A coupled CFD and wake model simulation of helicopter rotor in hover

Qinghe Zhao; Xiaodong Li

doi:10.1088/1755-1315/128/1/012116

A coupled CFD and wake model simulation of helicopter rotor in hover

Qinghe Zhao
, Xiaodong Li

School of Energy and Power Engineering

Beihang University

Research output: Contribution to journal › Conference article › peer-review

1 Scopus citations

Abstract

The helicopter rotor wake plays a dominant role since it affects the flow field structure. It is very difficult to predict accurately of the flow-field. The numerical dissipation is so excessive that it eliminates the vortex structure. A hybrid method of CFD and prescribed wake model was constructed by applying the prescribed wake model as much as possible. The wake vortices were described as a single blade tip vortex in this study. The coupling model is used to simulate the flow field. Both non-lifting and lifting cases have been calculated with subcritical and supercritical tip Mach numbers. Surface pressure distributions are presented and compared with experimental data. The calculated results agree well with the experimental data.

Original language	English
Article number	012116
Journal	IOP Conference Series: Earth and Environmental Science
Volume	128
Issue number	1
DOIs	https://doi.org/10.1088/1755-1315/128/1/012116
State	Published - 26 Mar 2018
Event	2017 3rd International Conference on Energy Equipment Science and Engineering, ICEESE 2017 - Beijing, China Duration: 28 Dec 2017 → 31 Dec 2017

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10.1088/1755-1315/128/1/012116

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title = "A coupled CFD and wake model simulation of helicopter rotor in hover",

abstract = "The helicopter rotor wake plays a dominant role since it affects the flow field structure. It is very difficult to predict accurately of the flow-field. The numerical dissipation is so excessive that it eliminates the vortex structure. A hybrid method of CFD and prescribed wake model was constructed by applying the prescribed wake model as much as possible. The wake vortices were described as a single blade tip vortex in this study. The coupling model is used to simulate the flow field. Both non-lifting and lifting cases have been calculated with subcritical and supercritical tip Mach numbers. Surface pressure distributions are presented and compared with experimental data. The calculated results agree well with the experimental data.",

author = "Qinghe Zhao and Xiaodong Li",

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AU - Zhao, Qinghe

AU - Li, Xiaodong

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PY - 2018/3/26

Y1 - 2018/3/26

N2 - The helicopter rotor wake plays a dominant role since it affects the flow field structure. It is very difficult to predict accurately of the flow-field. The numerical dissipation is so excessive that it eliminates the vortex structure. A hybrid method of CFD and prescribed wake model was constructed by applying the prescribed wake model as much as possible. The wake vortices were described as a single blade tip vortex in this study. The coupling model is used to simulate the flow field. Both non-lifting and lifting cases have been calculated with subcritical and supercritical tip Mach numbers. Surface pressure distributions are presented and compared with experimental data. The calculated results agree well with the experimental data.

AB - The helicopter rotor wake plays a dominant role since it affects the flow field structure. It is very difficult to predict accurately of the flow-field. The numerical dissipation is so excessive that it eliminates the vortex structure. A hybrid method of CFD and prescribed wake model was constructed by applying the prescribed wake model as much as possible. The wake vortices were described as a single blade tip vortex in this study. The coupling model is used to simulate the flow field. Both non-lifting and lifting cases have been calculated with subcritical and supercritical tip Mach numbers. Surface pressure distributions are presented and compared with experimental data. The calculated results agree well with the experimental data.

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JO - IOP Conference Series: Earth and Environmental Science

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T2 - 2017 3rd International Conference on Energy Equipment Science and Engineering, ICEESE 2017

Y2 - 28 December 2017 through 31 December 2017

ER -

A coupled CFD and wake model simulation of helicopter rotor in hover

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