LES of particle dispersion and gas-to-particle mass transfer in turbulent shear flows

Sean C Garrick; Michael Bühlmann

doi:10.1007/978-3-319-59584-9_3

LES of particle dispersion and gas-to-particle mass transfer in turbulent shear flows

Sean C Garrick, Michael Bühlmann

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Abstract

LES of condensation gas-to-particle mass transfer in turbulent incompressible mixing layers are performed. The flows are comprised of a particle-free condensable vapor mixing with micron-size porous particles. Simulations are performed at a single Reynolds number while varying the particle Stokes number, the mass transfer and convective time scales, and the vapor concentration at the particle surface. DNS has shown to be quite useful in capturing the fluid–particle interactions though at a high compute time. The goal of this work is to use LES to obtain a high level of fidelity to the DNS but with significantly reduced computational requirements.

Original language	English (US)
Title of host publication	SpringerBriefs in Applied Sciences and Technology
Publisher	Springer- Verlag
Pages	37-55
Number of pages	19
Edition	9783319595832
DOIs	https://doi.org/10.1007/978-3-319-59584-9_3
State	Published - Jan 1 2018

Publication series

Name	SpringerBriefs in Applied Sciences and Technology
Number	9783319595832
ISSN (Print)	2191-530X
ISSN (Electronic)	2191-5318

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10.1007/978-3-319-59584-9_3

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LES of particle dispersion and gas-to-particle mass transfer in turbulent shear flows. / Garrick, Sean C; Bühlmann, Michael.
SpringerBriefs in Applied Sciences and Technology. 9783319595832. ed. Springer- Verlag, 2018. p. 37-55 (SpringerBriefs in Applied Sciences and Technology; No. 9783319595832).

Research output: Chapter in Book/Report/Conference proceeding › Chapter

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N2 - LES of condensation gas-to-particle mass transfer in turbulent incompressible mixing layers are performed. The flows are comprised of a particle-free condensable vapor mixing with micron-size porous particles. Simulations are performed at a single Reynolds number while varying the particle Stokes number, the mass transfer and convective time scales, and the vapor concentration at the particle surface. DNS has shown to be quite useful in capturing the fluid–particle interactions though at a high compute time. The goal of this work is to use LES to obtain a high level of fidelity to the DNS but with significantly reduced computational requirements.

AB - LES of condensation gas-to-particle mass transfer in turbulent incompressible mixing layers are performed. The flows are comprised of a particle-free condensable vapor mixing with micron-size porous particles. Simulations are performed at a single Reynolds number while varying the particle Stokes number, the mass transfer and convective time scales, and the vapor concentration at the particle surface. DNS has shown to be quite useful in capturing the fluid–particle interactions though at a high compute time. The goal of this work is to use LES to obtain a high level of fidelity to the DNS but with significantly reduced computational requirements.

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BT - SpringerBriefs in Applied Sciences and Technology

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ER -

LES of particle dispersion and gas-to-particle mass transfer in turbulent shear flows

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