Drag reduction is a field of study in many engineering disciplines, and its aim is to reduce the fluid-mechanical forces exerted in an object in order to improve its mechanical and/or fuel efficiency. This book provides a guide to the current state-of-the-art in this area of engineering.
Drag reduction is a field of study in many engineering disciplines, and its aim is to reduce the fluid-mechanical forces exerted in an object in order to improve its mechanical and/or fuel efficiency. This book provides a guide to the current state-of-the-art in this area of engineering.
K. S. Choi is the author of Emerging Techniques in Drag Reduction, published by Wiley.
Inhaltsangabe
[1] Reviews on emerging techniques. Riblets: main known and unknown features Riblets and other methods of controlling near-wall turbulence Turbulent drag reduction strategies [2] Riblets and LEBUs. Effects of riblets on the growth of laminar and turbulent boundary layers Near-wall flow structure in a low Reynolds number turbulent boundary layer over misaligned ribs Study of the influence of external manipulators on the near-wall turbulence structure using wall-pressure fluctuations [3] Compliant walls. Improved optimization of compliant walls for transition delay Analysis of four types of viscoelastic coating for turbulent drag reduction The measurement of dynamic properties of viscoelastic materials for turbulent drag reduction [4] New approaches. The feasibility of using passive porous walls for drag reduction Variation of skin friction for a turbulent boundary layer interacting with the controlled longitudinal vortex arrays Reduction of parasitic effects related to the turbulent boundary layer on the fuselage using slot suction [5] Aircraft applications. HLFC for commercial aircraft: ELFIN 1 results on boundary layer suction Improving aerodynamic characteristics by means of turbulence management: a Fokker view Effect of lip configuration on the drag of a circular cavity
[1] Reviews on emerging techniques. Riblets: main known and unknown features Riblets and other methods of controlling near-wall turbulence Turbulent drag reduction strategies [2] Riblets and LEBUs. Effects of riblets on the growth of laminar and turbulent boundary layers Near-wall flow structure in a low Reynolds number turbulent boundary layer over misaligned ribs Study of the influence of external manipulators on the near-wall turbulence structure using wall-pressure fluctuations [3] Compliant walls. Improved optimization of compliant walls for transition delay Analysis of four types of viscoelastic coating for turbulent drag reduction The measurement of dynamic properties of viscoelastic materials for turbulent drag reduction [4] New approaches. The feasibility of using passive porous walls for drag reduction Variation of skin friction for a turbulent boundary layer interacting with the controlled longitudinal vortex arrays Reduction of parasitic effects related to the turbulent boundary layer on the fuselage using slot suction [5] Aircraft applications. HLFC for commercial aircraft: ELFIN 1 results on boundary layer suction Improving aerodynamic characteristics by means of turbulence management: a Fokker view Effect of lip configuration on the drag of a circular cavity
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