An IDDES study of the near-wake flow topology of a simplified heavy vehicle
Artikel i vetenskaplig tidskrift, 2022

The complex wake flow of a GTS (ground transportation system) model contributes to large percentage of the aerodynamic drag force. Therefore, predicting accurate wake flow will help carry out the drag reduction strategies. In this paper, the near-wake flow topology of the GTS was studied at Re = 2.7x10(4) to assess the capability of a hybrid RANS/LES (Reynolds-averaged Navier-Stokes/large eddy simulation) approach, known as IDDES (improved delayed detached eddy simulation). The current study also aims to understand the effects of different computational parameters, e.g. the spatial resolution, time step, residual level, discretization scheme and turbulence model, on this asymmetrical wake flow configuration. A comparison of IDDES with previous water channel tests, well-resolved LES, partially averaged Navier-Stokes and URANS (unsteady RANS) was included to better understand the benefits of this hybrid RANS/LES approach. The results show that on the medium and fine grids, the IDDES produces an asymmetrical flow topology (known as flow state I) in the near-wake of the vertical midplane, as reported in previous studies. The recommended parameters for the time step (1x10(-4) s) and residual level (1x10(-4)) provide sufficient accuracy of wake predictions to show good agreement with experiments. For the convective term of the momentum equation in IDDES, the bounded central difference discretization scheme is proposed to be adopted for discretization. Additionally, URANS cannot accurately capture this asymmetrical flow field. IDDES proves to be capable of predicting the wake flow field of this simplified heavy vehicle with high accuracy. All obtained conclusions can provide references for the aerodynamic drag reduction of the GTS.

IDDES

Asymmetrical wakes

Computational parameter

Heavy vehicle

Författare

Jie Zhang

Central South University

Zhanhao Guo

Central South University

Shuai Han

Central South University

Sinisa Krajnovic

Chalmers, Mekanik och maritima vetenskaper, Strömningslära

John Sheridan

Monash University

Guangjun Gao

Central South University

Transportation Safety and Environment

2631-6765 (ISSN) 2631-4428 (eISSN)

Vol. 4 2 tdac015

Ämneskategorier

Rymd- och flygteknik

Havs- och vattendragsteknik

Strömningsmekanik och akustik

DOI

10.1093/tse/tdac015

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Senast uppdaterat

2023-07-06