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01-11-2017 | Research Article

Fast X-ray imaging of cavitating flows

Authors: Ilyass Khlifa, Alexandre Vabre, Marko Hočevar, Kamel Fezzaa, Sylvie Fuzier, Olivier Roussette, Olivier Coutier-Delgosha

Published in: Experiments in Fluids | Issue 11/2017

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Abstract

A new method based on ultra-fast X-ray imaging was developed in this work for the investigation of the dynamics and the structures of complex two-phase flows. In this paper, cavitation was created inside a millimetric 2D Venturi-type test section, while seeding particles were injected into the flow. Thanks to the phase-contrast enhancement technique provided by the APS (Advanced Photon Source) synchrotron beam, high definition X-ray images of the complex cavitating flows were obtained. These images contain valuable information about both the liquid and the gaseous phases. By means of image processing, the two phases were separated, and velocity fields of each phase were, therefore, calculated using image cross-correlations. The local vapour volume fractions were also obtained, thanks to the local intensity levels within the recorded images. These simultaneous measurements, provided by this new technique, afford more insight into the structure and the dynamic of two-phase flows as well as the interactions between them, and hence enable to improve our understanding of their behaviour. In the case of cavitating flows inside a Venturi-type test section, the X-ray measurements demonstrate, for the first time, the presence of significant slip velocities between the phases within sheet cavities for both steady and unsteady flow configurations.

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Born M, Wolf E (1999) Principles of optics, 7th edn. Cambridge University Press, CambridgeCrossRef

Canny J (1986) A computational approach to edge detection. IEEE Trans. Trans Pattern Anal Mach Intell 8(6):679

Coutier-Delgosha O, Devilliers JF, Pichon T, Vabre A, Woo W, Legoupil S (2006) Internal structure and dynamics of sheet cavitation. Phys Fluids 18(017):103

Coutier-Delgosha O, Fortes-Patella R, Reboud JL, Stutz B (2004) Evaluation of the turbulence model influence on the numerical simulations of unsteady cavitation. Multiph Sci Technol 16:205CrossRef

Coutier-Delgosha O, Devilliers JF, Pichon T, Vabre A, Woo W, Legoupil S (2006) Test case n\(^{\circ }\) 30: Unsteady cavitation in a venturi type section. Phys Fluids 18:017103CrossRef

Coutier-Delgosha O, Stutz B, Vabre A, Legoupil S (2007) Analysis of the cavitating flow structure by experimental and numerical investigations. J Fluid Mech 578:171CrossRefMATH

Coutier-Delgosha O, Vabre A, Hocevar M, Delion R, Dazin A, Lazaro D, Gmar M, Fezzaa K, Lee WK (2009) Local measurements in cavitating flow by ultra fast x-ray imaging. In: Proceedings of FEDSM2009-ASME fluids engineering division summer meeting, Vail, Colorado, USA

Cuvier C, Foucaut J, Braud C, Stanislas M (2014) Characterisation of a high reynolds number boundary layer subject to pressure gradient and separation. J Turbul 15(8):473CrossRef

Duda RO, Hart PE (1972) Use of the hough transform to detect lines and curves in pictures. Comm ACM 15(1):11CrossRefMATH

Duke D, Kastengren A, Tilocco F, Swantek A, Powell C (2013) X-ray radiography measurements of cavitating nozzle flow. At Sprays 23(9):841CrossRef

Dular M, Bachert R, Stoffel B, Sirok B (2004) Investigation of a re-entrant jet reflection at an inclined cavity closure line. Eur J Mech B Fluids 24(4):522CrossRefMATH

Dular M, Bachert R, Schaad C, Stoffel B (2007) Experimental evaluation of numerical simulation of cavitating flow around hydrofoil. Eur J Mech B Fluids 26(5):688CrossRefMATH

Dular M, Khlifa I, Fuzier S, Adama-Maiga M, Coutier-Delgosha O (2012) Scale effect on unsteady cloud cavitation. Exp Fluids 53:1233CrossRef

Foucault J, Miliat B, Perenne N, Stanislas M (2003) Characterization of different piv algorithms using the europiv synthetic image generator and real images from a turbulent boundary layer. In: Proceedings of the EUROPIV 2 Workshop, pp 163–185

Ganesh H, Mäkiharju S, Ceccio SL (2016) Bubbly shock propagation as a mechanism for sheet-to-cloud transition of partial cavities. J Fluid Mech 802:37CrossRefMathSciNet

Gembicky M, Oss D, Fuchs R, Coppens P (2005) A fast mechanical shutter for submicrosecond time-resolved synchrotron experiments. J Synchrotron Radiat 12:665CrossRef

Gopalan S, Katz J (2000) Flow structure and modeling issues in the closure region of attached cavitation. Phys Fluids 12:895CrossRefMATH

Heindel TJ (2011) A review of x-ray flow visualization with applications to multiphase flows. J Fluids Eng 133:074001CrossRef

Hough PVC (1962) Method and means for recognizing complex patterns. US patent 3,069,654

Hsieh J (2015) Computed tomography: principles, design, artifacts and recent advances, 3rd edn. SPIE Press

Hubbell JH, Seltzer SM. Tables of X-ray mass attenuation coefficients and mass energy-absorption coefficients from 1 kev to 20 mev for elements z = 1 to 92 and 48 additional substances of dosimetric interest* (1999). URL:https://www.nist.gov/pml/x-ray-mass-attenuation-coefficients

Im KS, Fezzaa K, Wang YJ, Liu X, Wang J, Lai MC (2007) Particle tracking velocimetry using fast x-ray phase-contrast imaging. Appl Phys Lett 90:091919CrossRef

Kamono H, Kato H, Yamaguchi H, Miyanaga M (1993) Simulation of cavity flow by ventilated cavitation on a foil section. ASME FED 153:183

Kastengren A, Powell C (2014) Synchrotron x-ray techniques for fluid dynamics. Exp Fluids 55(3):1CrossRef

Khlifa I (2014) Imagerie par rayons-x des ãI’coulements diphasiques : application aux ãI’coulements cavitants. Ph.D. thesis, ENSAM

Knapp R (1955) Recent investigation on the mechanics of cavitation. Trans ASME 77:1045

Labertaux K, Ceccio SL (2001) Partial cavity flows. part 1. cavities forming on test objects without spanwise variation. J Fluid Mech 431:1CrossRefMATH

Lecoffre Y (1994) La cavitation, Hemès

Raffel M, Willert CE, Wereley ST, Kompenhans J (2007) Particle image velocimetry, a practical guide, 2nd edn. Springer, Berlin

Reboud JL, Stutz B, Coutier O (1998) In: The proceedings of the 3th Int. Symposium on Cavitation, vol. 2. Michel JM, Kato H, Grenoble, France, vol. 2, pp 203–208

Snigerev A, Snigereva I, Kohn V, Kuznetsov S, Schelokov I (1995) On the possibilities of x-ray phase contrast microimaging by coherent high-energy synchrotron radiation. Rev Sci Instrum 66:5486CrossRef

Stutz B, Legoupil S (2003) X-ray measurements within unsteady cavitation. Exp Fluids 35:130CrossRef

Stutz B, Reboud JL (1997a) Experiments on unsteady cavitation. Exp Fluids 22:191CrossRefMATH

Stutz B, Reboud JL (1997b) Two-phase flow structure of sheet cavitation. Phys Fluids 9:3678CrossRefMATHMathSciNet

Sveen JK (2004) An introduction to matpiv v. 1.6.1. Tech rep

Vabre A, Legoupil S, Colin S, Geoffroy S, Lee W, Fezzaa K (2008) X-ray propagationbase phase-enhanced imaging of the meniscus of a capillary flow in a rectangular microchannel. Int J Heat Technol 26(11):109

Wosnik M, Qin Q, Kawakami DT, Arndt v (2005) Arndt, R.: Large eddy simulation and time-resolved particle image velocimetry in the wake of a cavitating hydrofoil. In: Proceedings of FEDSM2005-ASME fluids engineering division summer meeting and exhibition, Houston, TX, USA

Title: Fast X-ray imaging of cavitating flows
Authors: Ilyass Khlifa
Alexandre Vabre
Marko Hočevar
Kamel Fezzaa
Sylvie Fuzier
Olivier Roussette
Olivier Coutier-Delgosha
Publication date: 01-11-2017
Publisher: Springer Berlin Heidelberg
Published in: Experiments in Fluids / Issue 11/2017
Print ISSN: 0723-4864
Electronic ISSN: 1432-1114
DOI: https://doi.org/10.1007/s00348-017-2426-7

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