Applied fluid mechanics for engineers /

Complete coverage of fluid mechanics for engineering applications. This comprehensive volume leads you from essential fluid mechanics concepts through to practical engineering applications. After an overview of tensor analysis, the book discusses the kinematics of flow motion and the conservation la...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Schobeiri, Meinhard (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: New York, N.Y. : McGraw-Hill Education, [2014]
Edición:First edition.
Colección:McGraw-Hill's AccessEngineering.
Temas:
Fluid mechanics.
Turbulence.
Laminar flow.
Electronic books.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • B. Preface
  • C. Nomenclature
  • Greek Symbols
  • Subscripts, Superscripts
  • 1. Introduction
  • Continuum Hypothesis
  • Molecular Viscosity
  • Flow Classification
  • Shear-Deformation Behavior of Fluids
  • References
  • 2. Vector and Tensor Analysis?Applications to Fluid Mechanics
  • Tensors in Three-Dimensional Euclidean Space
  • Vector Operations: Scalar, Vector, and Tensor Products
  • Contraction of Tensors
  • Differential Operators in Fluid Mechanics
  • Operator ? Applied to Different Functions
  • Problems
  • References
  • 3. Kinematics of Fluid Motion
  • Material and Spatial Description of the Flow Field
  • Translation, Deformation, Rotation
  • Reynolds Transport Theorem
  • Pathline, Streamline, Streakline
  • Problems
  • References
  • 4. Differential Balances in Fluid Mechanics
  • Mass Flow Balance in Stationary Frame of Reference
  • Differential Momentum Balance in Stationary Frame of Reference
  • Some Discussions on Navier-Stokes Equations
  • Energy Balance in Stationary Frame of Reference
  • Differential Balances in Rotating Frame of Reference
  • Problems
  • References
  • 5. Integral Balances in Fluid Mechanics
  • Mass Flow Balance
  • Balance of Linear Momentum
  • Balance of Moment of Momentum
  • Balance of Energy
  • Application of Energy Balance to Engineering Components
  • Irreversibility, Entropy Increase, Total Pressure Loss
  • Theory of Thermal Turbomachinery Stages
  • Dimensionless Stage Parameters
  • Unified Description of a Turbomachinery Stage
  • Turbine and Compressor Cascade Flow Forces
  • Problems
  • References
  • 6. Inviscid Potential Flows
  • Incompressible Potential Flows
  • Complex Potential for Plane Flows
  • Superposition of Potential Flow Elements
  • Blasius' Theorem
  • Kutta-Joukowski Theorem
  • Conformal Transformation
  • Vortex Theorems
  • Problems
  • References
  • 7. Viscous Laminar Flow
  • Steady Viscous Flow Through a Curved Channel
  • Temperature Distribution
  • Steady Parallel Flows
  • Unsteady Laminar Flows
  • Problems
  • References
  • 8. Laminar-Turbulent Transition
  • Stability of Laminar Flow
  • Laminar-Turbulent Transition
  • Stability of Laminar Flows
  • Physics of an Intermittent Flow, Transition
  • Implementation of Intermittency into Navier-Stokes Equations
  • Problems
  • References
  • 9. Turbulent Flow, Modeling
  • Fundamentals of Turbulent Flows
  • Averaging Fundamental Equations of Turbulent Flow
  • Turbulence Modeling
  • Grid Turbulence
  • Numerical Simulation Examples
  • Problems
  • Project
  • References
  • 10. Free Turbulent Flow
  • Types of Free Turbulent Flows
  • Fundamental Equations of Free Turbulent Flows
  • Free Turbulent Flows at Zero Pressure Gradient
  • Wake Flow at Nonzero Lateral Pressure Gradient
  • Projects
  • References
  • 11. Boundary Layer Theory
  • Boundary Layer Approximations
  • Exact Solutions of Laminar Boundary Layer Equations
  • Boundary Layer Theory Integral Method
  • Turbulent Boundary Layers
  • Boundary Layer, Differential Treatment
  • Measurement of Boundary Layer Flow, Basic Techniques
  • Examples: Calculations, Experiments
  • Parameters Affecting Boundary Layer
  • Numerical Simulation
  • Project
  • References
  • 12. Compressible Flow
  • Steady Compressible Flow
  • Unsteady Compressible Flow
  • Numerical Treatment
  • Problems
  • Project
  • References
  • 13. Flow Measurement Techniques, Calibration
  • Measurement of Time-Dependent Flow Field Using HWA
  • Measurement of Time-Averaged Flow Quantities Using Five-Hole Probes
  • References
  • A. Tensor Operations in Orthogonal Curvilinear Coordinate Systems
  • Change of Coordinate System
  • Co- and Contravariant Base Vectors, Metric Coefficients
  • Physical Components of a Vector
  • Derivatives of the Base Vectors, Christoffel Symbols
  • Spatial Derivatives in Curvilinear Coordinate Systems
  • Application Example 1: Inviscid Incompressible Flow Motion
  • Application Example 2: Viscous Flow Motion
  • Further Reading
  • B. Physical Properties of Dry Air.

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