%0 Conference Paper %1 hunt1988eddies %A Hunt, J. C. R. %A Wray, A. A. %A Moin, P. %B Proceedings of the 1988 Summer Program %D 1988 %K 26b12-calculus-of-vector-functions 74a05-kinematics-of-deformation 76a02-foundations-of-fluid-mechanics 76d17-viscous-vortex-flows %T Eddies, streams, and convergence zones in turbulent flows %U https://ctr.stanford.edu/proceedings-1988-summer-program %X Recent studies of turbulent shear flows have shown that many of their important kinematical and dynamical properties can be more clearly understood by describing the flows in terms of individual events or streamline patterns. These events or flow regions are studied because they are associated with relatively large contributions to certain average properties of the flow, for example kinetic energy, Reynolds stress, or to particular processes in the flow, such as mixing and chemical reactions, which may be concentrated at locations where streamlines converge for fast chemical reactions (referred to as convergence or C regions), or in recirculating eddying regions for slow chemical reactions. The aim of this project was to use the numerical simulations to develop suitable criteria for defining these eddying or vortical zones. The C and streaming (S) zones were defined in order to define the whole flow field. It is concluded that homogeneous and sheared turbulent flow fields are made up of characteristic flow zones: eddy, C, and S zones. A set of objective criteria were found which describe regions in which the streamlines circulate, converge or diverge, and form high streams of high velocity flow.

@inproceedings{hunt1988eddies, abstract = {Recent studies of turbulent shear flows have shown that many of their important kinematical and dynamical properties can be more clearly understood by describing the flows in terms of individual events or streamline patterns. These events or flow regions are studied because they are associated with relatively large contributions to certain average properties of the flow, for example kinetic energy, Reynolds stress, or to particular processes in the flow, such as mixing and chemical reactions, which may be concentrated at locations where streamlines converge for fast chemical reactions (referred to as convergence or C regions), or in recirculating eddying regions for slow chemical reactions. The aim of this project was to use the numerical simulations to develop suitable criteria for defining these eddying or vortical zones. The C and streaming (S) zones were defined in order to define the whole flow field. It is concluded that homogeneous and sheared turbulent flow fields are made up of characteristic flow zones: eddy, C, and S zones. A set of objective criteria were found which describe regions in which the streamlines circulate, converge or diverge, and form high streams of high velocity flow.}, added-at = {2021-06-18T01:51:58.000+0200}, author = {Hunt, J. C. R. and Wray, A. A. and Moin, P.}, biburl = {https://www.bibsonomy.org/bibtex/2f5ac3cd722e0f6dedb71f82844e6c59d/gdmcbain}, booktitle = {Proceedings of the 1988 Summer Program}, institution = {Center for Turbulence Research}, interhash = {ea802b589ed67bf72669055893cb4cc1}, intrahash = {f5ac3cd722e0f6dedb71f82844e6c59d}, keywords = {26b12-calculus-of-vector-functions 74a05-kinematics-of-deformation 76a02-foundations-of-fluid-mechanics 76d17-viscous-vortex-flows}, month = dec, timestamp = {2021-06-18T06:28:41.000+0200}, title = {Eddies, streams, and convergence zones in turbulent flows}, url = {https://ctr.stanford.edu/proceedings-1988-summer-program}, year = 1988 }