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Sökning: FÖRF:(Håkan Danielsson)

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1.
  • Marklund, Ture Jesper, 1970, et al. (författare)
  • Performance of an Automotive Under-Body Diffuser Applied to a Sedan and a Wagon Vehicle
  • 2013
  • Ingår i: SAE International Journal of Passenger Cars - Mechanical Systems. - : SAE International. - 1946-3995 .- 1946-4002. ; 6:1, s. 293-307
  • Tidskriftsartikel (refereegranskat)abstract
    • Reducing resistance forces all over the vehicle is the most sustainable way to reduce fuel consumption. Aerodynamicdrag is the dominating resistance force at highway speeds, and the power required to overcome this force increases by the power three of speed. The exterior body and especially the under-body and rear-end geometry of a passenger car aresignificant contributors to the overall aerodynamic drag. To reduce the aerodynamic drag it is of great importance to have a good pressure recovery at the rear. Since pressure drag is the dominating aerodynamic drag force for a passenger vehicle,the drag force will be a measure of the difference between the pressure in front and at the rear. There is high stagnationpressure at the front which requires a base pressure as high as possible. The pressure will recover from the sides by a taperangle, from the top by the rear wind screen, and from the bottom, by a diffuser. It is not necessarily the case that anoptimized lower part of the rear end for a wagon-type car has the same performance as for a sedan or hatch-back car. Thisstudy focused on the function of an under-body diffuser applied to a sedan and wagon car. The diffuser geometry waschosen from a feasibility stand-point of a production vehicle such as a passenger car. The fluid dynamic function andtheory of the automotive under-body diffuser working as a drag reduction device is discussed. The flow physics of theunder-body and the wake was analyzed to understand the diffuser behaviour in its application to lift and drag forces on avehicle in ground proximity. This work is mainly a numerical analysis that uses the traditional CFD approach from theautomotive industry. Results from this study show a potential to reduce aerodynamic drag of the sedan car approximately10%, and the wagon car by 2-3 %. The possible gain was much bigger for the sedan vehicle and the optimum occurs at ahigher diffuser angle. This was most likely due to the fact that the sedan car in its original shape produced more lift force than the wagon, a wagon usually produces very little lift or even down-force. Lift forces were also reduced with the use of under-body covers with diffuser. The down-force increased, or lift force decreased, linearly with increased diffuser angle, and the trend was the same for both sedan and wagon rear ends. Flow analysis of the wake showed the importance of how the wake is balanced.
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  • Marklund, Ture Jesper, 1970, et al. (författare)
  • FLOW FIELD AROUND AND IN A SAAB 9-3 CONVERTIBLE
  • 2009
  • Ingår i: EUROMECH COLLOQUIUM 509,External aerodynamics of Railway Vehicles Trucks Buses and Cars, Berlin, Germany, March 24--25, 2009. ; , s. 144-157
  • Konferensbidrag (refereegranskat)abstract
    • The aerodynamic comfort in a four seated convertible with open roof is not as goodas many would like it to be. This job was initiated to look at what should be done to improvethis. The car used for this study was a Saab 9-3 convertible. Most of the work was done inCFD in the commercial code Fluent.The flow field in the cockpit was first of all analyzed and evaluated. The problem with convertiblesis the large recirculation bubble that occurs around the passenger compartment. Therear seat passengers are located in an area of this zone with very high wind speeds comparedto the front seat passengers. The flow field was analyzed by several pressure and velocityplots and a method to evaluate comfort grading was developed. The selected main variable tocompare cases was the mean velocity that the passengers head is exposed to. This was foundto be the most affecting parameter because it affects not only the dynamic pressure, but alsothe temperature discomfort. Geometry optimizations of windows, wind shield and wind blockershave been simulated and evaluated. Height and length of the side windows and a numberof different wind deflectors on the wind shield, plus wind blockers inside and behind cockpitwas tested. The results show that the biggest potential of improvement is the wind deflector onthe windshield and some of the wind blockers.
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  • Resultat 1-4 av 4

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