A fully meshless method for ‘gas - evaporating droplet' flow modelling

Oyuna Rybdylova; Alexander Osiptsov; Sergei Sazhin; Steven Begg; Morgan Heikal

doi:10.1002/pamm.201510332

A fully meshless method for ‘gas - evaporating droplet' flow modelling

Oyuna Rybdylova, Alexander Osiptsov, Sergei Sazhin, Steven Begg, Morgan Heikal

Research output: Chapter in Book/Conference proceeding with ISSN or ISBN › Conference contribution with ISSN or ISBN › peer-review

Abstract

A meshless method for modelling two-phase flows with phase transition is described. The method is based on consideration of three systems: viscous-vortex blobs, thermal-blobs and droplets; and can be applied for numerical simulation of 2D non-isothermal flows of ‘gas-evaporating droplets' in the framework of the one-way coupled two-fluid approach. The carrier phase is viscous incompressible gas. The dispersed phase is presented by a cloud of identical spherical droplets, and, due to evaporation, the radius and mass of droplets are time dependent. The carrier phase parameters are calculated using the viscous-vortex and thermal-blob method; the dispersed phase parameters are calculated using the Lagrangian approach. Two applications have been considered: (i) a standard benchmark - Lamb vortex; (ii) a cold spray injected into a hot quiescent gas. In the latter problem three cases corresponding to three droplet sizes were investigated. The smallest droplets (of the three cases considered) are more readily entrained by the carrier phase and form ring-like structures; the flow shows better mixing. Larger droplets evaporate less intensively. The medium sized droplets collect into two narrow bands stretched along the jet axis. The largest droplets form a two-phase jet, which remains close to the jet axis.

Original language	English
Title of host publication	Proceedings in Applied Mathematics and Mechanics
Pages	685-686
Number of pages	2
Volume	15
Edition	1
DOIs	https://doi.org/10.1002/pamm.201510332
Publication status	Published - 21 Oct 2015
Event	86th Annual Meeting of the International Association of Applied Mathematics and Mechanics (GAMM), Lecce 2015 - Lecce Duration: 21 Oct 2015 → …

Publication series

Name	PAMM
ISSN (Print)	1617-7061

Conference

Conference	86th Annual Meeting of the International Association of Applied Mathematics and Mechanics (GAMM), Lecce 2015
Period	21/10/15 → …

Bibliographical note

This is the accepted version of the following article: Rybdylova, O., Osiptsov, A. N., Sazhin, S. S., Begg, S. and Heikal, M. (2015), A fully meshless method for ‘gas – evaporating droplet’ flow modelling. Proc. Appl. Math. Mech., 15: 685–686. , which has been published in final form at http://onlinelibrary.wiley.com/doi/10.1002/pamm.201510332/abstract. This
article may be used for non-commercial purposes in accordance with the Wiley Self-Archiving Policy.

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Rybdylova_etal.pdfAccepted author manuscript, 267 KBLicence: Unspecified

http://onlinelibrary.wiley.com/doi/10.1002/pamm.201510332/abstractLicence: Unspecified

Steven Begg
- S.M.Beggbrighton.acuk
- School of Arch, Tech and Eng - Reader
- Centre for Precision Health and Translational Medicine
- Advanced Engineering Centre - Director
Person: Academic
Oyuna Rybdylova
- O.Rybdylovabrighton.acuk
- School of Arch, Tech and Eng - Principal Lecturer
- Centre for Precision Health and Translational Medicine
- Advanced Engineering Centre
Person: Academic
Sergei Sazhin
- S.Sazhinbrighton.acuk
- School of Arch, Tech and Eng - Professor of Thermal Physics
- Centre for Precision Health and Translational Medicine
- Advanced Engineering Centre
Person: Academic

Cite this

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title = "A fully meshless method for {\textquoteleft}gas - evaporating droplet' flow modelling",

abstract = "A meshless method for modelling two-phase flows with phase transition is described. The method is based on consideration of three systems: viscous-vortex blobs, thermal-blobs and droplets; and can be applied for numerical simulation of 2D non-isothermal flows of {\textquoteleft}gas-evaporating droplets' in the framework of the one-way coupled two-fluid approach. The carrier phase is viscous incompressible gas. The dispersed phase is presented by a cloud of identical spherical droplets, and, due to evaporation, the radius and mass of droplets are time dependent. The carrier phase parameters are calculated using the viscous-vortex and thermal-blob method; the dispersed phase parameters are calculated using the Lagrangian approach. Two applications have been considered: (i) a standard benchmark - Lamb vortex; (ii) a cold spray injected into a hot quiescent gas. In the latter problem three cases corresponding to three droplet sizes were investigated. The smallest droplets (of the three cases considered) are more readily entrained by the carrier phase and form ring-like structures; the flow shows better mixing. Larger droplets evaporate less intensively. The medium sized droplets collect into two narrow bands stretched along the jet axis. The largest droplets form a two-phase jet, which remains close to the jet axis.",

author = "Oyuna Rybdylova and Alexander Osiptsov and Sergei Sazhin and Steven Begg and Morgan Heikal",

note = "This is the accepted version of the following article: Rybdylova, O., Osiptsov, A. N., Sazhin, S. S., Begg, S. and Heikal, M. (2015), A fully meshless method for {\textquoteleft}gas – evaporating droplet{\textquoteright} flow modelling. Proc. Appl. Math. Mech., 15: 685–686. , which has been published in final form at http://onlinelibrary.wiley.com/doi/10.1002/pamm.201510332/abstract. This article may be used for non-commercial purposes in accordance with the Wiley Self-Archiving Policy.; 86th Annual Meeting of the International Association of Applied Mathematics and Mechanics (GAMM), Lecce 2015 ; Conference date: 21-10-2015",

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Rybdylova, O, Osiptsov, A, Sazhin, S , Begg, S & Heikal, M 2015, A fully meshless method for ‘gas - evaporating droplet' flow modelling. in Proceedings in Applied Mathematics and Mechanics. 1 edn, vol. 15, PAMM, pp. 685-686, 86th Annual Meeting of the International Association of Applied Mathematics and Mechanics (GAMM), Lecce 2015, 21/10/15. https://doi.org/10.1002/pamm.201510332

TY - GEN

T1 - A fully meshless method for ‘gas - evaporating droplet' flow modelling

AU - Rybdylova, Oyuna

AU - Osiptsov, Alexander

AU - Sazhin, Sergei

AU - Begg, Steven

AU - Heikal, Morgan

N1 - This is the accepted version of the following article: Rybdylova, O., Osiptsov, A. N., Sazhin, S. S., Begg, S. and Heikal, M. (2015), A fully meshless method for ‘gas – evaporating droplet’ flow modelling. Proc. Appl. Math. Mech., 15: 685–686. , which has been published in final form at http://onlinelibrary.wiley.com/doi/10.1002/pamm.201510332/abstract. This article may be used for non-commercial purposes in accordance with the Wiley Self-Archiving Policy.

PY - 2015/10/21

Y1 - 2015/10/21

N2 - A meshless method for modelling two-phase flows with phase transition is described. The method is based on consideration of three systems: viscous-vortex blobs, thermal-blobs and droplets; and can be applied for numerical simulation of 2D non-isothermal flows of ‘gas-evaporating droplets' in the framework of the one-way coupled two-fluid approach. The carrier phase is viscous incompressible gas. The dispersed phase is presented by a cloud of identical spherical droplets, and, due to evaporation, the radius and mass of droplets are time dependent. The carrier phase parameters are calculated using the viscous-vortex and thermal-blob method; the dispersed phase parameters are calculated using the Lagrangian approach. Two applications have been considered: (i) a standard benchmark - Lamb vortex; (ii) a cold spray injected into a hot quiescent gas. In the latter problem three cases corresponding to three droplet sizes were investigated. The smallest droplets (of the three cases considered) are more readily entrained by the carrier phase and form ring-like structures; the flow shows better mixing. Larger droplets evaporate less intensively. The medium sized droplets collect into two narrow bands stretched along the jet axis. The largest droplets form a two-phase jet, which remains close to the jet axis.

AB - A meshless method for modelling two-phase flows with phase transition is described. The method is based on consideration of three systems: viscous-vortex blobs, thermal-blobs and droplets; and can be applied for numerical simulation of 2D non-isothermal flows of ‘gas-evaporating droplets' in the framework of the one-way coupled two-fluid approach. The carrier phase is viscous incompressible gas. The dispersed phase is presented by a cloud of identical spherical droplets, and, due to evaporation, the radius and mass of droplets are time dependent. The carrier phase parameters are calculated using the viscous-vortex and thermal-blob method; the dispersed phase parameters are calculated using the Lagrangian approach. Two applications have been considered: (i) a standard benchmark - Lamb vortex; (ii) a cold spray injected into a hot quiescent gas. In the latter problem three cases corresponding to three droplet sizes were investigated. The smallest droplets (of the three cases considered) are more readily entrained by the carrier phase and form ring-like structures; the flow shows better mixing. Larger droplets evaporate less intensively. The medium sized droplets collect into two narrow bands stretched along the jet axis. The largest droplets form a two-phase jet, which remains close to the jet axis.

U2 - 10.1002/pamm.201510332

DO - 10.1002/pamm.201510332

M3 - Conference contribution with ISSN or ISBN

VL - 15

T3 - PAMM

SP - 685

EP - 686

BT - Proceedings in Applied Mathematics and Mechanics

T2 - 86th Annual Meeting of the International Association of Applied Mathematics and Mechanics (GAMM), Lecce 2015

Y2 - 21 October 2015

ER -

A fully meshless method for ‘gas - evaporating droplet' flow modelling

Abstract

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Steven Begg

Oyuna Rybdylova

Sergei Sazhin

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