Investigation and quantification of flow unsteadiness in shock-particle cloud interaction

Hosseinzadeh-Nik, Zahra; Subramaniam, Shankar; Regele, Jonathan D.

doi:10.1016/j.ijmultiphaseflow.2018.01.011

Cited by 45 publications

(19 citation statements)

References 58 publications

(93 reference statements)

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“…Previous studies of shock interaction with particle arrays have estimated grid qualities by examining the drag-coefficient on a single particle (Mehta et al, 2016(Mehta et al, , 2018bHosseinzadeh-Nik et al, 2018). It is important that the particle forces are well reproduced in the simulation, since they are central to the problem under investigation.…”

Section: Grid Resolutionmentioning

confidence: 99%

“…This causes the difference between the velocity in the separated flow regions behind the particles in this region and the mean flow to increase, and since the spanwise fluctuations are not increased similarly, the anisotropy increases. The importance of particle scale fluctuations in shock-wave particle-cloud interaction was previously examined in two-dimensional configurations using inviscid simulations by Regele et al (2014), and viscous simulations by Hosseinzadeh-Nik et al (2018), where the particle volume fraction was 0.15. Both studies featured a M a = 1.67 shock wave, which is significantly weaker than the shock waves studied here.…”

Section: Velocity Fluctuationsmentioning

confidence: 99%

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Computational analysis of shock-induced flow through stationary particle clouds

Osnes

Vartdal

Omang

et al. 2019

International Journal of Multiphase Flow

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We investigate the shock-induced flow through random particle arrays using particle-resolved Large Eddy Simulations for different incident shock wave Mach numbers, particle volume fractions and particle sizes. We analyze trends in mean flow quantities and the unresolved terms in the volume averaged momentum equation, as we vary the three parameters. We find that the shock wave attenuation and certain mean flow trends can be predicted by the opacity of the particle cloud, which is a function of particle size and particle volume fraction. We show that the Reynolds stress field plays an important role in the momentum balance at the particle cloud edges, and therefore strongly affects the reflected shock wave strength. The Reynolds stress was found to be insensitive to particle size, but strongly dependent on particle volume fraction. It is in better agreement with results from simulations of flow through particle clouds at fixed mean slip Reynolds numbers in the incompressible regime, than with results from other shock wave particle cloud studies, which have utilized either inviscid or twodimensional approaches. We propose an algebraic model for the streamwise Reynolds stress based on the observation that the separated flow regions are the primary contributions to the Reynolds stress.

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Section: Grid Resolutionmentioning

confidence: 99%

Section: Velocity Fluctuationsmentioning

confidence: 99%

Computational analysis of shock-induced flow through stationary particle clouds

Osnes

Vartdal

Omang

et al. 2019

International Journal of Multiphase Flow

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“…While this term is typically neglected in incompressible flow models, recent work has shown that these unresolved velocity fluctuations can contribute to a significant portion of the total kinetic energy during particle-shock interactions [24,35,48].…”

Section: Filtered Momentummentioning

confidence: 99%

“…In the context of shock-particle interactions for moderately dilute and dense suspensions, small-scale velocity fluctuations are produced in particle interstitial sites and advected downstream with the mean flow [24,35,48] (see Fig. 1 (b)).…”

Section: Introductionmentioning

confidence: 99%

“…Because such fluctuations exist even in laminar flow (e.g., steady wakes), it is often referred to as pseudo-turbulent kinetic energy (PTKE). While this term is typically neglected in incompressible flows without significant consequence, recent DNS have shown that PTKE can contribute between 30% and 100% of the resolved kinetic energy in compressible flows [24,35,39,48]. Its strength has been shown to increase as the particle volume fraction and the incident shock Mach number increase [35].…”

Section: Introductionmentioning

confidence: 99%

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A volume-filtered description of compressible particle-laden flows

Shallcross

Fox

Capecelatro

2020

International Journal of Multiphase Flow

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In this work, we present a rigorous derivation of the volume-filtered viscous compressible Navier-Stokes equations for disperse two-phase flows. Compared to incompressible flows, many new unclosed terms appear. These terms are quantified via a posteriori filtering of two-dimensional direct simulations of shock-particle interactions. We demonstrate that the pseudo-turbulent kinetic energy (PTKE) systematically acts to reduce the local gas-phase pressure and consequently increase the local Mach number. Its magnitude varies with volume fraction and filter size, which can be characterized using a Knudsen number based on the filter size and inter-particle spacing. A transport equation for PTKE is derived and closure models are proposed to accurately capture its evolution. The resulting set of volume-filtered equations are implemented within a highorder Eulerian-Lagrangian framework. An interphase coupling strategy consistent with the volume filtered formulation is employed to ensure grid convergence. Finally PTKE obtained from the volume-filtered Eulerian-Lagrangian simulations are compared to a series of two-and three-dimensional direct simulations of shocks passing through stationary particles.

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