Underbody aerodynamics: Drag coefficient reduction in road vehicles

Aerodynamics of Cyclist Posture, Bicycle and Helmet Characteristics in Time Trial Stage

Journal of Applied Biomechanics ◽

10.1123/jab.28.3.317 ◽

2012 ◽

Vol 28 (3) ◽

pp. 317-323 ◽

Cited By ~ 8

Author(s):

Vincent Chabroux ◽

Caroline Barelle ◽

Daniel Favier

Keyword(s):

Statistical Analysis ◽

Wind Tunnel ◽

Drag Coefficient ◽

Drag Force ◽

Time Trial ◽

Frontal Area ◽

Significant Gain ◽

Upper Limbs ◽

Force Coefficient ◽

Coefficient Reduction

The present work is focused on the aerodynamic study of different parameters, including both the posture of a cyclist’s upper limbs and the saddle position, in time trial (TT) stages. The aerodynamic influence of a TT helmet large visor is also quantified as a function of the helmet inclination. Experiments conducted in a wind tunnel on nine professional cyclists provided drag force and frontal area measurements to determine the drag force coefficient. Data statistical analysis clearly shows that the hands positioning on shifters and the elbows joined together are significantly reducing the cyclist drag force. Concerning the saddle position, the drag force is shown to be significantly increased (about 3%) when the saddle is raised. The usual helmet inclination appears to be the inclination value minimizing the drag force. Moreover, the addition of a large visor on the helmet is shown to provide a drag coefficient reduction as a function of the helmet inclination. Present results indicate that variations in the TT cyclist posture, the saddle position and the helmet visor can produce a significant gain in time (up to 2.2%) during stages.

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Modelling of Drag Force Reduction for a Waterjet Propulsion System

Latvian Journal of Physics and Technical Sciences ◽

10.2478/lpts-2021-0035 ◽

2021 ◽

Vol 58 (5) ◽

pp. 3-14

Author(s):

M. Cerpinska ◽

M. Irbe ◽

A. Pupurs ◽

K. Burbeckis

Keyword(s):

Drag Coefficient ◽

Drag Force ◽

Velocity Ratio ◽

The Body ◽

Inlet Velocity ◽

Minimum Drag ◽

Simulation Results ◽

Force Reduction ◽

Design Options ◽

Coefficient Reduction

Abstract The paper provides simulation results for SUP (Stand Up Paddle) board appendage resistance. Additional propulsion is added to the SUP board. It is equipped with a waterjet. The waterjet is attached to the board rudder. This increases the drag coefficient for rudder five times. To reduce the drag variable, design options for the waterjet duct were proposed. The simulation tests were performed using SolidWorks Flow software using two types of simulations, namely, the pressure on the body and the flow around the body. The objective was to streamline the bluff duct of the waterjet and thus to create the appendage design with minimum drag force from fluid flow and possibly greater Inlet Velocity Ratio. Calculations showed that rounding-off the edges of waterjet duct resulted in 35 % of drag coefficient reduction, while further streamlining reduced it by additional 10 %.

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Mathematical Modeling of Drag Coefficient Reduction in Circular Cylinder Using Two Passive Controls at Re = 1000

Mathematical and Computational Applications ◽

10.3390/mca23010002 ◽

2018 ◽

Vol 23 (1) ◽

pp. 2

Author(s):

Chairul Imron ◽

Lutfi Mardianto ◽

Basuki Widodo ◽

Tri Yuwono

Keyword(s):

Mathematical Modeling ◽

Circular Cylinder ◽

Drag Coefficient ◽

Coefficient Reduction

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Aerodynamics Analysis and Range Enhancement Study of 81mm Mortar Shell (French Design)

Journal of Advanced Research in Fluid Mechanics and Thermal Sciences ◽

10.37934/arfmts.84.1.148159 ◽

2021 ◽

Vol 84 (1) ◽

pp. 148-159

Author(s):

Roman Kalvin ◽

Juntakan Taweekun ◽

Muhammad Waqas Mustafa ◽

Saba Arif

Keyword(s):

Drag Coefficient ◽

Parabolic Type ◽

Cfd Analysis ◽

Ansys Fluent ◽

Flight Duration ◽

Percent Increase ◽

Fluent Software ◽

Computational Fluid Dynamics Cfd ◽

French Design ◽

Coefficient Reduction

The aim of this research is performing the Computational Fluid Dynamics (CFD) analysis of 81mm Mortar Shell (French Design). The analysis is performed using ANSYS Fluent Software on three different Mach numbers (0.72, 0.76, and 0.84) and results are compared with existing design of 81mm HE M57D A2 Mortar. The drag coefficient of new modified design is found to be less than the existing model. The range of mortar shell is increased by 271 meters because of low drag coefficient with 5.96% percent increase in range and 15.73% decrease in drag coefficient value. Parabolic type; light weighted material fuze casing applied over the existing fuze will result in increase in aerodynamics, range enhancement and drag coefficient reduction. Weight optimization by using lighter material for mortar components and increasing the muzzle velocity can also increase flight duration of the projectile and increase its range. The analysis on 81mm Mortar Shell is a part of range enhancement study to overcome the short fall in required range of mortar shells.

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An overview of passive and active drag reduction methods for bluff body of road vehicles

International Journal of Engineering & Technology ◽

10.14419/ijet.v7i4.13.21328 ◽

2018 ◽

Vol 7 (4.13) ◽

pp. 53

Author(s):

Lay Chuan Eun ◽

Azmin Shakrine Mohd Rafie ◽

Surjatin Wiriadidjaja ◽

Omar Faruqi Marzuki

Keyword(s):

Drag Reduction ◽

Drag Coefficient ◽

Smooth Surface ◽

Bluff Body ◽

Rotation Speed ◽

Rotating Cylinder ◽

Road Vehicles ◽

Reduction Methods ◽

Base Drag ◽

Active Drag

This paper is an overview of results done on bluff body road vehicle’s base drag reduction either by experimental or numerical methods. Two categories of devices are divided that prove certain degrees of effectiveness in reducing the base drag, namely passive and active. The reduction of drag coefficient achieved in existing research ranging from 5% to 50%, which varies for each method and device. However, the higher the achieved drag reduction is, the greater the compensation required is. The compensation comes in various forms to achieve the desirable drag reduction. For passive drag reduction, hump shaped bluff body with boat-tail shows significant drag reduction by 50.9% compared to the other methods. Meanwhile, one of the potential of active drag reductions is by utilizing rotating cylinder. The rotating can reduce the drag on the bluff body by influencing the separation of boundary layer. The drag can be further reduced by enhancing the rotating cylinder with surface roughness and rotation speed. A notable 23% reduction of drag coefficient using rough surface on bluff body vehicle’s is achieved compared to the smooth surface.

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Drag coefficient reduction in the presence of pressure gradients by heat transfer

AIAA Journal ◽

10.2514/3.15021 ◽

2001 ◽

Vol 39 ◽

pp. 2262-2267

Author(s):

C. Feiler

Keyword(s):

Heat Transfer ◽

Drag Coefficient ◽

Pressure Gradients ◽

Coefficient Reduction

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The Effect of Plasma Actuator Placement on Drag Coefficient Reduction of Ahmed Body as an Aerodynamic Model

International Journal of Technology ◽

10.14716/ijtech.v7i2.2994 ◽

2016 ◽

Vol 7 (2) ◽

pp. 306 ◽

Cited By ~ 4

Author(s):

James Julian ◽

Harinaldi Harinaldi ◽

Budiarso Budiarso ◽

Revan Difitro ◽

Parker Stefan

Keyword(s):

Drag Coefficient ◽

Plasma Actuator ◽

Aerodynamic Model ◽

Actuator Placement ◽

Coefficient Reduction ◽

Ahmed Body

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A Wind-Tunnel Study of the Effect of Gap Flow and Gap Seals on the Aerodynamic Drag of Tractor-Trailer Trucks

Journal of Fluids Engineering ◽

10.1115/1.3448703 ◽

1978 ◽

Vol 100 (4) ◽

pp. 434-438 ◽

Cited By ~ 2

Author(s):

F. T. Buckley ◽

C. H. Marks

Keyword(s):

Wind Tunnel ◽

Drag Coefficient ◽

Aerodynamic Drag ◽

Motor Fuel ◽

Center Line ◽

Gap Flow ◽

Yaw Angle ◽

Wind Tunnel Study ◽

Gap Width ◽

Coefficient Reduction

The effect of gap width on the aerodynamic drag of a cab-over-engine tractor-trailer combination has been investigated for full-scale gap widths ranging from 0.61 m (24 in) to 1.83 m (72 in.) over a yaw angle range of 0 to 20 deg. The average drag on the vehicle was found to increase by 16 percent as the gap width increased from 0.61 m to 1.83 m. Drag reductions were found when a vertical seal was placed along the vehicle center line between the tractor and the trailer. Generally, the drag reduction increased as the percentage of gap width that was sealed increased, and as the yaw angle increased. The average drag coefficient reduction provided by a full gap seal increased from 0.02 to 0.05 as the gap width increased from 0.61 m to 1.4 m and then decreased slightly for gap widths up to 1.83 m. The effect of vehicle configuration on gap seal effectiveness was evaluated for a gap width of 1.3 m (51 in.) using models of six different tractors and two different trailers. The average drag coefficient reductions that were found ranged from 0.04 to 0.08 with 83 percent of the data being either 0.04 or 0.05. It is shown that the use of gap seals on the nearly half-million vehicles which comprise the nation’s long-haul trucking fleet can result in the conservation of about 1.4 × 109 liters (0.37 × 109 gal) of motor fuel each year.

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