Transition Location Effect on Shock Wave Boundary Layer Interaction
Anna Petersen (Hrsg.), Flavien Billard (Hrsg.), Pawel Flaszynski (Hrsg.), Patrick Grothe (Hrsg.), Jean-Paul Dussauge (Hrsg.), Piotr Doerffer (Hrsg.), Holger Babinsky (Hrsg.)
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Springer International Publishing
Naturwissenschaften, Medizin, Informatik, Technik / Maschinenbau, Fertigungstechnik
Beschreibung
This book presents experimental and numerical findings on reducing shock-induced separation by applying transition upstream the shock wave. The purpose is to find out how close to the shock wave the transition should be located in order to obtain favorable turbulent boundary layer interaction.
The book shares findings obtained using advanced flow measurement methods and concerning e.g. the transition location, boundary layer characteristics, and the detection of shock wave configurations. It includes a number of experimental case studies and CFD simulations that offer valuable insights into the flow structure. It covers RANS/URANS methods for the experimental test section design, as well as more advanced techniques, such as LES, hybrid methods and DNS for studying the transition and shock wave interaction in detail. The experimental and numerical investigations presented here were conducted by sixteen different partners in the context of the TFAST Project.The general focus is on determining if and how it is possible to improve flow performance in comparison to laminar interaction. The book mainly addresses academics and professionals whose work involves the aerodynamics of internal and external flows, as well as experimentalists working with compressible flows. It will also be of benefit for CFD developers and users, and for students of aviation and propulsion systems alike.
Kundenbewertungen
Transonic Wing Flow, Models of Flow Control Devices, Simulations of 3-D transonic Wing, High Pressure Turbine Blade, Reduce Flow Separation, Transition Location Effect, Compressible Flows, TFAST Project, Induced Transition to Turbulence, URANS Methods, fluid- and aerodynamics, Compressor and Fan Blade Aerodynamics, Transonic Turbine Flow, Hybrid RANS-LENS Methods, Shock Induced Separation, Laminar and Turbulent Boundary Layer