Particle motion in resonance tubes

A. GOLDSHTEIN; K. SHUSTER; P. VAINSHTEIN; M. FICHMAN; C. GUTFINGER

doi:10.1017/S0022112097008197

Abstract

Small particle motions in standing or travelling acoustic waves are well known and extensively studied. Particle motion in weak shock waves has been studied much less, especially particle motion in periodic weak shock waves which as yet has not been dealt with.

The present study considers small particle motions caused by weak periodic shock waves in resonance tubes filled with air. A simple mathematical model is developed for resonance gas oscillations under the influence of a vibrating piston with a finite amplitude at the first acoustic resonance frequency. It is shown that a symmetrical sinusoidal piston motion generates non-symmetric periodic shock waves. A model of particle motion in such a flow field is suggested. It is found that non-symmetric shock waves cause particle drift from the middle cross-section toward the ends of the resonance tube. The velocity of particle drift is found to be of the order of Dpρp/ Trρg, where Dp is the particle diameter, Tr the period of the resonance oscillation, ρp and ρg are the particle and gas density, respectively. At the same time, the velocity drift strongly depends on the ratio τ/Tr, where τ is the particle relaxation time. Particle drift is vigorous when τ/Tr∼1 and insignificant when τ/Tr 1. Theoretical predictions of particle drift in resonance tubes are verified numerically as well as experimentally.

When the particle relaxation time is much smaller than period of the resonance oscillations particles perform oscillations around their equilibrium positions with amplitude of the order of Dpρp/ρg. It is shown that the difference in oscillation amplitude of particle of difference sizes explains coalescence of aerosol droplets observed in experiments of Temkin (1970).

The importance of the phenomena for particle separation, coagulation and transport processes is discussed.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Holwill, I.L. 2000. Manipulation of micron-sized aerosol particles in an acoustic standing wave field. Journal of Aerosol Science, Vol. 31, Issue. , p. 684.

Gutfinger, C. Shuster, K. Goldshtein, A. and Fichman, M. 2001. EFFECT OF WEAK PERIODIC SHOCK WAVES ON THE BEHAVIOR OF AEROSOL PARTICLES. Journal of Aerosol Science, Vol. 32, Issue. , p. 931.

Alexeev, A. Goldshtein, A. and Gutfinger, C. 2002. Heat interaction in a resonance tube. Physics of Fluids, Vol. 14, Issue. 5, p. 1812.

Shuster, K. Fichman, M. Goldshtein, A. and Gutfinger, C. 2002. Agglomeration of submicrometer particles in weak periodic shock waves. Physics of Fluids, Vol. 14, Issue. 5, p. 1802.

Alexeev, A. and Gutfinger, C. 2003. Resonance gas oscillations in closed tubes: Numerical study and experiments. Physics of Fluids, Vol. 15, Issue. 11, p. 3397.

Alexeev, A. and Gutfinger, C. 2003. Particle drift in a resonance tube—a numerical study. The Journal of the Acoustical Society of America, Vol. 114, Issue. 3, p. 1357.

Alexeev, A. and Gutfinger, C. 2004. Aerosol deposition in periodic shock waves. Physics of Fluids, Vol. 16, Issue. 4, p. 1028.

Goddard, Gregory and Kaduchak, Gregory 2005. Ultrasonic particle concentration in a line-driven cylindrical tube. The Journal of the Acoustical Society of America, Vol. 117, Issue. 6, p. 3440.

2007. The Aerodynamic Origin of Abrupt Thrust Generation in Insect Flight (Part 1: Vortex Staying and Vortex Pairing Phenomena). Journal of the Korean Society for Aeronautical & Space Sciences, Vol. 35, Issue. 1, p. 1.

Gubaidullin, D. A. and Osipov, P. P. 2011. On certain regimes of inclusion drift in acoustic fields. Journal of Engineering Physics and Thermophysics, Vol. 84, Issue. 2, p. 270.

Gubaidullin, D.A. and Ossipov, P.P. 2013. Numerical investigation of particle drift in acoustic resonator with periodic shock wave. Applied Mathematics and Computation, Vol. 219, Issue. 9, p. 4535.

Gubaidullin, L. A. and Osipov, P. P. 2013. Influence of Reynolds and Strouhal numbers on the direction of the wave force acting on inclusions in a standing sinusoidal wave. Journal of Engineering Physics and Thermophysics, Vol. 86, Issue. 1, p. 51.

Gubaidullin, D. A. Zaripov, R. G. Tkachenko, L. A. and Shaidullin, L. R. 2015. Motion of a Particle During Nonlinear gas Oscillations Through an Open Pipe in an Unstressed-Wave Regime. Journal of Engineering Physics and Thermophysics, Vol. 88, Issue. 4, p. 871.

Gubaidullin, D. A. Zaripov, R. G. and Tkachenko, L. A. 2016. Spherical particle dynamics at oscillations in tubes in the shock wave field. High Temperature, Vol. 54, Issue. 6, p. 867.

Gubaidullin, D A Tkachenko, L A and Zaripov, R G 2016. The movement of a particle at nonlinear oscillations of high amplitude in the closed tube. Journal of Physics: Conference Series, Vol. 669, Issue. , p. 012020.

Tkachenko, L. A. and Sergienko, M. V. 2016. Resonant oscillations of a gas in an open tube in the shock-free wave mode. Acoustical Physics, Vol. 62, Issue. 1, p. 51.

Liu, Jizhou and Li, Xiaodong 2020. A computational investigation of particle acoustic agglomeration in a resonance tube. Powder Technology, Vol. 374, Issue. , p. 82.

Khmelev, V. N. Shalunov, A. V. and Golykh, R. N. 2020. Increasing the Efficiency of Coagulation of Submicron Particles under Ultrasonic Action. Theoretical Foundations of Chemical Engineering, Vol. 54, Issue. 4, p. 539.

Gubaidullin, D. A. Zaripov, R. G. Osipov, P. P. Tkachenko, L. A. and Shaidullin, L. R. 2021. Wave Dynamics of Gas Suspensions and Individual Particles during Resonance Oscillations. High Temperature, Vol. 59, Issue. 2-6, p. 384.

Khmelev, Vladimir Shalunov, Andrey and Golykh, Roman 2024. Mathematical Simulation of the Influence of Acoustic on the Efficiency of PM 2.5 Coagulation. Mathematics, Vol. 12, Issue. 5, p. 692.

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Particle motion in resonance tubes

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