Volume 6 Issue 3
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Hou-lin LIU, Dong-xi LIU, Yong WANG, Xian-fang WU, Jian WANG. 2013:  Application of modified k-ω model to predicting cavitating flow in centrifugal pump. Water Science and Engineering, 6(3): 331-339. doi: 10.3882/j.issn.1674-2370.2013.03.009
Citation: Hou-lin LIU, Dong-xi LIU, Yong WANG, Xian-fang WU, Jian WANG. 2013:  Application of modified k-ω model to predicting cavitating flow in centrifugal pump. Water Science and Engineering, 6(3): 331-339. doi: 10.3882/j.issn.1674-2370.2013.03.009
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 Application of modified k-ω model to predicting cavitating flow in centrifugal pump

doi: 10.3882/j.issn.1674-2370.2013.03.009

  • Research Center of Fluid Machinery Engineering and Technology, Jiangsu University, Zhenjiang 212013, P. R. China

Funds:  This work was supported by the National Natural Science Foundation of China (Grants No. 51179075 and 51239005) and A Project Funded by the Priority Academic Program Development of Jiangsu Higher Education Institutions.
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  • Corresponding author: Hou-lin LIU
  • Received Date: 2012-04-06
  • Rev Recd Date: 2012-09-02
    Abstract
  • Considering the compressibility of the cavity in the cavitating flow, this paper presents a modified k-ω model for predicting the cavitating flow in a centrifugal pump, in which the modified k-ω model and Schnerr-Sauer cavitation model were combined with ANSYS CFX. To evaluate the modified and standard k-ω models, numerical simulations were performed with these two models, respectively, and the calculation results were compared with the experimental data. Numerical simulations were executed with three different values of the flow coefficient, and the simulation results of the modified k-ω model showed agreement with most of the experimental data. The cavitating flow in the centrifugal pump obtained by the modified k-ω model at the design flow coefficient of 0.102, was analyzed. When the cavitation number decreases, the cavity initially generates on the suction side of the blade near the leading edge and then expands to the outlet of the impeller, and the decrease of the total pressure coefficient mainly occurs upstream of the impeller passage, while the downstream remains almost unaffected by the development of cavitation.

     

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    • References(28)
  • Coutier-Delgosha, O., Fortes-Patella, R., and Reboud, J. L. 2002. Simulation of unsteady cavitation with a two-equation turbulence model including compressibility effects. Journal of Turbulence, 3(1), 58-65.
    [doi: 10.1088/1468-5248/3/1/058]
    Coutier-Delgosha, O., Reboud, J. L., and Fortes-Patella, R. 2003a. Evaluation of the turbulence model influence on the numerical simulations of unsteady cavitation. Journal of Fluids Engineering, 125(1), 38-45.
    [doi: 10.1115/1.1524584]
    Coutier-Delgosha, O., Hofmann, M., Stoffel, B., Fortes, P. R., and Reboud, J. L. 2003b. Experimental and numerical studies in a centrifugal pump with two-dimensional curved blades in cavitating condition. Journal of Fluids Engineering, 125(6), 970-978.
    [doi: 10.1115/1.1596238]
    Frikha, S., Coutier-Delgosha, O., and Astolfi, J. A. 2009. In?uence of the cavitation model on the simulation of cloud cavitation on 2D foil section. International Journal of Rotating Machinery, 2008(45), 1-12.
    [doi: 10.1155/2008/146234]
    Li, D. 2011. Prediction of non-cavitating and cavitating performance of a SVA Potsdam propeller. Second International Symposium on Marine Propulsors. Hamburg: Hamburg University of Technology.  
    Li, H. Y., Kelecy, J. K., Egelja-Maruszewski, A., and Vasquez, S. A. 2008. Advanced computational modeling of steady and unsteady cavitating flows. 2008 American Society of Mechanical Engineers (ASME) International Mechanical Engineering Congress and Exposition. Boston: ASME.
    Liu, H. L., Wang, Y., Yuan, S. Q., Tan, M. G., and Wang, K. 2010. Effects of blade number on characteristics of centrifugal pumps. Chinese Journal of Mechanical Engineering, 23(6), 742-747.
    [doi:10.3901/CJME. 2010.06.742]
    Liu, L. J., Li, J., and Feng, Z. P. 2006. A numerical method for simulation of attached cavitation flows. International Journal for Numerical Methods in Fluids, 52(6), 639-658.
    [doi: 10.1002/fld.1192]
    Olsson, M. 2008. Numerical Investigation on the Cavitating Flow in a Waterjet Pump. Ph. D. Dissertation. Sweden: Chalmers University of Technology.
    Pierrat, D., Gros, L., Couzinet, A., Pintrand, G., Le Fur, B., and Gyomlai, Ph. 2008. Experiment and numerical investigations of leading edge cavitation in a helico-centrifugal pump. The 12th International Symposium on Transport Phenomena and Dynamics of Rotating Machinery.
    Sato, T., Nagahara, T., and Suzuki, S. 2009. Cavitation analysis on double-suction volute pump. Third International Association for the History of Religions (IAHR) International Meeting of Workshop on Cavitation and Dynamic Problems in Hydraulic Machinery and System. Brno: IAHR.
    Schnerr, G. H., and Sauer, J. 2001. Physical and numerical modeling of unsteady cavitation dynamics. Fourth International Conference on Multiphase Flow. New Orleans: ICMF.
    Sezal, I. H., Schmidt, S. J., Schnerr, G. H., Thalhamer, M., and Förster, M. 2006. Shock and wave dynamics of compressible liquid flows with special emphasis on unsteady load on hydrofoils and on cavitation in injection nozzles. Sixth International Symposium on Cavitation. Wageningen: Maritime Research Institute Netherlands.
    Singhal, A. K., Athavale, M. M., Li, H. Y., and Jiang, Y. 2002. Mathematical basis and validation of the full cavitation model. Journal of Fluids Engineering, 124(3), 617-624.
    [doi: 10.1115/1.1486223]
    Wang, Y., Liu, H. L., Yuan, S. Q., Tan, M. G., and Wang, K. 2011. CFD simulation on cavitation characteristics in centrifugal pump. Journal of Drainage and Irrigation Machinery Engineering, 29(2),99-103.
    [doi:10.3969 /j. issn.1674-8530] (in Chinese)
    Wilcox, D. C. 2006. Turbulence Modeling for CFD. California: DCW Industries.
    Wu, J. Y., Utturkar, Y., Senocak, I., Shyy, W., and Arakere, N. 2003. Impact of turbulence and compressibility modeling on three-dimensional cavitating flow computations. 33rd AIAA Fluid Dynamics Conference and Exhibit. Orlando: American Institute of Aeronautics and Astronautics .
    Wu, J. Y., Wang, G. Y., and Shyy, W. 2005. Time-dependent turbulent cavitating flow computations with interfacial transport and filter-based models. International Journal for Numerical Methods in Fluids, 49(7), 739-761.
    [doi: 10.1002/fld.1047]
    Zwart, P., Gerber, A. G., and Belamri, T. 2004. A two-phase model for predicting cavitation dynamics. Fifth International Conference on Multiphase Flow. Yokohama: ICMF.
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