| Description |
1 online resource (337 pages) |
| Contents |
Cover; Half Title; Title Page; Copyright Page; Dedication Page; Contents; Preface; Author; 1: Basic Concepts; 1.1 Historical Background; 1.2 Simple Demonstrations of the Coanda Effect; 1.3 Manipulation of Coanda Flow; 1.3.1 Flow Control Definition; 1.3.2 Role of Shear and Boundary Layers in Coanda Flow Control; 1.3.3 Flow Control Classification; 1.3.3.1 Contact or Non-Surface-Contact-Based; 1.3.3.2 Energy-Expenditure-Based; 1.3.4 Flow Control Methodologies; 1.3.5 Flow Control Outcomes; 1.4 Understanding the Coanda Effect through Simple Sketches; 1.4.1 Coanda Effect in Incompressible Flow |
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1.4.1.1 Jet Flow over a Straight Wall (i.e., Wall with No Curvature)1.4.1.2 Jet Flow over a Wall with Curvature; 1.4.1.3 Jet Flow through a Channel or Tube; 1.4.1.4 Jet Flow in a Channel with Sudden Expansion; 1.4.2 Coanda Effect in Compressible Flow; 1.5 Basic Flows Associated with Creating the Coanda Effect; 1.5.1 Consideration of Free Shear and Boundary Layer Flows; 1.5.1.1 Velocity Profiles of Free Shear and Boundary Layer Flows; 1.5.1.2 Laminar or Turbulent Flow from Velocity Profiles; 1.5.1.3 Inflectional Velocity Profiles |
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1.5.1.4 Displacement and Momentum Thickness from Velocity Profiles1.5.2 Free Jet Flow; 1.5.2.1 Development of a Free Jet; 1.5.2.2 Supersonic Jet Development; 1.5.3 Flow Entrainment in a Jet; 1.5.4 Instabilities in Shear Layers; 1.5.4.1 Role of Viscosity; 1.5.4.2 Role of Reynolds Number and Mach Number; 1.5.5 Wall Flow and Its Development; 1.5.6 Transition in Boundary Layers; 1.5.6.1 The Routes to Turbulence; 1.5.6.2 Role of Viscosity and Reynolds Number; 1.5.7 Flow Separation; 1.5.7.1 Laminar Boundary Layer Separation; 1.5.7.2 Unsteady Boundary Layer Separation |
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1.5.7.3 Turbulent Boundary Layer Separation1.5.7.4 Three-Dimensional Boundary Layer Separation; 1.6 Concluding Remarks; References; 2: Tools of Investigation; 2.1 Mathematical Treatment; 2.1.1 Conservation Equations; 2.1.1.1 Conservation of Mass Equation; 2.1.1.2 Conservation of Momentum Equation; 2.1.1.3 Conservation of Energy Equation; 2.1.2 Reducing the Number of Unknowns; 2.1.3 Well-Posed Incompressible Equations; 2.1.3.1 Non-Turbulent Flows; 2.1.3.2 Turbulent Flows; 2.1.4 "Karman Approach" for Incompressible and Compressible Flows |
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2.1.5 Equations for Fluid Flow near a Wall with Little or No Curvature2.1.6 Equations for Fluid Flow near a Wall with Curvature; 2.1.6.1 First Order Boundary Layer Equations; 2.1.6.2 Some Comments on the Above Equations; 2.1.6.3 Second Order Boundary Layer Equations; 2.1.6.4 Reduction of Second Order Boundary Layer Equations for Two Dimensions; 2.1.7 Special Mathematical Models for Blowing; 2.1.7.1 Viscous Diffusion; 2.1.7.2 Point Vortex Model; 2.2 Physical Experimentation; 2.2.1 Facilities for Controlled Experiment; 2.2.2 Flow Diagnostic Techniques; 2.2.3 Pressure-Based Measurement Technique |
| Notes |
2.2.3.1 One-Dimensional Velocity Measurement |
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Print version record |
| Subject |
Aeronautics.
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Body fluid flow.
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Coanda effect -- Industrial applications
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Coanda effect -- Scientific applications
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Fluidics.
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Hydraulic engineering.
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aviation.
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aeronautics.
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hydraulic engineering.
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Aeronautics
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Body fluid flow
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Fluidics
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Hydraulic engineering
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| Form |
Electronic book
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| ISBN |
9780429805448 |
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0429805446 |
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