The influence of vehicle body roll motion on aerodynamic characteristics under crosswind condition

Purpose The purpose of this study is investigate the transient aerodynamic characteristics of high-speed vehicle with body roll motion under crosswind condition to improve aerodynamic stability. Design/methodology/approach An overset mesh was used to simulate the rolling motion of the vehicle body....

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Bibliographic Details
Published in:International journal of numerical methods for heat & fluid flow 2023-11, Vol.33 (12), p.4138-4157
Main Authors: Taiming, Huang, Ma, JingMao, Zhang, Li, Hao, Pan, Feng, MingChen, Zeng, Wei, Ou, Changjie
Format: Article
Language:English
Subjects:
Aerodynamic characteristics
Aerodynamic coefficients
Aerodynamic loads
Aerodynamic stability
Air flow
Attitudes
Crosswinds
Cyclic loads
Extreme values
Finite element method
Horizontal orientation
Motion stability
Movement
Numerical methods
Pressure distribution
Rocket launches
Rolling motion
Simulation
Streamlines
Turbulence models
Vehicles
Viscosity
Vortices
Wind effects
Wind tunnel testing
Wind tunnels
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Summary:Purpose The purpose of this study is investigate the transient aerodynamic characteristics of high-speed vehicle with body roll motion under crosswind condition to improve aerodynamic stability. Design/methodology/approach An overset mesh was used to simulate the rolling motion of the vehicle body. A wind tunnel experiment was conducted to validate the numerical method. Findings The results revealed that the vehicle’s aerodynamic characteristics changed periodically with the body’s periodic motion. In the absence of crosswind, the pressure distribution on the left and right sides of the vehicle body was symmetrical, and the speed streamline flowed to the rear of the vehicle in an orderly manner. The maximum aerodynamic lift observed in the transient simulation was −0.089, which is approximately 0.70 times that of the quasi-static simulation experiment. In addition, the maximum aerodynamic side force observed in the transient simulation was 0.654, which is approximately 1.25 times that of the quasi-static simulation experiment. Originality/value The aerodynamic load varies periodically with the vehicle body’s cyclic motion. However, the extreme values of the aerodynamic load do not occur when the vehicle body is at its highest or lowest position. This phenomenon is primarily attributed to the mutual interference of airflow viscosity and the hysteresis effect in the flow field, leading to the formation of a substantial vortex near the wheel. Consequently, the aerodynamic coefficient at each horizontal position becomes inconsistent during the periodic rolling of the vehicle body.
ISSN:0961-5539
0961-5539
1758-6585
DOI:10.1108/HFF-06-2023-0337