2011
DOI: 10.1504/ijad.2011.038846
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Drag reduction by pulsed jets on strongly unstructured wake: towards the square back control

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Cited by 27 publications
(21 citation statements)
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“…3.4 Pulsed Jet Effectiveness of pulsed jet has been investigated experimentally on the suppression of the rear slant recirculation bubble, without acting on longitudinal structures on an Ahmed body with 25° slant angle and it is found that 6 -8% maximum drag reduction is obtained depending on the geometric and jet exhaust configurations that show different sensitivity to the forcing parameters [30]. Another investigation has been carried out with an Ahmed body having 35° slant angle where 20% drag reduction is achieved that confirms the interest in using pulsed jets (shown in Figure 6) in order to reduce aerodynamic drag and pollutant emission [31]. By acting on the kinematic of the wake, this control technique changes the wall pressure and shear stress distributions on geometry of vehicles and generates evolutions in energy dissipation per unit process [32].…”
Section: Synthetic Jetssupporting
confidence: 53%
See 1 more Smart Citation
“…3.4 Pulsed Jet Effectiveness of pulsed jet has been investigated experimentally on the suppression of the rear slant recirculation bubble, without acting on longitudinal structures on an Ahmed body with 25° slant angle and it is found that 6 -8% maximum drag reduction is obtained depending on the geometric and jet exhaust configurations that show different sensitivity to the forcing parameters [30]. Another investigation has been carried out with an Ahmed body having 35° slant angle where 20% drag reduction is achieved that confirms the interest in using pulsed jets (shown in Figure 6) in order to reduce aerodynamic drag and pollutant emission [31]. By acting on the kinematic of the wake, this control technique changes the wall pressure and shear stress distributions on geometry of vehicles and generates evolutions in energy dissipation per unit process [32].…”
Section: Synthetic Jetssupporting
confidence: 53%
“…Maximum contribution of drag reduction for different control methods is shown in Figure 22. From the above analysis, it is seen that the drag reduction for active control system could be as much as 20% by using the pulse jet [31,32] and plasma actuator [39] as shown in Figure 20 and 22. On the other hand, for passive control system, the drag could be decreased to 21.2% by using Flaps [50] as shown in Figure 21 and 22.…”
Section: Discussionmentioning
confidence: 93%
“…This is not the only option to improve the aerodynamics of a car. There are also ways of controlling the flow around the vehicle by means of continuous or oscillating air blowing [6,4,14]. In this work, numerical calculations were performed to examine the aerodynamic drag force created on individual body parts of the high energy efficiency vehicle, specially designed for the Shell Eco-marathon competition.…”
Section: Introductionmentioning
confidence: 99%
“…To improve this negative situation, one way is to use active flow control to reduce drag. Vehicle wakes are characterized by both large pressure drag and coherent structures [9,5,2,7]. In addition, their 3D features, which contribute for large part of performance losses, make the physical mechanisms at play even more complex.…”
Section: Introductionmentioning
confidence: 99%