1 |
AMEUR H. Energy efficiency of different impellers in stirred tank reactors[J]. Energy, 2015, 93: 1980-1988.
|
2 |
BLIATSIOU C, MALIK A, BOHM L, et al. Influence of impeller geometry on hydromechanical stress in stirred liquid/liquid dispersions[J]. Industrial & Engineering Chemistry Research, 2019, 58: 2537-2550.
|
3 |
BAO Yuyun, LU Yu, CAI Ziqi, et al. Effects of rotational speed and fill level on particle mixing in a stirred tank with different impellers[J]. Chinese Journal of Chemical Engineering, 2018, 26:1383-1391.
|
4 |
MOLNÁR B, EGEDY A, VARGA T. CFD model based comparison of mixing efficiency of different impeller geometries[C]// PIERUCCI S, KLEMES J J. 11th International Conference on Chemical and Process Engineering. Milan, Italy: Aidic Servizi Srl, Via Giuseppe Colombo81, 2013, 32: 1453-1458.
|
5 |
ZEDNÍKOVÁ M, LINEK V, MOUCHA T, et al. Energy demands of different impeller types in gas-liquid dispersions[J]. Separation and Purification Technology, 2004, 39: 123-131.
|
6 |
XIE M H, XIA J Y, ZHOU Z, et al. Flow pattern, mixing, gas hold-up and mass transfer coefficient of triple-impeller configurations in stirred tank bioreactors[J]. Industrial & Engineering Chemistry Research, 2014, 53: 5941-5953.
|
7 |
杨宇成, 杨时颖, MOSES Arowo. 旋转泡沫填料反应器的研究进展[J]. 化工进展, 2018, 37(6): 2046-2052.
|
|
YANG Yucheng, YANG Shiying, MOSES Arowo. Research progress in a rotating foam reactor[J]. Chemical Industry and Engineering Progress, 2018, 37(6): 2046-2052.
|
8 |
MENDOZA F, Lopes BAÑALES A, CID E, et al. Hydrodynamics in a stirred tank in the transitional flow regime[J]. Chemical Engineering Research & Design, 2018, 132: 865-880.
|
9 |
DEVI T T, KUMAR B, PETEL A K. Detached eddy simulation of turbulent flow in stirred tank reactor[J]. Procedia Engineering, 2015, 127: 87-94.
|
10 |
QI Nana, WANG Hui, ZHANG Kai, et al. Numerical simulation of fluid dynamics in the stirred tank by the SSG Reynolds Stress Model[J]. Frontiers of Chemical Engineering in China, 2010, 4: 506-514.
|
11 |
CHENG D, WANG S, YANG C, et al. Numerical simulation of turbulent flow and mixing in gas-liquid-liquid stirred tanks[J]. Industrial & Engineering Chemistry Research, 2017, 56: 13051-13064.
|
12 |
YANG Fengling, ZHOU Shenjie, AN Xiaohui. Gas-liquid hydrodynamics in a vessel stirred by dual dislocated-blade Rushton impellers[J]. Chinese Journal of Chemical Engineering, 2015, 23: 1746-1754.
|
13 |
NAUSHEEN Basha, AHMED Kovacevic, SHAM Rane. Analysis of oil-injected twin-screw compressor with multiphase flow models[J]. Designs, 2019, 3(4): 54.
|
14 |
SPALART P R. Comments on the feasibility of LES for wings, and on a hybrid RANS/LES approach[C]//Proceedings of First AFOSR International Conference on DNS/LES, 1997.
|
15 |
SPALART P R, DECK S, SHUR M L, et al. A new version of detached-eddy simulation, resistant to ambiguous grid densities[J]. Theoretical and Computational Fluid Dynamics, 2006, 20: 181-195.
|
16 |
LIN Dun, SU Xinrong, YUAN Xin. DDES analysis of the wake vortex related unsteadiness and losses in the environment of a high-pressure turbine stage[J]. Journal of Turbomachinery, 2018, 140: 041001.
|
17 |
XIAO Zhixiang, LIU Jian, FU Song. Calculations of massive separation around landing-gear-like geometries[J]. Journal of Hydrodynamics, 2010, 22: 883-888.
|
18 |
YANG Yuchen, WANG Zhenming, ZHAO Ning. A DDES study of the flow past a prolate spheroid using a high-order U-MUSCL scheme[J]. International Journal of Modern Physics B, 2020, 34(14/15/16): 6.
|
19 |
Gritskevich MIKHAIL S, Garbaruk ANDREY V, JOCHEN Schütze, et al. Development of DDES and IDDES formulations for the k-ω shear stress transport model[J]. Flow, Turbulence and Combustion, 2012, 88: 431-449.
|
20 |
ZHU Quanhong, XIAO Hang, CHEN Aqiang, et al. CFD study on double-to single-loop flow pattern transition and its influence on macro mixing efficiency in fully baffled tank stirred by a Rushton turbine[J]. Chinese Journal of Chemical Engineering, 2019, 27: 993-1000.
|
21 |
ZHANG Ning, LIU Xiaokai, GAO Bo. DDES analysis of the unsteady wake flow and its evolution of a centrifugal pump[J]. Renewable Energy, 2019, 141: 570-582.
|
22 |
HUNT J C R, WRAY A A, MOIN P. Eddies, stream and convergence zones in turbulent flows[R]. San Francisco, USA: Center of Turbulence Research Proceedings of the Summer Program, 1988: 193-208.
|
23 |
ZHOU Hao, CAI Guobiao, ZHANG Jianhua, et al. Research of wall roughness effects based on Q criterion[J]. Microfluidics and Nanofluidics, 2017, 21: 114.
|
24 |
FU Wushung, LAI Yuchih, LI Chunggang. Estimation of turbulent natural convection in horizontal parallel plates by the Q criterion[J]. International Communications in Heat and Mass Transfer, 2013, 45: 41-46.
|
25 |
Peter VRÁBEL, Van Der Lans ROB G J M, KAREL Ch A M Luyben, et al. Mixing in large-scale vessels stirred with multiple radial or radial and axial up-pumping impellers: modelling and measurements[J]. Chemical Engineering Science, 2000, 55: 5881-5896.
|
26 |
ZHANG Qinghua, YANG Cha, MAO Zaisha. Large eddy simulation of turbulent flow and mixing time in a gas-liquid stirred tank[J]. Industrial & Engineering Chemistry Research, 2012, 51: 10124-10131.
|
27 |
GIUSEPPINA Montante, ALESSANDRO Paglianti. Gas hold-up distribution and mixing time in gas-liquid stirred tanks[J]. Chemical Engineering Journal, 2015, 279: 648-658.
|