Vortex rings from notched nozzles

TL;DR

This study investigates how the shape of notched nozzles influences vortex ring formation and evolution using direct numerical simulations, revealing consistent formation mechanisms and complex flow interactions.

Contribution

It introduces a detailed analysis of asymmetrical vortex ring formation from notched nozzles, highlighting the effects of nozzle shape on vortex dynamics and reconnection processes.

Findings

Distinct vortex rings form following nozzle shape

Entrained ambient fluid creates streamwise structures

Vortex reconnection occurs at the end of formation

Abstract

The formation of a vortex ring from a piston/nozzle apparatus depends on the nozzle exit's shape. Here we study the formation mechanism and the evolution of asymmetrical rings from notched nozzles using direct numerical simulations. Three types of nozzle are used: i) V-notched; ii) A-notched and iii)W-notched nozzles. The results show that a distinct main vortex ring is formed following the shape of nozzle exit at initial formation time. However entrainment from the surrounding ambient fluid through the trough locations creates pairs of streamwise structure after the piston stops. This structure connects to the leading vortex ring at the trough position and propagates toward the nozzle's centerline. The special topology of the leading ring is augmented by the circumferential flow, which is split into smaller portions around the circumference. This flow drives the evolution of the ring at the later stage; excite instability growth during the flow evolution. The streamwise vortex tubes finally collide at the centerline of the nozzle and induce vortex reconnection at the end of the formation. This formation process is consistent in all examined cases, which suggests that it might be applicable for more complex nozzle cases.