Characteristic analysis of unsteady viscous flow around a cavitating propeller 被引量：4

Characteristic analysis of unsteady viscous flow around a cavitating propeller

导出

摘要 Based on viscous multiphase flow theory, this paper presents some recent validation results with a hybrid grid and sliding mesh solving Unsteady Navier-Stokes (N-S) and Bubble Dynamics equations as applied to prediction of pressure, velocity and vapor volume fraction in the wake in an uniform inflow. Comparable to experimental results, numerical predictions of sheet cavitation, tip vortex cavitation and hub vortex cavitation are in agreement with the corresponding experimental data, the same as numerical predictions of pressure in wake. Tip vortex cavitation is the most important to generate the pressure fluctuation within the near wake. The characteristics such as blade and shaft rate frequency of propeller pressure in wake coincide with its geometric model and parameters. With increasing distance from propeller disk, the pressure signals at blade frequency de-crease. The process of attenuation becomes fast with the decreased advance coefficient and cavitation number. Based on viscous multiphase flow theory, this paper presents some recent validation results with a hybrid grid and sliding mesh solving Unsteady Navier-Stokes (N-S) and Bubble Dynamics equations as applied to prediction of pressure, velocity and vapor volume fraction in the wake in an uniform inflow. Comparable to experimental results, numerical predictions of sheet cavitation, tip vortex cavitation and hub vortex cavitation are in agreement with the corresponding experimental data, the same as numerical predictions of pressure in wake. Tip vortex cavitation is the most important to generate the pressure fluctuation within the near wake. The characteristics such as blade and shaft rate frequency of propeller pressure in wake coincide with its geometric model and parameters. With increasing distance from propeller disk, the pressure signals at blade frequency de-crease. The process of attenuation becomes fast with the decreased advance coefficient and cavitation number.

作者 ZHU ZhiFeng1, 2, FANG ShiLang1 & WANG XiaoYan1 1 Key Laboratory of Underwater Acoustic Signal Processing of Ministry of Education, Southeast University, Nanjing 210096, China 2 School of Electrical Engineering and Information, Anhui University of Technology, Maanshan 243002, China

出处《Science China(Technological Sciences)》 SCIE EI CAS 2010年第7期1983-1992,共10页 中国科学（技术科学英文版）

基金 supported by the Pre-research Major Project of China (Grant No. 06904002068)

关键词 cavitating FLOW RANS PROPELLER SLIDING mesh MULTIPHASE FLOW cavitating flow RANS propeller sliding mesh multiphase flow

分类号 V11 [航空宇航科学与技术—人机与环境工程]

引文网络
相关文献

参考文献4

1朱志峰,王晓燕,方世良.基于非结构网格RANS方法螺旋桨空化研究[J].海洋工程,2009,27(4):103-107. 被引量：7
2傅慧萍,李福新.回转体局部空泡绕流的非线性分析[J].力学学报,2002,34(2):278-285. 被引量：18
3叶金铭,熊鹰.空泡螺旋桨诱导的船体脉动压力预报(英文)[J].船舶力学,2005,9(6):21-29. 被引量：10
4董世汤,唐登海,周伟新.CSSRC的螺旋桨定常面元法[J].船舶力学,2005,9(5):46-60. 被引量：32

二级参考文献13

1Lee. Predictioin of steady and unsteady performance of marine propellers with or without cavitation by numerical lifting surface theory [D]. Ph.D. Dissertation Massachusetts Institute of Technology, Cambridge, MA, 1979.
2Jules W, Lindau. Propeller cavitation breakdown analysis[J]. Journal of Fluids Engineering, 2005,127:995 - 1002.
3Shin Hyung Rhee, Kawamura. Propeller cavitation study using an unstructured grid based Navier-Stokes solver[J]. Journal of Fluids Engineering, 2005,127:986 - 994.
4Manninen. On the mixture model for multiphase flow[ R]. Technical Research Centre of Finland, Vahion Teknillinen Tutkimuskeskus, Espoo, Finland, VTr Publications 288, 1996.
5SchiUer L, Naumann Z. A drag coefficient correlation[J]. Z. Ven. Dtsch. Ing, 1933, 77(12): 318-320.
6Singhal A K, Athavale M M, Li H Y, et al. Mathematical basis and validation of the full cavitation model[J]. ASME J. Fluids Eng., 2002,124(3) : 617 - 624.
7Francesco Salvatore, Claudio Testa, Luca Greco. A viscous/inviscid coupled formulation for unteady sheet cavitation modelling of marine profellers[ C ]//Fifth International Symposium on Cavitation (CAV2003). Osaka: [ s. n. ] ,2003 : 1 - 16.
8叶金铭.[D].武汉:海军工程大学,2003.
9Kerwin J E, Lee C S. Prediction of steady and unsteady marine propeller performance by numerical lifting-surface theory [J]. Trans. SNAME, 1978,86:218-253.
10谭廷寿王德恂.高性能船用螺旋桨研究[R].武汉:武汉交通科技大学研究报告,2001..

共引文献57

1张学伟,张亮,张嘉钟,魏英杰,王聪.通气超空泡稳定性分析的一种数值算法[J].力学学报,2008,40(6):820-825. 被引量：10
2刘巨斌,肖昌润,郑学龄.轴对称物体空泡流动的数值计算[J].海军工程大学学报,2004,16(4):4-7. 被引量：6
3傅慧萍,鲁传敬,吴磊.回转体空泡流特性研究[J].水动力学研究与进展（A辑）,2005,20(1):84-89. 被引量：28
4王言英.船用螺旋桨理论及其应用研究进展[J].大连理工大学学报,2006,46(2):306-312. 被引量：12
5辛公正,丁恩宝,唐登海.对转螺旋桨升力面设计方法[J].船舶力学,2006,10(2):40-46. 被引量：7
6刘巨斌,张志宏.基于传输方程空化模型的定常自然空化流场数值计算[J].海军工程大学学报,2007,19(1):35-38. 被引量：6
7覃新川,黄胜,常欣.船舶螺旋桨面元法的改进[J].华中科技大学学报（自然科学版）,2007,35(5):65-68. 被引量：10
8杨洪澜,张嘉钟,黄文虎.绕细长体空化器的垂直超空化流分析[J].哈尔滨商业大学学报（自然科学版）,2007,23(2):179-184. 被引量：1
9陈彦勇,高咏涛,夏雨.大侧斜对转螺旋桨在鱼雷上的应用研究[J].船舶力学,2008,12(2):231-236. 被引量：5
10张学伟,魏英杰,张嘉钟,王聪,于开平.重力场中超空泡形态的数值仿真研究[J].舰船科学技术,2008,30(5):110-114. 被引量：1

同被引文献20

1ZHENG Hong1,2 & ZHOU ChuangBing3 1 State Key Laboratory of Geomechanics and Geotechnical Engineering, Wuhan 430071, China,2 China Three Gorges University, Key Laboratory of Geological Hazards on Three Gorges Reservoir Area, Ministry of Education, Yi Chang 443002, China,3 School of Civil Engineering, Wuhan University, Wuhan 430072, China.Global analysis on slope stability and its engineering application[J].Science China(Technological Sciences),2009,52(2):507-512. 被引量：4
2WANG Lei1,2 & CHANG JinShi2 1 Huadian Electric Power Research Institute, Hangzhou 310030, China,2 College of Water Conservancy and Civil Engineering, China Agricultural University, Beijing 100083, China.Computational theory of cavitating flows for hydraulic turbomachinery with consideration of influence of water quality[J].Science China(Technological Sciences),2010,53(12):3341-3348. 被引量：4
3童峰,陆佶人,方世良.水声目标识别中一种轴频提取方法[J].声学学报,2004,29(5):398-402. 被引量：15
4吴国清,魏学环,周钢.提取螺旋桨识别特征的二种途径[J].声学学报,1993,18(3):210-216. 被引量：26
5张晓冬,李志义,武君,刘学武,刘东学,夏远景.水力空化对化学反应的强化效应[J].化工学报,2005,56(2):262-265. 被引量：46
6史广智,胡均川.舰船噪声调制谱谐波族结构特性理论分析[J].声学学报,2007,32(1):19-25. 被引量：31
7孙冬梅,朱岳明,张明进.降雨入渗过程的水-气二相流模型研究[J].水利学报,2007,38(2):150-156. 被引量：31
8应崇福.新世纪内声空化声致发光的研究进展——兼论声致热核聚变和声(致)化学[J].中国科学（G辑）,2007,37(2):129-136. 被引量：21
9高贤娴,陈伟中,黄威,徐俊峰,徐兴华,刘亚楠,梁越.空化泡内外质量交换的唯象模型[J].科学通报,2009,54(4):408-413. 被引量：7
10CAO XiaoLi ZHANG XiaoBin QIU LiMin GAN ZhiHua.Validation of full cavitation model in cryogenic fluids[J].Chinese Science Bulletin,2009,54(10):1633-1640. 被引量：13

引证文献4

1蔡军,淮秀兰,闫润生,李勋锋.湍流作用下水力空化气泡内温度演变的动力学分析[J].科学通报,2011,56(12):947-955. 被引量：15
2方世良,朱志峰.船舶螺旋桨辐射噪声与尾流场的相关性及特征分析方法[J].声学技术,2012,31(1):36-41. 被引量：2
3LIU Yan,ZHAO Peng-fei,WANG Qiang,CHEN Zhao-hui.URANS COMPUTATION OF CAVITATING FLOWS AROUND SKEWED PROPELLERS[J].Journal of Hydrodynamics,2012,24(3):339-346. 被引量：4
4张晓悦,王栋,张晓乐,陈晓东.Numerical modeling airflow in soil with impact of groundwater[J].Journal of Central South University,2013,20(5):1405-1411.

二级引证文献21

1吴晓霞,张华余,马空军.超声空化泡运动特性的研究进展[J].应用声学,2012,31(6):416-422. 被引量：17
2张淑君,陈可.基于水力空化技术的降解特性研究[J].力学与实践,2013,35(1):26-30. 被引量：2
3Jun Cai,Xunfeng Li,Bin Liu,Xiulan Huai.Effect of cavitating flow on forced convective heat transfer: a modeling study[J].Chinese Science Bulletin,2014,59(14):1580-1590. 被引量：2
4陶跃群,蔡军,淮秀兰,朱军,侯燕.高压对冲空化射流降解有机废水的实验研究[J].工程热物理学报,2018,39(12):2738-2744. 被引量：4
5姜继海,张健,李艳杰,罗念宁,于安才.Heat Transfer Process of Bubble during the Occurrence of Cavitation in Hydraulic System[J].Journal of Donghua University(English Edition),2014,31(3):229-234.
6李万鹏,魏岗,杜辉,王欣隆,尤云祥.分层流体中螺旋桨效应激发内波的实验分析[J].解放军理工大学学报（自然科学版）,2014,15(6):576-582. 被引量：5
7鹿麟,潘光.泵喷推进器非定常空化性能数值模拟分析[J].上海交通大学学报,2015,49(2):262-268. 被引量：6
8左志钢,刘树红,刘德民,覃大清,吴玉林.Numerical analyses of pressure fluctuations induced by interblade vortices in a model Francis turbine[J].Journal of Hydrodynamics,2015,27(4):513-521. 被引量：12
9张小强,祝锡晶,王建青.超声振动珩磨单空化泡溃灭温度研究[J].中国机械工程,2016,27(6):796-800. 被引量：1
10陶跃群,蔡军,刘斌,淮秀兰.湍流作用下空化泡的动力学分析和溃灭瞬间自由基产量计算[J].中国科学院大学学报（中英文）,2017,34(2):191-197. 被引量：10

1张林医,许洋,崔现成,杨益.高场磁共振PROPELLER技术控制运动伪影讨论[J].医疗装备,2013,26(6):3-4. 被引量：1
2ZENG Daxing Hou Yulei HUANG Zhen LU Wenjuan.Type Synthesis and Characteristic Analysis of a Family of 2-DOF Rotational Decoupled Parallel Mechanisms[J].Chinese Journal of Mechanical Engineering,2009,22(6):833-840. 被引量：14
3HUANG JingBo 1 ,XIAO ZhiXiang 1 ,FU Song 1 &ZHANG Miao 2 1 School of Aerospace Engineering,Tsinghua University,Beijing 100084,China,2 Shanghai Aircraft Design and Research Institute of COMAC,Shanghai 200232,China.Study of control effects of vortex generators on a supercritical wing[J].Science China(Technological Sciences),2010,53(8):2038-2048. 被引量：5
4屈鲁.没有叶片的风机[J].能源,2015,0(12):61-62. 被引量：1
5Sheng Zhou,Hongbin Wu,Xinqian Zheng.Frequency Analyses for Mechanism Research of Unsteady Flow Inside Three Dimensional Compressor Cascade[J].Journal of Thermal Science,2004,13(3):207-212.
6施高萍,郭晓梅,陈红亮.不同叶片安装角的轴流泵内部流动特性分析[J].水力发电,2012,38(1):84-86. 被引量：2
7ZHAO QingJun,LIU XiYang,WANG HuiShe,ZHAO XiaoLu,XU JianZhong.Experimental investigation on unsteady pressure fluctuation of rotor tip region in high pressure stage of a vaneless counter-rotating turbine[J].Science China(Technological Sciences),2009,52(6):1478-1483. 被引量：1
8段文清.几种医疗设备疑难故障维修5例[J].医疗设备信息,2003,18(4):76-77.
9杨策,李志刚,蒋滋康,索沂生.Numerical Investigation of a High-speed Centrifugal Compressor Impeller[J].Tsinghua Science and Technology,1999,4(4):1678-1682. 被引量：3
10Guanghui Wu,Lijie Zheng,Keqi Wu.Numerical Analysis and PIV Measurements of Tip Vortex in an Axial Rotor with Skewed-Swept Blade at Its Leading Edge[J].Journal of Thermal Science,2004,13(1):16-23. 被引量：1

Science China(Technological Sciences)

2010年第7期

浏览历史

内容加载中请稍等...