Three-dimensional simulation of primary break-up in a close-coupled atomizer

N. Zeoli; H. Tabbara; S. Gu

doi:10.1007/s00339-012-6966-7

Three-dimensional simulation of primary break-up in a close-coupled atomizer

N. Zeoli, H. Tabbara, S. Gu^*

^*Corresponding author for this work

Department of Civil Engineering

Cranfield University

Research output: Contribution to journal › Article › peer-review

32 Citations (Scopus)

Abstract

Until now much of the modelling activity around close-coupled gas atomization has been mainly focused on gas-only flow with discrete phase interaction using Lagrangian-based models. However, this approach is unable to supply valuable information regarding the primary break-up mechanism of the melt being injected. Furthermore, much of existing numerical work is based on two-dimensional axisymmetric geometries, and therefore suffers the absence of three-dimensional flow features. In order to overcome these aspects the authors have carried out an analysis using a three-dimensional geometry by means of an Eulerian, Volume of Fluid, model to accurately present the early stages of melt stream behaviour at the atomizer's melt inlet. The study investigates the mechanisms associated with primary break-up, and the results obtained highlight three modes under which a close-coupled atomizer may operate.

Original language	English
Pages (from-to)	783-792
Number of pages	10
Journal	Applied Physics A: Materials Science and Processing
Volume	108
Issue number	4
DOIs	https://doi.org/10.1007/s00339-012-6966-7
Publication status	Published - Sept 2012

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abstract = "Until now much of the modelling activity around close-coupled gas atomization has been mainly focused on gas-only flow with discrete phase interaction using Lagrangian-based models. However, this approach is unable to supply valuable information regarding the primary break-up mechanism of the melt being injected. Furthermore, much of existing numerical work is based on two-dimensional axisymmetric geometries, and therefore suffers the absence of three-dimensional flow features. In order to overcome these aspects the authors have carried out an analysis using a three-dimensional geometry by means of an Eulerian, Volume of Fluid, model to accurately present the early stages of melt stream behaviour at the atomizer's melt inlet. The study investigates the mechanisms associated with primary break-up, and the results obtained highlight three modes under which a close-coupled atomizer may operate.",

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AU - Tabbara, H.

AU - Gu, S.

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N2 - Until now much of the modelling activity around close-coupled gas atomization has been mainly focused on gas-only flow with discrete phase interaction using Lagrangian-based models. However, this approach is unable to supply valuable information regarding the primary break-up mechanism of the melt being injected. Furthermore, much of existing numerical work is based on two-dimensional axisymmetric geometries, and therefore suffers the absence of three-dimensional flow features. In order to overcome these aspects the authors have carried out an analysis using a three-dimensional geometry by means of an Eulerian, Volume of Fluid, model to accurately present the early stages of melt stream behaviour at the atomizer's melt inlet. The study investigates the mechanisms associated with primary break-up, and the results obtained highlight three modes under which a close-coupled atomizer may operate.

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Three-dimensional simulation of primary break-up in a close-coupled atomizer

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