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100   $a20121010d2012      uy         0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aBoundary layer flow over elastic surfaces and combined method of drag reduction /$fViktor V. Babenko, Ho Hwan Chun, Inwon Lee
205   $a1st ed.
210   $aWaltham, Mass. $cElsevier$d2012
215   $a1 online resource (634 p.)
300   $aDescription based upon print version of record.
311 08$a9780123948069 
311 08$a0123948061 
320   $aIncludes bibliographical references and index.
327   $aFront Cover; Boundary Layer Flow over Elastic Surfaces and Combined Method of Drag Reduction; Copyright Page; Contents; Preface; List of Symbols; Indices; Lower; Upper; Abbreviations; 1 Interaction of the Free Stream with an Elastic Surface; 1.1 Introductory Remarks; 1.2 Basic Types of Coherent Vortical Structures arising in the Flow about a Body, and Methods of their Control; 1.2.1 CVS Types; CVSs in a Boundary Layer; CVSs in the Flow over a Curvilinear Surface; CVSs Generated in Cavities on a Body Surface; Transversal CVSs; Longitudinal CVSs; Tornado-shaped CVSs
327   $aCVSs Generated in Front of or behind an ObstacleTransversal CVSs; Longitudinal CVSs; CVS at Corners of a Body; CVSs in Longitudinal Flow about a Body; CVSs in Flows about Wings; Flow about a Profile at an Angle of Attack; CVSs at Tips of Obstacles and Wings; CVSs on a Triangular Wing; CVSs behind an Oscillating Wing; CVSs in the Flow between Lattices of Profiles; CVS about High-drag Bodies; CVS Generated in Internal Flows; CVS on Boundaries of Submerged or Near-wall Jets; CVSs at Non-stationary (Forward, Rotary) Movement of a Body; CVSs in Geophysical Problems; 1.2.2 Methods of CVS Control
327   $aMethods of CVS Control in a Boundary LayerMethods of CVS Control on Curvilinear Surfaces; Methods of CVS Control in Cavities; Methods of Controlling CVSs Generated behind a Prominence; Methods of CVS Control in Corners; CVS Control Methods in Longitudinal Flow about a Body; Methods of Controlling CVSs Arising at Flows on Wings; Methods of CVS control for flow about a profile at an angle of attack; CVS control on the ends of ledges and wings; CVS Control on a Triangular Wing; CVS Control by means of a Fluctuating Wing; Methods of CVS Control on High-drag Bodies
327   $aMethods of CVS Control in Internal FlowsMethods of CVS Control in Submerged and Near-wall Jets; 1.3 Coherent Structures in a Turbulent Boundary Layer; 1.4 The Flow over Elastic Surfaces; 1.5 Experimental Studies on the Characteristics of Elastic Plates; 1.6 Experimental Investigations of Coherent Vortical Structures in a Transitional Boundary Layer on the Flow over a Rigid Plate; 1.7 Distribution of Disturbing Movement across the Thickness of a Laminar Boundary Layer over a Rigid Surface; 1.8 Physical Process of Laminar-Turbulent Transition of a Boundary Layer over a Rigid Plate
327   $a1.9 Hydrobionic Principles of Drag Reduction1.10 Experimental Investigation of Coherent Vortical Structures in a Transitional Boundary Layer over an Elastic Plate; 1.11 Distribution of Disturbing Movement on the Thickness of a Laminar Boundary Layer on an Elastic Surface; 1.12 Receptivity of the Boundary Layer to Different Disturbances; 1.13 The Boundary Layer as a Heterogeneous, Asymmetric Wave-Guide; 1.14 Control Methods of the CVSs of a Boundary Layer; 1.14.1 Experimental Investigation of a Flow of the Localized Hollows
327   $a1.14.2 Concentrated and Distributed Methods of Formation of Longitudinal Vortical Systems in a Boundary Layer
330   $a While other methods of drag reduction are well-known in marine R&D and ship design environments worldwide, compliant coating drag reduction remains less well-known and poorly understood. This important book presents cutting-edge techniques and findings from research sources not generally accessible by Western researchers and engineers, aiding the application and further development of this potentially important technology.   Beginning with an introduction to drag reduction that places the authors' work on elastic surfaces and combined techniques in context, the book moves on to provide
606   $aBoundary layer
606   $aFrictional resistance (Hydrodynamics)
606   $aFluid dynamics
615  0$aBoundary layer.
615  0$aFrictional resistance (Hydrodynamics)
615  0$aFluid dynamics.
676   $a620.1/064
676   $a620.44
676   $a620.1064
700   $aBabenko$b Viktor V$01823539
701   $aChun$b Ho Hwan$01823540
701   $aLee$b Inwon$01823541
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9911006502103321
996   $aBoundary layer flow over elastic surfaces and combined method of drag reduction$94390260
997   $aUNINA