On the drag reduction of road vehicles with trailing edge-integrated lobed mixers

Rejniak, Aleksandra Anna; Gatto, A.

doi:10.1177/09544070211039697

Cited by 3 publications

(2 citation statements)

References 62 publications

(152 reference statements)

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“…The rear trailer devices are shown to perform the best with combinations with the device attached at the front and the side of the trailer. Rejniak and Gatto [20] explained that the trailing edge devices modifies the structure of the generated wake which results in aerodynamic drag reduction.…”

Section: Introductionmentioning

confidence: 99%

Drag Reduction of a Simplified Truck Model Using Cab Roof Fairings

Ismadi,

Mustaffa

2023

AEJ

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Adverse effects of climate change have prompt transition towards a low-carbon transportation sector. Electrification of the transportation sector is one of the ongoing efforts to reduce the Greenhouse Gas emissions. However, electrification of long haul and heavy-duty vehicles remain a huge challenge due to cost and limitation in the current battery technology. Improving the aerodynamic design of current truck-trailer is an alternative to electrification. This initiative involves modifying the current truck-trailer body design or attaching accessories for aerodynamic drag reduction that can lead to improved fuel economy. In this paper, the effectiveness of four Cab Roof Fairing (CRF) designs on the aerodynamic drag reduction of a simplified truck model is investigated. The results of a numerical simulation performed on a two-dimensional model show that the CRF can reduce aerodynamic drag by up to 45%. The CRF is found to reduce the vertical velocity component of the flow at fore part of the truck body. This leads to a relatively smaller wake region when compared against the baseline case. Wind tunnel results is performed to verify the results of the numerical simulation. At Reynolds number , the measured coefficient of drag reduction is about 6% when compared with the baseline case.

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Section: Introductionmentioning

confidence: 99%

Drag Reduction of a Simplified Truck Model Using Cab Roof Fairings

Ismadi,

Mustaffa

2023

AEJ

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“…In this context, vehicle aerodynamics is a field of research that has received considerable attention to reduce drag and thus, decrease fuel consumption. 1–4 In heavy vehicles, for example, aerodynamic drag can account for up to 80% of total motion resistance, which might be a great source of improvement. 5 Indeed, the fuel consumption of heavy vehicles has already been decreased by 3%–4% when aerodynamic drag was reduced by around 10%.…”

Section: Introductionmentioning

confidence: 99%

Drag reduction of a commercial bus with add-on aerodynamic devices

Ribeiro

Bravo-Mosquera

Ayala-Zuluaga

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part D:

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In the automotive industry, the implementation of drag reduction systems has provided considerable decreases in fuel consumption. These outcomes are in line with the increasing demands of the environmental regulations and consumers’ requirements. Although some studies explain how aerodynamic devices reduce the aerodynamic drag on light and heavy vehicles such as Ahmed bodies and trucks, buses have received almost no attention. For this reason, the flow over the Marcopolo Paradiso 1200 G7 commercial bus and the influence of several aerodynamic devices on the drag force and fuel consumption of the bus are discussed in this article. Three distinct devices (vortex generators, lateral devices, and rails) were proposed after flow visualization tests on the baseline bus. Thus, the entire evaluation consisted of 11 arrangements by combining the three aerodynamic devices. The changes in drag due to all arrangements are estimated using wind tunnel tests, which are validated using Computational Fluid Dynamics simulations. The fuel consumption is evaluated in a simplified long-haul driving cycle between two cities. The devices were able to alter the flow behavior on the bus, resulting in a maximum decrease of 8.63% in the drag coefficient and 3.92% in fuel consumption. Given that the devices used are just first prototypes, we estimate that greater reductions can be achieved with optimized systems. Likewise, this paper probably leads to real applications in other commercial buses due to the evident drag reductions.

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