Active flow control analysis at the rear of an SUV

Eulalie, Yoann; Fournier, Elisabeth; Gilotte, Philippe; Holst, David; Johnson, Shaun A; Nayeri, Christian Navid; Schütz, Thomas; Wieser, Dirk

doi:10.1108/hff-06-2017-0230

Cited by 7 publications

(6 citation statements)

References 8 publications

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“…Typical Cd variations on a full-scale SUV, are characterized by a symmetric curve depending on the yaw angle. Minimum Cd value is at the centre position, corresponding to a symmetric rear static pressure distribution (Eulalie et al , 2018). For positive or negative yaw angles, lowest static pressure values are always on the leeward lateral side.…”

Section: Pressure Measurementsmentioning

confidence: 99%

Aerodynamical characteristics of a reduced scale ground vehicle according to yaw angle variations

Gilotte

Mortazavi

Carvajal

et al. 2021

HFF

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Purpose The purpose of this paper is to study pressure measurement correlations, as the location of the pressure sensors should enable to capture variation of the drag force depending on the yaw angle and some geometrical modifications. Design/methodology/approach The present aerodynamical study, performed on a reduced scale mock-up representing a sport utility vehicle, involves both numerical and experimental investigations. Experiments performed in a wind tunnel facility deal with drag and pressure measurements related to the side wind variation. The pressure sensor locations are deduced from wall streamlines computed from large eddy simulation results on the external surfaces of the mock-up. Findings After validation of the drag coefficient (Cd) values computed with an aerodynamic balance, measurements should only imply pressure tap mounted on the vehicle to perform real driving emission (RDE) tests. Originality/value Relation presented in this paper between pressure coefficients measured on a side sensor and the drag coefficient data must enable to better quantify the drag force contribution of a ground vehicle in RDE tests.

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Section: Pressure Measurementsmentioning

confidence: 99%

Aerodynamical characteristics of a reduced scale ground vehicle according to yaw angle variations

Gilotte

Mortazavi

Carvajal

et al. 2021

HFF

Self Cite

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“…These experiments are done with PIV, for the active method numerical analysis is rare [55][56][57]. Low amounts can be due to the fact that the validation measurement already has enough information.…”

Section: Active Systemsmentioning

confidence: 99%

Quantitative Analysis of Drag Reduction Methods for Blunt Shaped Automobiles

Szodrai

2020

Applied Sciences

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In fluid mechanics, drag related problems aim to reduce fuel consumption. This paper is intended to provide guidance for drag reduction applications on cars. The review covers papers from the beginning of 2000 to April 2020 related to drag reduction research for ground vehicles. Research papers were collected from the library of Science Direct, Web of Science, and Multidisciplinary Digital Publishing Institute (MDPI). Achieved drag reductions of each research paper was collected and evaluated. The assessed research papers attained their results by wind tunnel measurements or calculating validated numerical models. The study mainly focuses on hatchback and notchback shaped ground vehicle drag reduction methods, such as active and passive systems. Quantitative analysis was made for the drag reduction methods where relative and absolute drag changes were used for evaluations.

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“…The pressure drag is the main component of aerodynamic drag (Edwige et al , 2018), which results in a low average pressure on the rear surface because of the unsteady rear wake (Eulalie et al , 2018; Metka and Gregory, 2015). For the features of long bluff body and square geometry, the negative pressure zone and high energy loss in the wake region emerge as a result of the flow separation caused by the square edge around the rear surface.…”

Section: Introductionmentioning

confidence: 99%

Enhancing turbulence: a potential strategy for drag reduction based on ground transportation systems (GTS) model

Yang

Liu

2021

HFF

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Purpose The purpose of this paper is to investigate the mechanism and performance of a potential strategy, which is to enhance turbulence to carry out drag reduction for heavy trucks. Design/methodology/approach Enhancing turbulence deflector (ETD) was placed on the roof surface of an ground transportation system (GTS) to investigate the drag reduction mechanism of enhancing turbulence. Transition shear-stress transport improved delay detach eddy simulation model was adopted to simulate the unsteady small-scale flow around the ETD. Findings By optimizing the three influencing factors, diameter, streamwise length and streamwise position, the optimized ETD has achieved a maximum drag reduction of 7.04%. The analysis of flow field results shows that enhancing turbulence can effectively suppress flow separation and reduce the negative pressure intensity in the wake region of GTS. Originality/value The present work provides another potential possibility for the improvement of the aerodynamic performance of heavy trucks.

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Active flow control analysis at the rear of an SUV

Cited by 7 publications

References 8 publications

Aerodynamical characteristics of a reduced scale ground vehicle according to yaw angle variations

Aerodynamical characteristics of a reduced scale ground vehicle according to yaw angle variations

Quantitative Analysis of Drag Reduction Methods for Blunt Shaped Automobiles

Enhancing turbulence: a potential strategy for drag reduction based on ground transportation systems (GTS) model

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