An experimental insight into the effect of confinement on tip vortex cavitation of an elliptical hydrofoil

OLIVIER BOULON; MATHIEU CALLENAERE; JEAN-PIERRE FRANC; JEAN-MARIE MICHEL

doi:10.1017/S002211209900525X

Abstract

The present paper is devoted to an analysis of tip vortex cavitation under confined situations. The tip vortex is generated by a three-dimensional foil of elliptical planform, and the confinement is achieved by flat plates set perpendicular to the span, at an adjustable distance from the tip. In the range of variation of the boundary-layer thickness investigated, no significant interaction was observed between the tip vortex and the boundary layer which develops on the confinement plate. In particular, the cavitation inception index for tip vortex cavitation does not depend significantly upon the length of the plate upstream of the foil. On the contrary, tip clearance has a strong influence on the non-cavitating structure of the tip vortex and consequently on the inception of cavitation in its core. The tangential velocity profiles measured by a laser-Doppler velocimetry (LDV) technique through the vortex, between the suction and the pressure sides of the foil, are strongly asymmetric near the tip. They become more and more symmetric downstream and the confinement speeds up the symmetrization process. When the tip clearance is reduced to a few millimetres, the two extrema of the velocity profiles increase. This increase results in a decrease of the minimum pressure in the vortex centre and accounts for the smaller resistance to cavitation observed when tip clearance is reduced. For smaller values of tip clearance, a reduction of tip clearance induces on the contrary a significant reduction in the maxima of the tangential velocity together with a significant increase in the size of the vortex core estimated along the confinement plate. Hence, the resistance to cavitation is much higher for such small values of tip clearance and in practice, no tip vortex cavitation is observed for tip clearances below 1.5 mm. The cavitation number for the inception of tip vortex cavitation does not correlate satisfactorily with the lift coefficient, contrary to classical results obtained without any confinement. Owing to the specificity introduced by the confinement, the usual procedure developed in an infinite medium to estimate the vortex strength from LDV measurements is not applicable here. Hence, a new quantity homogeneous to a circulation had to be defined on the basis of the maximum tangential velocity and the core size, which proved to be better correlated to the cavitation inception data.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Moisy, Frédéric Porta, Arth ur La Voth, Greg and Bodenschatz, Eberhard 2000. Vortex Structure and Dynamics. Vol. 555, Issue. , p. 263.

Gopalan, Shridhar Katz, Joseph and Liu, Han L. 2002. Effect of Gap Size on Tip Leakage Cavitation Inception, Associated Noise and Flow Structure. Journal of Fluids Engineering, Vol. 124, Issue. 4, p. 994.

Arndt, Roger E.A. 2002. CAVITATION IN VORTICAL FLOWS. Annual Review of Fluid Mechanics, Vol. 34, Issue. 1, p. 143.

Oweis, Ghanem F. Choi, Jaehyug and Ceccio, Steven L. 2004. Dynamics and noise emission of laser induced cavitation bubbles in a vortical flow field. The Journal of the Acoustical Society of America, Vol. 115, Issue. 3, p. 1049.

Oweis, G. F. van der Hout, I. E. Iyer, C. Tryggvason, G. and Ceccio, S. L. 2005. Capture and inception of bubbles near line vortices. Physics of Fluids, Vol. 17, Issue. 2,

2005. Fundamentals of Cavitation. Vol. 76, Issue. , p. 223.

Oweis, Ghanem F. and Ceccio, Steven L. 2005. Instantaneous and time-averaged flow fields of multiple vortices in the tip region of a ducted propulsor. Experiments in Fluids, Vol. 38, Issue. 5, p. 615.

You, Donghyun Wang, Meng Moin, Parviz and Mittal, Rajat 2006. Effects of tip-gap size on the tip-leakage flow in a turbomachinery cascade. Physics of Fluids, Vol. 18, Issue. 10,

Brujan, Emil-Alexandru 2011. Cavitation in Non-Newtonian Fluids. p. 117.

Rabinovitch, Jason Brion, Vincent and Blanquart, Guillaume 2012. Effect of a splitter plate on the dynamics of a vortex pair. Physics of Fluids, Vol. 24, Issue. 7,

Mitroglou, Nicholas and Gavaises, Manolis 2013. Mapping of cavitating flow regimes in injectors for medium-/heavy-duty diesel engines. International Journal of Engine Research, Vol. 14, Issue. 6, p. 590.

Dreyer, Matthieu Decaix, Jean Münch-Alligné, Cécile and Farhat, Mohamed 2014. Mind the gap: a new insight into the tip leakage vortex using stereo-PIV. Experiments in Fluids, Vol. 55, Issue. 11,

Pennings, P. C. Westerweel, J. and van Terwisga, T. J. C. 2015. Flow field measurement around vortex cavitation. Experiments in Fluids, Vol. 56, Issue. 11,

Zhao, Yu Wang, Guoyu Jiang, Yutong and Huang, Biao 2016. Numerical analysis of developed tip leakage cavitating flows using a new transport-based model. International Communications in Heat and Mass Transfer, Vol. 78, Issue. , p. 39.

Wang, Ben-long Liu, Zhi-hui Li, Hao-yu Wang, Ya-yun Liu, Deng-cheng Zhang, Ling-xin and Peng, Xiao-xing 2017. On the numerical simulations of vortical cavitating flows around various hydrofoils. Journal of Hydrodynamics, Vol. 29, Issue. 6, p. 926.

SHI, Lei ZHANG, Desheng ZHAO, Ruijie SHI, Weidong and ESCH, B.P.M. (Bart) van 2017. Visualized observations of trajectory and dynamics of unsteady tip cloud cavitating vortices in axial flow pump. Journal of Fluid Science and Technology, Vol. 12, Issue. 1, p. JFST0007.

Peng, Xiao-xing Xu, Liang-hao Liu, Yu-wen Zhang, Guo-ping Cao, Yan-tao Hong, Fang-wen and Yan, Kai 2017. Experimental measurement of tip vortex flow field with/without cavitation in an elliptic hydrofoil. Journal of Hydrodynamics, Vol. 29, Issue. 6, p. 939.

Ghadimi, Parviz Tanha, Araz Tavakoli, Sasan and Feizi Chekab, Mohammad A. 2018. RANS simulation of the tip vortex flow generated around a NACA 0015 hydrofoil and examination of its hydrodynamic characteristics. Journal of Marine Engineering & Technology, Vol. 17, Issue. 2, p. 106.

Karathanassis, I. K. Trickett, K. Koukouvinis, P. Wang, J. Barbour, R. and Gavaises, M. 2018. Illustrating the effect of viscoelastic additives on cavitation and turbulence with X-ray imaging. Scientific Reports, Vol. 8, Issue. 1,

Liu, Yabin Tan, Lei and Wang, Binbin 2018. A Review of Tip Clearance in Propeller, Pump and Turbine. Energies, Vol. 11, Issue. 9, p. 2202.

Download full list

Article contents

An experimental insight into the effect of confinement on tip vortex cavitation of an elliptical hydrofoil

Abstract

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

An experimental insight into the effect of confinement on tip vortex cavitation of an elliptical hydrofoil

Abstract

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests