This study presents a numerical investigation of vortex rings generated at low Reynolds numbers within radially confined domains. The motivation stems from the lack of previous studies addressing these combined conditions, which are relevant to wall-bounded microjet flows. We solve the governing equations using the entropy-damped artificial-compressibility (EDAC) formulation with compact finite-difference schemes (CS-FD) and a third-order total variation diminishing Runge–Kutta (TVD-RK3) method; moreover, an immersed-boundary method (IBM) resolves curvilinear walls on a Cartesian grid. Validation against high-Reynolds-number confined and low-Reynolds-number unconfined experiments, and against direct numerical simulations, confirms the solver’s accuracy. We examine vortex rings with L/D₀=4. 0 over 150 Re 1000 and confinement ratios DC/D₀=1. 75, \, 2. 0, \, 2. 5, plus an unconfined reference. In all cases, two dissipation zones appear: one within the ring and another near the wall. The dominant site shifts with Re: for Re 250 dissipation concentrates in the ring, whereas for Re 500 it localizes near the wall. Furthermore, confinement reduces streamwise displacement and circulation by narrowing the effective cross section and intensifying the wall-attached vorticity layer. Decreasing Re suppresses roll-up of this layer, thereby allowing longer travel before viscous losses dominate. Lower Re also stabilizes the ring: no three-dimensionality is observed for Re 500 at any confinement, while at Re=1000 azimuthal undulations arise under tighter confinement (DC/D₀ 2. 0) but remain absent for DC/D₀=2. 5, indicating that strong confinement lowers the Reynolds number threshold for breakdown.
Silva-Soto et al. (Fri,) studied this question.