Detached-eddy Simulation for Time-dependent Turbulent Cavitating Flows 被引量：10

Detached-eddy Simulation for Time-dependent Turbulent Cavitating Flows

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摘要 The Reynolds-averaged Navier-Stokes（RANS）,such as the original k-ω two-equation closures,have been very popular in providing good prediction for a wide variety of flows with presently available computational resource.But for cavitating flows,the above equations noticeably over-predict turbulent production and hence effective viscosity.In this paper,the detached eddy simulation（DES） method for time-dependent turbulent cavitating flows is investigated.To assess the state-of-the-art of computational capabilities,different turbulence models including the widely used RANS model and DES model are conducted.Firstly,in order to investigate the grid dependency in computations,different grid sizes are adopted in the computation.Furthermore,the credibility of DES model is supported by the unsteady cavitating flows over a 2D hydrofoil.The results show that the DES model can effectively reduce the eddy viscosities.From the experimental validations regarding the force analysis,frequency and the unsteady cavity visualizations,more favorable agreement with experimental visualizations and measurements are obtained by DES model.DES model is better able to capture unsteady phenomena including cavity length and the resulting hydrodynamic characteristics,reproduces the time-averaged velocity quantitatively around the hydrofoil,and yields more acceptable and unsteady dynamics features.The DES model has shown to be effective in improving the overall predictive capability of unsteady cavitating flows. The Reynolds-averaged Navier-Stokes（RANS）,such as the original k-ω two-equation closures,have been very popular in providing good prediction for a wide variety of flows with presently available computational resource.But for cavitating flows,the above equations noticeably over-predict turbulent production and hence effective viscosity.In this paper,the detached eddy simulation（DES） method for time-dependent turbulent cavitating flows is investigated.To assess the state-of-the-art of computational capabilities,different turbulence models including the widely used RANS model and DES model are conducted.Firstly,in order to investigate the grid dependency in computations,different grid sizes are adopted in the computation.Furthermore,the credibility of DES model is supported by the unsteady cavitating flows over a 2D hydrofoil.The results show that the DES model can effectively reduce the eddy viscosities.From the experimental validations regarding the force analysis,frequency and the unsteady cavity visualizations,more favorable agreement with experimental visualizations and measurements are obtained by DES model.DES model is better able to capture unsteady phenomena including cavity length and the resulting hydrodynamic characteristics,reproduces the time-averaged velocity quantitatively around the hydrofoil,and yields more acceptable and unsteady dynamics features.The DES model has shown to be effective in improving the overall predictive capability of unsteady cavitating flows.

作者 HUANG Biao WANG Guoyu YU Zhiyi SHI Shuguo

机构地区 School of Mechanical Engineering

出处《Chinese Journal of Mechanical Engineering》 SCIE EI CAS CSCD 2012年第3期484-490,共7页 中国机械工程学报（英文版）

基金 supported by National Natural Science Foundation of China (Grant No.11172040)

关键词 cavitation detached-eddy simulation unsteady cavitating flows cavitation,detached-eddy simulation,unsteady cavitating flows

分类号 TP311.13 [自动化与计算机技术—计算机软件与理论] O357.5 [理学—流体力学]

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参考文献16

1KNAPP R T, DAILY J W, HAMMITT F G Cavitation[M].New York: McGraw-Hill, 1970.
2王福军,张玲,黎耀军,张志民.轴流式水泵非定常湍流数值模拟的若干关键问题[J].机械工程学报,2008,44(8):73-77. 被引量：53
3KUBOTA A, KATO H, YAMAGUCHI H. A new modeling of cavitating flows: a numerical study of unsteady cavitation on a hydrofoil section[J]..Z Fluid Mech., 1992, 240: 59-96.
4MERKLE C L, FENG J Z, BUELOW P E O. Computational modeling of the dynamics of sheet cavitation[C/CD]//Proc. Third International Symposium on Cavitation, Grenoble, France, 1998.
5KUNZ R F, BOGER D A, STINEBRING D R A. A preconditioned Navier-Stokes method for two-phase flows with application to cavitation predition[J]. Comput. Fluid, 2000, 29:849- 875.
6SINGHAL A K, ATHAVALE M M. Mathematical basis and validation of the full cavitation model[J]. Journal of Fluids Engineering, 2002, 124: 617-624.
7COUTIER-DELGOSHA O, FORTES-PATELLA R, REBOUND J L. Evaluation of the turbulence model influence on the numerical simulations of unsteady cavition[J]. J. Fluids Eng., 2003, 125: 33-45.
8JOHANSEN S T, WU J, SHYY W. Filter-based unsteady RANS computations[J]. Int. J.Heat and Fluid Flow, 2004, 25(1): 10-21.
9SPALART P R, JOU W H, STRELETS M, et al. Comments on the feasibility of LES for wings, and on a hybrid RANS/LES approach, advances in DNS/LES[C]//First AFOSR International Conference on DNS/LES, Greyden, Columbus, OH, 1997, 2001 : 102-114.
10GEORGE S. Constantinescu. LES and DES investigations of turbulent flow over a sphere[G]. AIAA 2000-0540.

二级参考文献11

1WANG Fu-jun LI Yao-jun CONG Guo-hui WANG Wen-e WANG Hai-song.CFD SIMULATION OF 3D FLOW IN LARGE-BORE AXIAL-FLOW PUMP WITH HALF-ELBOW SUCTION SUMP[J].Journal of Hydrodynamics,2006,18(2):243-247. 被引量：36
2GUO S J, MARUTA Y, OKAMOTO H, et al. Complex pressure fluctuations and vibrations in a pump-water tunnel system[C]//Proceedings of the 4th ASME/JSME Joint Fluids Engineering Conference: Volume 2, Part A, July 6-10, 2003, Honolulu, Hawaii. New York: ASME, 2003: 19-26.
3SCHRAPP H, STARK U, GOLTZ I, et al. Structure of the rotor tip flow in a highly-loaded single-stage axial-flow pump approaching stall, part Ⅰ:Breakdown of the tip-clearance vortex[C]//Proceedings of the ASME Heat Transfer/Fluids Engineering Summer Conference, HT/FED 2004, July 11-15, 2004, Charlotte, NorthCarolina. New York: ASME, 2004:307-312.
4WEGNER B, MALTSEV A, SCHNEIDER C, et al. Assessment of unsteady RANS in predicting swirl flow instability based on LES and experiments[J]. International Journal of Heat and Fluid Flow, 2004, 25(3): 528-536.
5GOTO A, NOHMI M, SAKURAI T, et al. Hydrodynamic design system for pumps based on 3D CAD/CFD and inverse design method[J]. Journal of Fluids Engineering, Transactions of the ASME, 2002, 124(2): 329-335.
6MULLER N, EINZINGER J, LEPACH T, et al. Applica- tion of a multi level CFD-technique for the design optimisation of hydraulic machinery bladings[C] //Proceedings of the ASME Heat Transfer/Fluids Engineering Summer Conference, HT/FED 2004, July l 1-15, 2004, Charlotte, North Carolina. New York: ASME, 2004: 601-608.
7WHITE J D, HOLLOWAY A G L, GERBER A G. Predicting turbine performance of high specific speed pumps using CFD[C]//Proceedings of ASME Fluids Engineering Division Summer Conference, FEDSM2005, 2005, June 19-23, 2005, Houston. New York: ASME, 2005: 125-131.
8NILSSON H, DAVIDSON L. Validations of CFD against detailed velocity and pressure measurements in water turbine runner flow[J]. International Journal for Numerical Methods in Fluids, 2003, 41 : 863-879.
9FERZIGER J H, PERIC M. Computational methods for fluid dynamics [M]. 3rd ed. Berlin: Springer-Verlag, 2002.
10MICHELASSI V, WISSINK J G, RODI W. Direct numerical simulation, large eddy simulation and unsteady Reynolds-averaged Navier-Stokes simulations of periodic unsteady flow in a low-pressure turbine cascade: A comparison[J]. Journal of Power and Energy, 2003, 217(4): 403-412.

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1张校文,汤方平,张文鹏,石丽建,葛恒军,袁海霞.轴流泵装置反转水动力特性研究[J].农业机械学报,2022,53(8):163-172. 被引量：3
2黎耀军,沈金峰,刘竹青,唐学林,张志民.轴流泵轮缘间隙非定常流动的大涡模拟[J].农业机械学报,2013,44(S1):113-118. 被引量：13
3陈红勋,朱兵.单台轴流泵模型0°安放角的数值计算分析[J].水动力学研究与进展（A辑）,2009,24(4):480-485. 被引量：13
4王春林,司艳雷,赵佰通,张浩,郑海霞.旋流自吸泵内部湍流场大涡模拟[J].农业机械学报,2009,40(9):68-72. 被引量：8
5SHI Weidong ZHANGDesheng GUAN Xingfan LENG Hongfei.Numerical and Experimental Investigation of High-efficiency Axial-flow Pump[J].Chinese Journal of Mechanical Engineering,2010,23(1):38-44. 被引量：50
6张博,王国玉,黄彪,时素果.绕水翼空化非定常的动力特性[J].机械工程学报,2010,46(6):164-169. 被引量：6
7黄彪,王国玉,张博,余志毅.FBM湍流模型在云状空化流动数值计算中的应用与评价[J].机械工程学报,2010,46(8):147-153. 被引量：8
8蔡宏伟,潘志军.排涝泵站轴流泵进、出水流道的数值模拟[J].中国给水排水,2010,26(9):71-74. 被引量：5
9朱荣生,胡自强,付强.双叶片泵内压力脉动的数值模拟[J].农业工程学报,2010,26(6):129-134. 被引量：24
10朱荣生,胡自强,杨爱玲.双叶片泵内非定常流动的数值模拟[J].排灌机械工程学报,2011,29(1):26-30. 被引量：14

同被引文献131

1梁尚,李勇,万德成.基于自适应网格技术的Clark-Y水翼空泡数值模拟[J].水动力学研究与进展（A辑）,2020,35(1):1-8. 被引量：5
2陈材侃,刘华.解三维水翼绕流的下潜涡环栅格法[J].船舶力学,2005,9(2):41-45. 被引量：8
3肖业祥,韩凤琴,久保田乔.非定常水斗表面自由水膜的流动机理[J].华南理工大学学报（自然科学版）,2006,34(4):75-79. 被引量：8
4罗兴琦,陈乃祥,林汝长.混流式转轮的准三维设计[J].水利学报,1996,28(10):18-21. 被引量：9
5罗兴琦,陈乃祥,彭国义,林汝长.有旋流动的全三维反问题计算在混流式转轮设计中的应用[J].水利学报,1996,28(10):27-31. 被引量：2
6曹伟,魏英杰,王聪,邹振祝,黄文虎.超空泡技术现状、问题与应用[J].力学进展,2006,36(4):571-579. 被引量：66
7刘桦,李家春,何友声,孟庆国.“十一五”水动力学发展规划的建议[J].力学进展,2007,37(1):142-146. 被引量：9
8何友声,刘桦,赵岗.二维空泡流的脉动性态研究[J].力学学报,1997,29(1):1-7. 被引量：21
9韩凤琴,肖业祥,久保田乔.旋转水斗内的非定常射流干涉[J].华南理工大学学报（自然科学版）,2007,35(6):25-28. 被引量：6
10Leroux J B,Coutier-Delgosha O,Astolfi J A.A joint experimental and numerical study of mechanisms associated to instability of partial cavitation on two-dimensional hydrofoil[J].Physics of Fluids,2005,17(5):1-20.

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2黄彪,王国玉,赵宇.Numerical simulation unsteady cloud cavitating flow with a filter-based density correction model[J].Journal of Hydrodynamics,2014,26(1):26-36. 被引量：23
3ZHANG XiaoBin,ZHANG Wei,CHEN JianYe,QIU LiMin,SUN DaMing.Validation of dynamic cavitation model for unsteady cavitating flow on NACA66[J].Science China(Technological Sciences),2014,57(4):819-827. 被引量：8
4施卫东,张光建,张德胜.基于PANS模型的水翼非定常空化特性研究[J].华中科技大学学报（自然科学版）,2014,42(4):1-5. 被引量：6
5周广礼,姚朝帮.小展弦比翼大攻角水动力数值计算方法[J].舰船科学技术,2015,37(6):47-51. 被引量：7
6洪锋,袁建平,周帮伦.空泡半径非线性变化的空化模型及应用[J].华中科技大学学报（自然科学版）,2015,43(10):15-20. 被引量：8
7Guoyu Wang,Qin Wu,Biao Huang.Dynamics of cavitation–structure interaction[J].Acta Mechanica Sinica,2017,33(4):685-708. 被引量：11
8刘城,闫清东,李娟,李晋,邹波.高功率密度液力变矩器空化特性研究[J].机械工程学报,2020,56(24):147-155. 被引量：8
9赵旻晟,赵伟文,万德成.E779A螺旋桨斜流工况下的空泡数值模拟[J].中国造船,2021,62(3):94-102. 被引量：3
10季斌,程怀玉,黄彪,罗先武,彭晓星,龙新平.空化水动力学非定常特性研究进展及展望[J].力学进展,2019,49(1):428-479. 被引量：67

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2罗兴锜,朱国俊,冯建军.水轮机技术进展与发展趋势[J].水力发电学报,2020(8):1-18. 被引量：34
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4梁尚,李勇,万德成.基于自适应网格技术的Clark-Y水翼空泡数值模拟[J].水动力学研究与进展（A辑）,2020,35(1):1-8. 被引量：5
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2HUANG Biao,WANG GuoYu,ZHAO Yu,WU Qin.Physical and numerical investigation on transient cavitating flows[J].Science China(Technological Sciences),2013,56(9):2207-2218. 被引量：16
3HU ChangLi,WANG GuoYu,CHEN GuangHao,HUANG Biao.A modified PANS model for computations of unsteady turbulence cavitating flows[J].Science China(Physics,Mechanics & Astronomy),2014,57(10):1967-1976. 被引量：12
4唐智权,吕集尔,刘慕仁,孔令江.在连续位置和速度条件下的NS模型研究[J].广西师范大学学报（自然科学版）,2007,25(3):7-10.
5Chien-Chou Tseng.Turbulence and cavitation models for time-dependent turbulent cavitating flows[J].Acta Mechanica Sinica,2011,27(4):473-487. 被引量：10
6HU Ning.A rescaling method for correcting log-layer mismatch in detached eddy simulation[J].Science China(Physics,Mechanics & Astronomy),2013,56(6):1165-1175.
7Hassan GHASSEMI,Ahmad Reza KOHANSAL.Isoparametric Boundary Element Method Applied to the Rectangular and Delta Hydrofoils near the Free Surface[J].China Ocean Engineering,2010,24(2):321-331.
8YANG Chi,HUANG Fuxin,WANG Lijue,WAN De-cheng.NUMERICAL SIMULATIONS OF HIGHLY NONLINEAR STEADY AND UNSTEADY FREE SURFACE FLOWS[J].Journal of Hydrodynamics,2011,23(6):683-696. 被引量：5
9TAMURA Y.,MATSUMOTO Y..IMPROVEMENT OF BUBBLE MODEL FOR CAVITATING FLOW SIMULATIONS[J].Journal of Hydrodynamics,2009,21(1):41-46. 被引量：23
10Qin Wu,Biao Huang,Guoyu Wang.Lagrangian-based investigation of the transient flow structures around a pitching hydrofoil[J].Acta Mechanica Sinica,2016,32(1):64-74. 被引量：1

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2012年第3期

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