An LES Investigation of the Near-Wake Flow Topology of a Simplified Heavy Vehicle

Rao, Anil; Zhang, Jie; Minelli, Guglielmo; Basara, Branislav; Krajnović, Siniša

doi:10.1007/s10494-018-9959-6

Cited by 22 publications

(33 citation statements)

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“…Simulations which accurately capture the wake unsteadiness at high Reynolds number, and which furthermore extend over the large time scales of bi-modal switching, are very costly. Unsteady simulations of simplified bluff body flows have been performed using partially averaged Navier-Stokes (PANS), simulations (Mirzaei, Krajnović & Basara 2015;Rao et al 2018a), unsteady Reynolds-averaged Navier-Stokes simulations (Khalighi, Chen & Iaccarino 2012), detached eddy simulations and large eddy simulations (Krajnović & Davidson 2003;Serre et al 2013;Aljure et al 2014;Östh et al 2014;Rao et al 2018b), some also employing a lattice Boltzmann formulation (Roumeas et al 2009;Lucas et al 2017 The present study achieves what we believe are the first simulations of wake bi-modality, capturing both asymmetric states, for a blunt bluff body. No artificial forcing nor inlet perturbations are applied to trigger bi-modality; the flow develops naturally from a steady inlet velocity condition, with bi-modal switches occurring randomly.…”

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confidence: 66%

Simulations of the bi-modal wake past three-dimensional blunt bluff bodies

2019

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The bi-modal behaviour of the turbulent flow past three-dimensional blunt bluff bodies is simulated using wall-resolved large eddy simulations. Bi-modality (also called bi-stability) is a phenomenon that occurs in the wakes of three-dimensional bluff bodies. It manifests as a random displacement of the wake between preferred off-centre locations. Two bluff bodies are considered in this work: a conventional square-back Ahmed body representative of road cars, and a simplified lorry, which is taller than it is wide, with its aspect ratio corresponding to a 15 % European lorry scale model. To our knowledge, this is the first time that the asymmetric bi-modal switching behaviour of the wake, observed experimentally, has been captured in simulations. The resulting unsteady flow fields are then analysed, revealing instantaneous topological changes in the wake experiencing bi-modal switching. The best-resolved case, the simplified lorry geometry, is then studied in greater detail using modal decomposition to gain insights into the energy content and the dominant frequencies of the wake flow structures associated with the asymmetric states. High-frequency snapshots of the switching sequence allow us to propose that large hairpin vortices are responsible for the triggering of the switching.

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confidence: 66%

Simulations of the bi-modal wake past three-dimensional blunt bluff bodies

2019

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“…It may be recalled that the height-to-width ratio of the GTS (1.392) is approximately equal to the width-to-height ratio of the squareback Ahmed body (1.35), thus indicating that the aspect ratio of the bluff body is a critical parameter in determining the occurrence of bi-stable flow states (Grandemange et al (2013a), McArthur et al (2016)). While the bi-stable states observed in the wake of squareback Ahmed body occur in the lateral midplane, the two flow states in the GTS wake are observed in the vertical midplane; flow state I in McArthur et al (2016) and Gunes (2010), and flow state II in Schmidt et al (2018), Rao et al (2018b), Ortega et al (2004) and Unaune et al (2005). The wake asymmetry (and the resulting bi-stable flow state) was found to originate at low Reynolds numbers for a squareback Ahmed body, where the flow transitions from a steady asymmetric flow state to an unsteady asymmetric flow state at Re ' 410 via an imperfect supercritical bifurcation (Grandemange et al (2012), Cadot et al (2015)), and is observed at Reynolds numbers well into the turbulent region of flow at Re ' 9:5 Â 10 4 .…”

Section: Introductionmentioning

confidence: 97%

“…The GTS model is representative of a truck and a trailer with no intermediate gap, and is commonly used model in the transportation industry to investigate the aerodynamics of heavy vehicles. While a more detailed description of the near-wake flow topology of heavy vehicles has been presented in Rao et al (2018b), where well-resolved LES were undertaken on a simplified GTS model; a brief description of the literature reviewed is presented here.…”

Section: Introductionmentioning

confidence: 99%

“…Recent experimental investigations at Re ¼ 2:7 Â 10 4 by McArthur et al (2016) has shown that the flow topology in the vertical midplane of the GTS model is invariant over a large range of Reynolds numbers (Re, defined as the ratio of the inertial to the viscous forces), with a near identical flow topology being observed at Re ¼ 2 Â 10 6 (Storms et al (2001), Croll et al (1996)). The mean flow topology in this plane is asymmetrical, and consists of a large triangular-shaped vortex on one side, with an elliptical-shaped vortex located opposite to it, and a pair of counter-rotating vortices is observed in the lateral midplane (also see McArthur et al (2016) and Rao et al (2018b) for a detailed description of the flow topology). Previous studies using RANS (Reynolds-averaged Navier-Stokes) turbulence models have failed to accurately predict the asymmetrical flow topology in the vertical midplane (Salari et al (2004), Roy et al (2006), Ghias et al (2008)).…”

Section: Introductionmentioning

confidence: 99%

“…LES for a truncated GTS model by Ortega et al (2004) and detached eddy simulations (DES) by Unaune et al (2005) showed a flow topology in the vertical midplane which is anti-symmetric to that observed in the experiments, while the URANS (unsteady Reynolds-averaged Navier-Stokes) k À ε RNG turbulence model used by Gunes (2010) showed a flow topology similar to the experimental studies at Re ¼ 2 Â 10 6 . With the flow topology remaining invariant over a wide range of Reynolds numbers, well-resolved LES were undertaken by Rao et al (2018b) for a simplified GTS model, with modifications to the frontal A-pillars to obtain solutions on a purely hexahedral mesh, replicating the work of McArthur et al (2016). The mean flow topology in the vertical midplane was anti-symmetric to that observed in McArthur et al (2016) for three meshes of increasing spatial resolution, and the flow topology was also insensitive to small yaw angles of up to 2:5 ∘ (also see Gentile et al (2017), Volpe et al (2014a)).…”

Section: Introductionmentioning

confidence: 99%

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Investigation of the near-wake flow topology of a simplified heavy vehicle using PANS simulations

Rao

Minelli

Zhang

et al. 2018

Journal of Wind Engineering and Industrial Aerodynamics

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The near-wake flow topology of a ground transportation system (GTS) is investigated using partially-averaged Navier-Stokes (PANS) simulations at Re ¼ 2:7 Â 10 4. Recent numerical investigations for the GTS model using large eddy simulations (LES) showed an anti-symmetric flow topology (flow state II) in the vertical midplane compared to that observed in previous experimental studies (flow state I). The geometrical configuration of the GTS permits bi-stable behaviour, and the realisation of each of the two flow states, which are characterised by an asymmetrical flow topology, is achieved by varying the differencing scheme for the convective flux in the PANS simulations; AVL SMART schemes predict flow state I, while central differencing scheme (CDS) predicts flow state II. When the GTS model was placed away from the ground plane, the AVL SMART scheme fails to predict the flow asymmetry resulting in a pair of symmetrical vortices in the vertical midplane, while flow state II topology is observed when CDS is used. The switch from flow state I (II) to flow state II (I) is achieved by changing the numerical scheme from AVL SMART (CDS) to CDS (AVL SMART), with an intermediate transient-symmetric (TS) state being observed during the switching process. The numerical scheme in the PANS simulations thus plays a critical role in determining the initial flow topology in the near wake of the GTS.

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The benefits of green horizontal networks: Lessons learned from sharing charging infrastructure for electric freight vehicles

Melander

Wallström²

2022

Bus Strat Env

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Regulations to reduce greenhouse gas emissions of passenger vehicles are becoming increasingly stringent. The aerodynamic drag is a major contributor to the vehicle's total energy consumption where a large portion is attributed to the base wake. This paper optimises the angles of small trailing edge flaps on a base cavity of a full-scale sports utility vehicle placed in a wind tunnel. The trailing edge flaps are controlled using servos mounted inside the cavity. The flap angles are optimised using a surrogate model based optimisation algorithm with the objective of reducing the aerodynamic drag at different yaw angles and to create a yaw-insensitive geometry by considering several weighted yaw angles to form the driving cycle averaged drag. Low drag designs are further investigated using base pressures and wake measurements. The results show that the base pressures are symmetrised by reducing the crossflow in the wake. As the model is yawed the wake becomes increasingly downwash dominated by a large rotating windward structure which is reduced by the optimised flaps. The cycle averaged drag optimised design has a smaller increase in drag when yawed compared to a design optimised without considering yaw.

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An LES Investigation of the Near-Wake Flow Topology of a Simplified Heavy Vehicle

Cited by 22 publications

References 74 publications

Simulations of the bi-modal wake past three-dimensional blunt bluff bodies

Simulations of the bi-modal wake past three-dimensional blunt bluff bodies

Investigation of the near-wake flow topology of a simplified heavy vehicle using PANS simulations

The benefits of green horizontal networks: Lessons learned from sharing charging infrastructure for electric freight vehicles

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