CFD simulation of aerodynamic forces on the DrivAer car model: Impact of computational parameters

Peng Qin; Alessio Ricci; Bert Blocken

doi:10.1016/j.jweia.2024.105711

CFD simulation of aerodynamic forces on the DrivAer car model: Impact of computational parameters

Peng Qin (Corresponding author), Alessio Ricci, Bert Blocken

Building Physics

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Abstract

Automobile designers and engineers are constantly focusing on aerodynamic optimization with the aim of reducing fuel consumption and particulate and gaseous emissions. In the last decade, a generic car body called DrivAer model has been frequently adopted in numerical and experimental investigations. However, the setup of the CFD domain, grid, turbulence model and numerical approach can significantly impact the accuracy of results and requires sensitivity studies. This is the goal of this study for which wind-tunnel (WT) tests and CFD simulations were carried out on the 1:4 reduced-scale DrivAer notchback model. The target parameters were the drag (C_D) and lift (C_L) coefficients. First, the CFD results were validated with the WT tests. Next, the impact of surface grid resolution, total prism layer height, first prism layer height, growth rate, cell type, upstream and downstream distances, turbulence models, and numerical approaches was systematically investigated. The sensitivity analysis provides a set of guidelines on optimal grid generation. The validation study indicates that a hybrid RANS-LES approach is a good trade-off for an accurate yet economical simulation of the aerodynamic forces. These guidelines are expected to help researchers and practitioners in CFD simulations of car aerodynamics.

Original language	English
Article number	105711
Number of pages	22
Journal	Journal of Wind Engineering and Industrial Aerodynamics
Volume	248
DOIs	https://doi.org/10.1016/j.jweia.2024.105711
Publication status	Published - May 2024

Funding

This work was supported by the Chinese Scholarship Council ( CSC ) funded project 201806260251. This work was carried out on the Dutch national e-infrastructure with the support of SURF Cooperative. During the execution of this project, Alessio Ricci was a postdoctoral fellow of the Research Foundation \u2013 Flanders ( FWO ) (project FWO 1256822N) at KU Leuven and its financial support is gratefully acknowledged. The authors gratefully acknowledge the partnership with Ansys CFD. They are also grateful to the wind-tunnel team of the Eindhoven University of Technology for the support provided during the experimental campaign.

Keywords

Aerodynamic forces
CFD simulations
DrivAer car model
Practical recommendations
Vehicle aerodynamics
Wind-tunnel testing

UN SDGs

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

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abstract = "Automobile designers and engineers are constantly focusing on aerodynamic optimization with the aim of reducing fuel consumption and particulate and gaseous emissions. In the last decade, a generic car body called DrivAer model has been frequently adopted in numerical and experimental investigations. However, the setup of the CFD domain, grid, turbulence model and numerical approach can significantly impact the accuracy of results and requires sensitivity studies. This is the goal of this study for which wind-tunnel (WT) tests and CFD simulations were carried out on the 1:4 reduced-scale DrivAer notchback model. The target parameters were the drag (CD) and lift (CL) coefficients. First, the CFD results were validated with the WT tests. Next, the impact of surface grid resolution, total prism layer height, first prism layer height, growth rate, cell type, upstream and downstream distances, turbulence models, and numerical approaches was systematically investigated. The sensitivity analysis provides a set of guidelines on optimal grid generation. The validation study indicates that a hybrid RANS-LES approach is a good trade-off for an accurate yet economical simulation of the aerodynamic forces. These guidelines are expected to help researchers and practitioners in CFD simulations of car aerodynamics.",

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CFD simulation of aerodynamic forces on the DrivAer car model: Impact of computational parameters

Abstract

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Keywords

UN SDGs

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