An experimental investigation of planar countercurrent turbulent shear layers

DAVID J. FORLITI; BRIAN A. TANG; PAUL J. STRYKOWSKI

doi:10.1017/S0022112005003642

Abstract

The spatial development of planar incompressible countercurrent shear layers was investigated experimentally. A facility was constructed to establish countercurrent shear layers without the formation of global stagnation in the flow. Particle image velocimetry was employed to obtain detailed measurements within the region of self-preservation for velocity ratios $U_{2}/U_{1}$ between 0 and −0.3. The spatial growth rate of countercurrent shear layers was found to agree generally with simple analytical theory. At 30% counterflow, the growth rate was approximately twice as large as the case with no counterflow. Peak turbulence quantities, when normalized by the applied shear magnitude, $\Delta U$, were found to be nominally constant for low levels of counterflow, but at counterflow velocities above 13% of the primary stream velocity, peak turbulence levels increased. The observed transition is accompanied by the development of mean flow three-dimensionality. The deviation occurs at a counterflow level that is in agree- ment with theoretical predictions for transition from convective to absolute instability.

Crossref Citations

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

Behrens, Alison A. Anderson, Matthew J. Strykowski, Paul J. and Forliti, David J. 2005. Enhancing Combustion in a Dump Combustor Using Countercurrent Shear: Part 2 — Heat Release Rate Measurements and Geometry Effects. p. 347.

Forliti, David J. Behrens, Alison A. Strykowski, Paul J. and Tang, Brian A. 2005. Enhancing Combustion in a Dump Combustor Using Countercurrent Shear: Part 1 — Nonreacting Flow Control and Preliminary Combustion Results. p. 339.

Birch, Stanley 2006. A Review of Axisymmetric Jet Flow Data for Noise Applications.

Gillgrist, R. D. Forliti, D. J. and Strykowski, P. J. 2007. On the Mechanisms Affecting Fluidic Vectoring Using Suction. Journal of Fluids Engineering, Vol. 129, Issue. 1, p. 91.

Behrens, A. A. and Strykowski, P. J. 2007. Controlling Volumetric Heat Release Rates in a Dump Combustor Using Countercurrent Shear. AIAA Journal, Vol. 45, Issue. 6, p. 1317.

Lee, Sang-Wook Smith, David S. Loth, Francis Fischer, Paul F. and Bassiouny, Hisham S. 2007. Importance of flow division on transition to turbulence within an arteriovenous graft. Journal of Biomechanics, Vol. 40, Issue. 5, p. 981.

Forliti, David and Ahmed, Kareem 2008. Flame Stabilization in a Model Ramjet Combustor Using a Transverse Slot Jet.

Humphrey, Joseph A.C. Rosales, Jorge L. Legendre, Lindsay A. LeDuc, J. Patrick and Landers, James P. 2008. Vortex dynamics in confined counter-current shearing flows with applications to mixing. International Journal of Heat and Fluid Flow, Vol. 29, Issue. 4, p. 1089.

Forliti, David and Diaz-Guardamino, Ignacio Echavarria 2008. Thrust Vector Control Using Transverse Injection and Countercurrent Shear.

Forliti, D. J. and Diaz-Guardamino, I. Echavarria 2009. Exploring Mechanisms of Fluidic Thrust Vectoring Using a Transverse Jet and Suction. AIAA Journal, Vol. 47, Issue. 10, p. 2329.

Caillol, P. 2009. Absolute and convective instabilities of an inviscid compressible mixing layer: Theory and applications. Physics of Fluids, Vol. 21, Issue. 10,

Agarwal, Krishna Kant and Ravikrishna, R. V. 2011. Experimental and Numerical Studies in a Compact Trapped Vortex Combustor: Stability Assessment and Augmentation. Combustion Science and Technology, Vol. 183, Issue. 12, p. 1308.

Choutapalli, Isaac M. Krothapalli, Anjaneyulu and Alkislar, Mehmet B. 2012. Pulsed-Jet Ejector Thrust Augumentor Characteristics. Journal of Propulsion and Power, Vol. 28, Issue. 2, p. 293.

Hajesfandiari, A. and Forliti, D. J. 2014. On the influence of internal density variations on the linear stability characteristics of planar shear layers. Physics of Fluids, Vol. 26, Issue. 5,

Arratia, Cristóbal Mowlavi, Saviz and Gallaire, François 2018. Absolute/convective secondary instabilities and the role of confinement in free shear layers. Physical Review Fluids, Vol. 3, Issue. 5,

Dupont, P. Piponniau, S. and Dussauge, J. P. 2019. Compressible mixing layer in shock-induced separation. Journal of Fluid Mechanics, Vol. 863, Issue. , p. 620.

Hamzehloo, Arash Lusher, David J. Laizet, Sylvain and Sandham, Neil D. 2021. Direct numerical simulation of compressible turbulence in a counter-flow channel configuration. Physical Review Fluids, Vol. 6, Issue. 9,

Helm, Clara M. Martín, M. Pino and Williams, Owen J.H. 2021. Characterization of the shear layer in separated shock/turbulent boundary layer interactions. Journal of Fluid Mechanics, Vol. 912, Issue. ,

Yang, Jinwei Anderson, Matt J. Strykowski, Paul J. and Srinivasan, Vinod 2021. Effects of confinement on absolute and convective instabilities for momentum-driven countercurrent shear layers. Physical Review Fluids, Vol. 6, Issue. 7,

Wang, Sen and Ghaemi, Sina 2022. Unsteady motions in the turbulent separation bubble of a two-dimensional wing. Journal of Fluid Mechanics, Vol. 948, Issue. ,

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An experimental investigation of planar countercurrent turbulent shear layers

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