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Vortex ring formation process in starting jets with uniform background co- and counter-flow

Jianwei Zhu, Guoqing Zhang, Lei Gao, S. C. M. Yu

2023Journal of Fluid Mechanics12 citationsDOI

Abstract

The formation process of the leading vortex ring in starting jets with uniform background co- and counter-flow has been studied numerically for $-0.5\leq R_v\leq 0.5$ , where $R_v$ is the ratio of background velocity to jet velocity. For the cases with background counter-flow, the normal formation process of the leading vortex ring would be destroyed when $R_v<-0.4$ , i.e. the trailing jet would overtake the leading vortex ring through the centre, a phenomenon reminiscent of vortex leapfrogging. As the velocity ratio $R_v$ increases, the formation number $F_{t^*}$ decreases from $9.6$ at $R_v=-0.4$ to $1.92$ at $R_v=0.5$ . An analytical model based on the kinematic criterion has been developed so as to describe the relationship between the formation number $F_{t^*}$ and velocity ratio $R_v$ . A linear relationship between the vortex core parameter and stroke ratio of starting jet ( $\varepsilon \sim k_1L/D$ ) for the Norbury vortex ring has been established and used effectively to close the model. For co-flow with $0< R_v\leq 0.5$ , the results from this model are consistent with the present numerical simulation and the experiments by Krueger et al. ( J. Fluid Mech. , vol. 556, 2006, pp. 147–166). For counter-flow, two different equations are proposed for $-0.4\leq R_v\leq -0.2$ and $-0.2< R_v<0$ , respectively.

Topics & Concepts

VortexPhysicsVortex ringJet (fluid)Flow (mathematics)Ring (chemistry)MechanicsChemistryOrganic chemistryFluid Dynamics and Turbulent FlowsComputational Fluid Dynamics and AerodynamicsFluid Dynamics and Vibration Analysis