Turbulent impinging jet flow into an unshrouded rotor-stator system: Hydrodynamics and heat transfer

Sébastien Poncet, Thien Duy Nguyen, Souad Harmand, Julien Pellé, Riccardo Da Soghe, Cosimo Bianchini, Stéphane Viazzo

Research output: Contribution to journalArticlepeer-review

21 Scopus citations

Abstract

New calculations using an innovative Reynolds Stress Model are compared to velocity measurements performed by Particle Image Velocimetry technique and the predictions of a k-ω SST model in the case of an impinging jet flow onto a rotating disk in a discoidal and unshrouded rotor-stator system. The cavity is characterized by a dimensionless spacing interval G=0.02 and a low aspect ratio for the jet e/D=0.25. Jet Reynolds numbers ranging from 1.72×104 to 4.3×104 and rotational Reynolds numbers between 0.33×105 and 5.32×105 are considered. Three flow regions have been identified: a jet-dominated flow area at low radii characterized by a zero tangential velocity, a mixed region at intermediate radii and rotation-dominated flow region outwards. For all parameters, turbulence, which tends to the isotropic limit in the core, is much intense in a region located after the impingement zone. A relative good agreement between the PIV measurements and the predictions of the RSM has been obtained in terms of the radial distributions of the core-swirl ratio and of the turbulence intensities. The k-ω SST model overestimates these flow characteristics in the jet dominated area. For the thermal field, the heat transfers are enhanced in the jet dominated region and decreases towards the periphery of the cavity. The jet Reynolds number appears to have a preponderant effect compared to the rotational one on the heat transfer distribution. The two RANS modelings compare quite well with the heat transfer measurements for these ranges of parameters.

Original languageEnglish
Pages (from-to)719-734
Number of pages16
JournalInternational Journal of Heat and Fluid Flow
Volume44
DOIs
StatePublished - Dec 2013
Externally publishedYes

Funding

This work was undertaken as part of the MEDEE (Energy control of electric devices) program. The authors would like to thank the Nord-Pas-De-Calais region and the EU (FEDER) for their financial support as well as the LABEX MEC (ANR-11-LABX-0092) through the HYDREX program.

FundersFunder number
Labex MECANR-11-LABX-0092
European Commission
European Regional Development Fund

    Keywords

    • Heat transfer
    • Impinging jet
    • Infrared thermography
    • Particle Image Velocimetry
    • RANS modeling
    • Rotor-stator

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