Numerical investigation on the mechanism of the effects of plate vibration on mixing and combustion of transverse hydrogen injection

Kun Ye; Zhengyin Ye; Chunna Li; Jie Wu

doi:10.1016/j.ijhydene.2018.10.123

Numerical investigation on the mechanism of the effects of plate vibration on mixing and combustion of transverse hydrogen injection

Kun Ye, Zhengyin Ye, Chunna Li, Jie Wu

School of Aeronautics

Northwestern Polytechnical University Xian

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

11 Scopus citations

Abstract

This study numerically investigates the effects of plate vibration and deformation on the combustion performance, the shock wave structure, the mixing characteristics and the flame structure for transverse hydrogen injection. The finite-rate method is used to simulate combustion. Results show that plate vibration causes the combustion performance to oscillate both temporally and spatially, while plate deformation can only change the static characteristics of the flow. Plate vibration and deformation increase the intensity and number of shock wave reflections in different ways. In addition, both plate vibration and deformation increase the momentum flux ratio and the jet penetration depth, which enhances mixing. Finally, plate vibration widens the flame and moves it upward to a greater extent than plate deformation.

Original language	English
Pages (from-to)	22636-22648
Number of pages	13
Journal	International Journal of Hydrogen Energy
Volume	43
Issue number	50
DOIs	https://doi.org/10.1016/j.ijhydene.2018.10.123
State	Published - 13 Dec 2018

Keywords

Combustion efficiency
Mixing characteristics
Plate deformation
Plate vibration
Supersonic combustion
Transverse hydrogen injection

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.ijhydene.2018.10.123

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title = "Numerical investigation on the mechanism of the effects of plate vibration on mixing and combustion of transverse hydrogen injection",

abstract = "This study numerically investigates the effects of plate vibration and deformation on the combustion performance, the shock wave structure, the mixing characteristics and the flame structure for transverse hydrogen injection. The finite-rate method is used to simulate combustion. Results show that plate vibration causes the combustion performance to oscillate both temporally and spatially, while plate deformation can only change the static characteristics of the flow. Plate vibration and deformation increase the intensity and number of shock wave reflections in different ways. In addition, both plate vibration and deformation increase the momentum flux ratio and the jet penetration depth, which enhances mixing. Finally, plate vibration widens the flame and moves it upward to a greater extent than plate deformation.",

keywords = "Combustion efficiency, Mixing characteristics, Plate deformation, Plate vibration, Supersonic combustion, Transverse hydrogen injection",

author = "Kun Ye and Zhengyin Ye and Chunna Li and Jie Wu",

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T1 - Numerical investigation on the mechanism of the effects of plate vibration on mixing and combustion of transverse hydrogen injection

AU - Ye, Kun

AU - Ye, Zhengyin

AU - Li, Chunna

AU - Wu, Jie

PY - 2018/12/13

Y1 - 2018/12/13

N2 - This study numerically investigates the effects of plate vibration and deformation on the combustion performance, the shock wave structure, the mixing characteristics and the flame structure for transverse hydrogen injection. The finite-rate method is used to simulate combustion. Results show that plate vibration causes the combustion performance to oscillate both temporally and spatially, while plate deformation can only change the static characteristics of the flow. Plate vibration and deformation increase the intensity and number of shock wave reflections in different ways. In addition, both plate vibration and deformation increase the momentum flux ratio and the jet penetration depth, which enhances mixing. Finally, plate vibration widens the flame and moves it upward to a greater extent than plate deformation.

AB - This study numerically investigates the effects of plate vibration and deformation on the combustion performance, the shock wave structure, the mixing characteristics and the flame structure for transverse hydrogen injection. The finite-rate method is used to simulate combustion. Results show that plate vibration causes the combustion performance to oscillate both temporally and spatially, while plate deformation can only change the static characteristics of the flow. Plate vibration and deformation increase the intensity and number of shock wave reflections in different ways. In addition, both plate vibration and deformation increase the momentum flux ratio and the jet penetration depth, which enhances mixing. Finally, plate vibration widens the flame and moves it upward to a greater extent than plate deformation.

KW - Combustion efficiency

KW - Mixing characteristics

KW - Plate deformation

KW - Plate vibration

KW - Supersonic combustion

KW - Transverse hydrogen injection

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SN - 0360-3199

VL - 43

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JO - International Journal of Hydrogen Energy

JF - International Journal of Hydrogen Energy

IS - 50

ER -

Numerical investigation on the mechanism of the effects of plate vibration on mixing and combustion of transverse hydrogen injection

Abstract

Keywords

UN SDGs

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