Recent advances in physical understanding and quantitative prediction of impinging-jet dynamics and atomization

Xiaodong CHEN; Vigor YANG

doi:10.1016/j.cja.2018.10.010

Recent advances in physical understanding and quantitative prediction of impinging-jet dynamics and atomization

Xiaodong CHEN^*, Vigor YANG

^*Corresponding author for this work

School of Aerospace Engineering

School of Materials Science and Engineering, Georgia Institute of Technology

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

50 Citations (Scopus)

Abstract

Impinging-jet injectors are widely used in liquid propulsion applications, since their simple configuration provides reliable and efficient atomization. The flowfield involves a series of complicated spatio-temporal evolutions. Much effort has been directed toward understanding the underlying physics and developing quantitative predictions of impinging-jet atomization. This paper summarizes the recent advances in this direction, including state-of-the-art theoretical, experimental, and numerical studies, along with representative results. Finally, concluding remarks address remaining challenges and highlight modeling capabilities of high-fidelity simulations.

Original language	English
Pages (from-to)	45-57
Number of pages	13
Journal	Chinese Journal of Aeronautics
Volume	32
Issue number	1
DOIs	https://doi.org/10.1016/j.cja.2018.10.010
Publication status	Published - Jan 2019

Keywords

Computational fluid dynamics
Flow instability
Flow visualization
Gas/liquid interfacial dynamics
Impinging-jet atomization
Theoretical models
Two-phase flow

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10.1016/j.cja.2018.10.010

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abstract = "Impinging-jet injectors are widely used in liquid propulsion applications, since their simple configuration provides reliable and efficient atomization. The flowfield involves a series of complicated spatio-temporal evolutions. Much effort has been directed toward understanding the underlying physics and developing quantitative predictions of impinging-jet atomization. This paper summarizes the recent advances in this direction, including state-of-the-art theoretical, experimental, and numerical studies, along with representative results. Finally, concluding remarks address remaining challenges and highlight modeling capabilities of high-fidelity simulations.",

keywords = "Computational fluid dynamics, Flow instability, Flow visualization, Gas/liquid interfacial dynamics, Impinging-jet atomization, Theoretical models, Two-phase flow",

author = "Xiaodong CHEN and Vigor YANG",

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AB - Impinging-jet injectors are widely used in liquid propulsion applications, since their simple configuration provides reliable and efficient atomization. The flowfield involves a series of complicated spatio-temporal evolutions. Much effort has been directed toward understanding the underlying physics and developing quantitative predictions of impinging-jet atomization. This paper summarizes the recent advances in this direction, including state-of-the-art theoretical, experimental, and numerical studies, along with representative results. Finally, concluding remarks address remaining challenges and highlight modeling capabilities of high-fidelity simulations.

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KW - Flow instability

KW - Flow visualization

KW - Gas/liquid interfacial dynamics

KW - Impinging-jet atomization

KW - Theoretical models

KW - Two-phase flow

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Recent advances in physical understanding and quantitative prediction of impinging-jet dynamics and atomization

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Keywords

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