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Experiments in Fluids

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01.04.2011 | Research Article

Measurements of the tip leakage vortex structures and turbulence in the meridional plane of an axial water-jet pump

verfasst von: Huixuan Wu, Rinaldo L. Miorini, Joseph Katz

Erschienen in: Experiments in Fluids | Ausgabe 4/2011

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Abstract

Particle image velocimetry (PIV) measurements at varying resolutions focus on the flow structures in the tip region of a water-jet pump rotor, including the tip-clearance flow and the rollup process of a tip leakage vortex (TLV). Unobstructed views of these regions are facilitated by matching the optical refractive index of the transparent pump with that of the fluid. High-magnification data reveal the flow non-uniformities and associated turbulence within the tip gap. Instantaneous data and statistics of spatial distributions and strength of vortices in the rotor passage reveal that the leakage flow emerges as a wall jet with a shear layer containing a train of vortex filaments extending from the tip of the blade. These vortices are entrained into the TLV, but do not have time to merge. TLV breakdown in the aft part of the blade passage further fragments these structures, increasing their number and reducing their size. Analogy is made between the circumferential development of the TLV in the blade passage and that of the starting jet vortex ring rollup. Subject to several assumptions, these flows display similar trends, including conditions for TLV separation from the shear layer feeding vorticity into it.

Vorheriger Artikel Time-resolved volumetric particle tracking velocimetry of large-scale vortex structures from the reattachment region of a laminar separation bubble to the wake

Nächster Artikel Stereoscopic PIV measurements of flow in the nasal cavity with high flow therapy

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Arndt REA (1981) Cavitation in fluid machinery and hydraulic structures. Annu Rev Fluid Mech 13:273–328CrossRef

Chow YC, Uzol O, Katz J (2002) Flow non-uniformities and turbulent “hot spots” due to wake-blade and wake-wake interactions in a multistage turbomachine. ASME J Turbomach 124:553–563CrossRefMATH

Denton JD (1993) Loss mechanisms in turbomachines. J Turbomach 115:621–656CrossRef

Farrell KJ, Billet ML (1994) A correlation of leakage vortex cavitation in axial-flow pumps. J Fluids Eng 116:551–557CrossRef

Furukawa M, Inoue M, Saiki K, Yamada K (1999) The role of tip leakage vortex breakdown in compressor rotor aerodynamics. J Turbomach 121:469–480CrossRef

Gerolymos GA, Vallet I (1999) Tip-clearance and secondary flows in a transonic compressor rotor. J Turbomach 121:751–762CrossRef

Gharib M, Rambod E, Shariff K (1998) A universal time scale for vortex ring formation. J Fluid Mech 360:121–140CrossRefMATHMathSciNet

Gourdain N, Leboeuf F (2009) Unsteady simulation of an axial compressor stage with casing and blade passive treatments. J Turbomach 131:021013CrossRef

Hall MG (1972) Vortex breakdown. Annu Rev Fluid Mech 4:195–218CrossRef

Higuchi H, Arndt REA, Rogers MF (1989) Characteristics of tip vortex cavitation noise. J Fluids Eng 111:495–501CrossRef

Jang CM, Furukawa M, Inoue M (2001a) Analysis of vortical flow field in a propeller fan by LDV measurements and LES—part I: three-dimensional vortical flow structures. J Fluids Eng 123(4):748–754CrossRef

Jang CM, Furukawa M, Inoue M (2001b) Analysis of vortical flow field in a propeller fan by LDV measurements and LES—part II: unsteady nature of vortical flow structures due to tip vortex breakdown. J Fluids Eng 123(4):755–761CrossRef

Lakshminarayana B (1996) Fluid dynamics and heat transfer of turbomachinery. Wiley Interscience, New York

Leibovich S (1978) The structure of vortex breakdown. Annu Rev Fluid Mech 10:221–246CrossRef

Li YS, Cumpsty NA (1991a) Mixing in axial flow compressors: part I-test facilities and measurements in a four-stage compressor. J Turbomach 113:161–165CrossRef

Li YS, Cumpsty NA (1991b) Mixing in axial flow compressors: part II-measurements in a single-stage compressor and a duct. J Turbomach 113:166–174CrossRef

Liu B, Wang H, Liu H, Yu H, Jiang H, Chen M (2004) Experimental investigation of unsteady flow field in the tip region of an axial compressor rotor passage at near stall condition with stereoscopic particle image velocimetry. Trans ASME 126:360–374CrossRef

Ma R, Devenport WJ (2007) Tip gap effects on the unsteady behavior of a tip leakage vortex. AIAA J 45:1713–1724CrossRef

Mailach R, Lehmann I, Vogeler K (2001) Rotating instabilities in an axial compressor originating from the fluctuating blade tip vortex. J Turbomach 123:453–461CrossRef

Miorini R, Wu H, Katz J (2010) The internal structure of the tip leakage vortex within the rotor of an axial water-jet pump. Submitted to J Turbomach

Muthanna C, Devenport WJ (2004) Wake of a compressor cascade with tip gap part 1: mean flow and turbulence structure. AIAA J 42(11):2320–2331CrossRef

Oweis GF, Ceccio SL (2005) Instantaneous and time-averaged flow fields of multiple vortices in the tip region of a ducted propulsor. Exp Fluids 38:615–636CrossRef

Oweis GF, Fry D, Chesnakas CJ, Jessup SD, Ceccio SL (2006a) Development of a tip-leakage flow part 1: the flow over a range of Reynolds numbers. J Fluid Eng 128:751–764CrossRef

Oweis GF, Fry D, Chesnakas CJ, Jessup SD, Ceccio SL (2006b) Development of a tip-leakage flow part 2: comparison between the ducted and un-ducted rotor. J Fluid Eng 128:765–773CrossRef

Palafox P, Oldfield MLG, LaGraff JE, Jones TV (2008) PIV maps of tip leakage and secondary flow fields on a low-speed turbine blade cascade with moving end wall. J Turbomach 130:011001CrossRef

Rosenfeld M, Rambod E, Gharib M (1998) Circulation and formation number of laminar vortex rings. J Fluid Mech 376:297–318CrossRefMATHMathSciNet

Roth G, Katz J (2001) Five techniques for increasing the speed and accuracy of PIV interrogation. Meas Sci Technol 12:238–245CrossRef

Shen YT, Gowing S, Jessup S (2009) Tip vortex cavitation inception scaling for high Reynolds number applications 131:071301

Shusser M, Gharib M (2000) Energy and velocity of a forming vortex ring. Phys Fluids 12:618–621CrossRefMATHMathSciNet

Sieverding CH, Arts T, Dénos R, Brouckaert J-F (2000) Measurements techniques for unsteady flows in turbomachines. Exp Fluids 28:285–321CrossRef

Soranna F, Chow YC, Uzol O, Katz J (2008) Turbulence within a turbomachine rotor wake subject to nonuniform contraction. AIAA J 46(11):2687–2702CrossRef

Tan CS, Day I, Morris S, Wadia A (2010) Spike-type compressor stall inception, detection, and control. Annu Rev Fluid Mech 42:275–300CrossRef

Uzol O, Katz J (2007) Flow measurement techniques in turbomachinery. In: Tropea C, Yarin AL, Foss JF (eds) Handbook of experimental fluid mechanics. Springer, Berlin, pp 919–957CrossRef

Uzol O, Chow YC, Katz J, Meneveau C (2002) Unobstructed particle image velocimetry measurements within an axial turbo-pump using liquid and blades with matched refractive indices. Exp Fluids 33:909–919

Uzol O, Brzozowski D, Chow YC, Katz J, Meneveau C (2007) A database of PIV measurements within a turbomachinery stage and sample comparisons with unsteady RANS. J Turbulence 8(10):1–20

Xiao X, McCarter AA, Lakshminarayana B (2001) Tip clearance effects in a turbine rotor: part I pressure field and loss. ASME J Turbomach 123:296–304CrossRef

You D, Wang M, Moin P, Mittal R (2006) Effects of tip-gap size on the tip-leakage flow in a turbomachinery cascade. Phys Fluids 18:105102CrossRef

Yu X, Liu B (2007) Stereoscopic PIV measurement of unsteady flows in an axial compressor stage. Exp Therm Fluid Sci 31:1049–1060CrossRef

Zhou J, Adrian RJ, Balachandar S, Kendall TM (1999) Mechanisms for generating coherent packets of hairpin vortices in channel flow. J Fluid Mech 387:353–396CrossRefMATHMathSciNet

Titel: Measurements of the tip leakage vortex structures and turbulence in the meridional plane of an axial water-jet pump
verfasst von: Huixuan Wu
Rinaldo L. Miorini
Joseph Katz
Publikationsdatum: 01.04.2011
Verlag: Springer-Verlag
Erschienen in: Experiments in Fluids / Ausgabe 4/2011
Print ISSN: 0723-4864
Elektronische ISSN: 1432-1114
DOI: https://doi.org/10.1007/s00348-010-0975-0

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