impellers
title_full_unstemmed Experimental and computational investigation of mixing with contra-rotating, baffle-free impellers
title_sort experimental and computational investigation of mixing with contra-rotating, baffle-free impellers
publishDate 2018
url https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=85038423449&origin=inward
http://cmuir.cmu.ac.th/jspui/handle/6653943832/58409
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