Flow dynamics and enhanced mixing in a converging–diverging channel

Gepner, S. W.; Floryan, J. M.

doi:10.1017/jfm.2016.621

Cited by 24 publications

(18 citation statements)

References 40 publications

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“…Active stirring Converging-diverging channel [3,25] Hydrodynamics [8,47] Rigid or flexible structures [2,38] Rigid or flexible structures [18,28,36,45] Staggered herringbone channel [56] Acoustics [14,33] Partitioned pipe mixer [35] Electro-hydrodynamics [13] Twisted pipes [7,12,34] Magneto-hydrodynamics [27] Focusing channels [37] Acoustically driven bubbles [49] Elastic turbulence [9,10,29] Dielectrophoresis [40] Corrugated channel [26] Electrokinetics [46] TABLE I: Examples of configurations for passive stirring, and types of forcing for active stirring, for open flow mixing (not exhaustive list).…”

Section: Passive Stirringmentioning

confidence: 99%

Active chaotic mixing in a channel with rotating arc-walls

et al. 2021

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An active inline mixer suitable for flows at low Reynolds number and high Péclet number is studied. An alternated oscillatory forcing protocol is imposed by three rotating circular arc-walls in a straight channel. In the two-dimensional case, simple phenomenological arguments are used to estimate heuristically the mixing efficiency with two non-dimensional control parameters: the Strouhal number based on the bulk flow velocity, and the strength of the cross flow relative to the transport flow. The validity and limitations of the proposed mixing conditions are explained by the transport mechanisms in the mixer. The beneficial role of the elliptic flow regions for stretching and folding the passive scalar interfaces is highlighted, as well as a correlation between good mixing ability and the chaotic advection of tracers in the mixing zone.

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Section: Passive Stirringmentioning

confidence: 99%

Active chaotic mixing in a channel with rotating arc-walls

et al. 2021

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“…Results of this verification are outlined in the Appendix. We also note that the approach used here has already been established for similar flows (Gepner & Floryan 2016;Yadav et al 2017Yadav et al , 2018Hossain, Cantwell & Sherwin 2021;Yadav, Gepner & Szumbarski 2021) and both spatial and temporal resolutions used in this work are more than sufficient to recover both hydrodynamic stability and nonlinear saturation states, as outlined in Yadav et al (2017).…”

Section: Problem Descriptionmentioning

confidence: 91%

“…While numerical investigations characterizing effects of longitudinal corrugation on hydrodynamic stability (Szumbarski 2007;Szumbarski & Błoński 2011;, and analysis of consequent nonlinear states (Yadav et al 2017;Pushenko & Gepner 2021) have been performed, to date there seem to be no experimental results reported to support existing numerical findings. The lack of experimental results is somewhat surprising, considering that the alternative, transverse groove configuration received much attention, both from experimental as well as computational perspectives (Sobey 1980;Nishimura, Ohori & Kawamura 1984;Nishimura et al 1985Nishimura et al , 1990aGschwind, Regele & Kottke 1995;Blancher, Creff & Quere 1998;Cabal, Szumbarski & Floryan 2002;Floryan & Floryan 2010;Mitsudharmadi, Jamaludin & Winoto 2012;Rivera-Alvarez & Ordonez 2013;Gepner & Floryan 2016). On the other hand, it seems that, at least in the qualitative sense, the destabilization mechanism caused by the presence of longitudinal grooves and consequent variation in the streamwise velocity, is similar to the gap instability (Moradi & Tavoularis 2019;Lamarche-Gagnon & Tavoularis 2021) that exists in the eccentric annular flow configuration and has been experimentally investigated (Piot & Tavoularis 2011).…”

Section: Introductionmentioning

confidence: 99%

Slowing down convective instabilities in corrugated Couette–Poiseuille flow

Yadav

Gepner²

2022

J. Fluid Mech.

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Couette–Poiseuille (CP) flow in the presence of longitudinal grooves is studied by means of numerical analysis. The flow is actuated by movement of the flat wall and pressure imposed in the opposite direction. The stationary wall features longitudinal grooves that modify the flow, change hydrodynamic drag on the driving wall and cause onset of hydrodynamic instability in the form of travelling waves with a consequent supercritical bifurcation, already at moderate ranges of the Reynolds number. We show that by manipulating this system it is possible to significantly decrease phase speed of the unstable wave and to effectively decouple time scales of wave propagation and amplification with a potential to significantly reduce the distance required for the onset of nonlinear effects. Current analysis begins with concise characterization of stationary, laminar CP flow and the effects of applying a selected corrugation pattern, followed by determination of conditions leading to the onset of instabilities. In the second part we illustrate selected nonlinear solutions obtained for low, supercritical values of the Reynolds numbers and due to the amplification of unstable travelling waves of possibly low phase velocities. This work is concluded with a short discussion of a linear evolution of a wave packet consisting of a superposition of a number of unstable waves and initiated by a localized pulse. This part illustrates that in addition to the reduction of the phase velocity of a single, unstable mode, imposition of the Couette component also reduces group velocity of a wave packet.

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“…Active methods employ external body forces 17 , actuated particles 18 and various stirrers 9 with all of them requiring an external energy input. Three-dimensionality and unsteadiness do not guarantee chaos 19,20 , and not every chaotic state guarantees good stirring; either Poincaré maps or Lyapunov exponents must be used to verify whether the resulting flow is both chaos-and stirring-capable.…”

mentioning

confidence: 99%

“…The Fourier expansion was truncated after M modes with M selected to make ratio of kinetic energies of this mode and mode zero small enough (10 −20 was used in the computations). The spectral element mesh as well as the local expansions were selected based on the convergence studies carried out previously in the context of stability and nonlinear saturation studies 19,26,33 . Sufficient temporal accuracy and resolution were achieved with the step size of ∆ = t 2e-2 26,33 , which translates to approximately 1000 timesteps per period of the oscillatory flow.…”

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confidence: 99%

Use of Surface Corrugations for Energy-Efficient Chaotic Stirring in Low Reynolds Number Flows

Gepner

Floryan

2020

Sci Rep

Self Cite

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We demonstrate that an intensive stirring can be achieved in laminar channel flows in a passive manner by utilizing the recently discovered instability waves which lead to chaotic particle movements. The stirring is suitable for mixtures made of delicate constituents prone to mechanical damage, such as bacteria and DNA samples, as collisions between the stream and both the bounding walls as well as mechanical mixing devices are avoided. Debris accumulation is prevented as no stagnant fluid zones are formed. Groove symmetries can be used to limit stirring to selected parts of the flow domain. The energy cost of flows with such stirring is either smaller or marginally larger than the energy cost of flows through smooth channels.

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Flow dynamics and enhanced mixing in a converging–diverging channel

Cited by 24 publications

References 40 publications

Active chaotic mixing in a channel with rotating arc-walls

Active chaotic mixing in a channel with rotating arc-walls

Slowing down convective instabilities in corrugated Couette–Poiseuille flow

Use of Surface Corrugations for Energy-Efficient Chaotic Stirring in Low Reynolds Number Flows

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