| 1 |
Analysis of the turbulent flow and trailing vortices induced by new design grooved blade impellers in a baffled tank
Martinez-Delgadillo SA, Alonzo-Garcia A, Mendoza-Escamilla VX, Gonzalez-Neria I, Yanez-Varela JA
Chemical Engineering Journal, 358, 225, 2019 |
| 2 |
Computational fluid dynamics simulation of hydrodynamics in an uncovered unbaffled tank agitated by pitched blade turbines
Li L, Wang J, Feng L, Gu X
Korean Journal of Chemical Engineering, 34(11), 2811, 2017 |
| 3 |
Numerical simulation of flow field characteristics in a gas-liquid-solid agitated tank
Li L, Xu B
Korean Journal of Chemical Engineering, 33(7), 2007, 2016 |
| 4 |
Numerical investigation of the effect of the Rushton type turbine design factors on agitated tank flow characteristics
Yapici K, Karasozen B, Schafer M, Uludag Y
Chemical Engineering and Processing, 47(8), 1346, 2008 |
| 5 |
Aggregates settling velocity-direct in situ measurement
Kysela B, Chara Z, Ditl P
Separation Science and Technology, 43(7), 1610, 2008 |
| 6 |
A simplified procedure to identify trailing vortices generated by a Rushton turbine
Escudie R, Line A
AIChE Journal, 53(2), 523, 2007 |
| 7 |
Improving gas distribution through agitator and gas sparger modification in an autoclave model
Noui-Mehidi MN, Zhu YG, Wu J
Journal of Chemical Engineering of Japan, 40(3), 213, 2007 |
| 8 |
Characterization of trailing vortices generated by a Rushton turbine
Escudie R, Bouyer D, Line A
AIChE Journal, 50(1), 75, 2004 |
| 9 |
Experimental analysis of hydrodynamics induced by a Moritz HAS impeller in laminar and turbulent regimes
Escudie R, Line A, Kiener P
Canadian Journal of Chemical Engineering, 80(4), 566, 2002 |
