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An introduction to transport phenomena in materials engineering

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Hlavní autor: Gaskell, David R., 1940-
Médium: Elektronický zdroj E-kniha
Jazyk:angličtina
Vydáno: [New York, N.Y.] (222 East 46th Street, New York, NY 10017) : Momentum Press, 2012.
Vydání:2nd ed.
Témata:
Materials > Transport properties.
Materials > Fluid dynamics.
Mass transfer.
Heat > Transmission.
Thermodynamics of Materials
High Temperature Kinetics
Transport Phenomena
Materials Processing
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Obsah:
  • List of symbols
  • 1. Engineering units and pressure in static fluids
  • 1.1 Origins of engineering units
  • 1.2 Concept of pressure
  • 1.3 Measurement of pressure
  • 1.4 Pressure in incompressible fluids
  • 1.5 Buoyancy
  • 1.6 Summary
  • Problems
  • 2. Momentum transport and laminar flow of Newtonian fluids
  • 2.1 Introduction
  • 2.2 Newton's lax of viscosity
  • 2.3 Conservation of momentum in steady-state flow
  • 2.4 Fluid flow between two flat parallel plates
  • 2.5 Fluid flow down in inclined plane
  • 2.6 Fluid flow in a vertical cylindrical tube
  • 2.7 Capillary flowmeter
  • 2.8 Fluid flow in an annulus
  • 2.9 Mean residence time
  • 2.10 Calculation of viscosity from the kinetic theory of gases
  • 2.11 Viscosities of liquid metals
  • 2.12 Summary
  • Problems
  • 3. Equations of continuity and conservation of momentum and fluid flow past submerged objects
  • 3.1 Introduction
  • 3.2 Equation of continuity
  • 3.3 Conservation of momentum
  • 3.4 Navier-Stokes equation for fluids of constant density and viscosity
  • 3.5 Fluid flow over a horizontal flat plane
  • 3.6 Approximate integral method in obtaining boundary layer thickness
  • 3.7 Creeping flow past a sphere
  • 3.8 Summary
  • Problems
  • 4. Turbulent flow
  • 4.1 Introduction
  • 4.2 Graphical representation of fluid flow
  • 4.3 Friction factor and turbulent flow in cylindrical pipes
  • 4.4 Flow over a flat plate
  • 4.5 Flow past a submerged sphere
  • 4.6 Flow past a submerged cylinder
  • 4.7 Flow through packed beds
  • 4.8 Fluidized beds
  • 4.9 Summary
  • Problems
  • 5. Mechanical energy balance and its application to fluid flow
  • 5.1 Introduction
  • 5.2 Bernoulli's equation
  • 5.3 Friction loss, Ef
  • 5.4 Influence of bends, fittings, and changes in the pipe radius
  • 5.5 Concept of head
  • 5.6 Fluid flow in an open channel
  • 5.7 Drainage from a vessel
  • 5.8 Emptying a vessel by discharge through an orifice
  • 5.9 Drainage of a vessel using a drainage tube
  • 5.10 Emptying a vessel by drainage through a drainage tube
  • 5.11 Bernoulli equation for flow of compressible fluids
  • 5.12 Pilot tube
  • 5.13 Orifice plate
  • 5.14 Summary
  • Problems
  • 6. Transport of heat by conduction
  • 6.1 Introduction
  • 6.2 Fourier's law and Newton's law
  • 6.3 Conduction
  • 6.4 Conduction in heat sources
  • 6.5 Thermal conductivity and the kinetic theory of gases
  • 6.6 General heat conduction equation
  • 6.7 Conduction of heat at steady state in two dimensions
  • 6.8 Summary
  • Problems
  • 7. Transport of heat by convection
  • 7.1 Introduction
  • 7.2 Heat transfer by forced convection from a horizontal flat plate at a uniform constant temperature
  • 7.3 Heat transfer from a horizontal flat plate with uniform heat flux along the plate
  • 7.4 Heat transfer during fluid flow in cylindrical pipes
  • 7.5 Energy balance in heat transfer by convection between a cylindrical pipe and a flowing fluid
  • 7.6 Heat transfer by forced convection from horizontal cylinders
  • 7.7 Heat transfer by forced convection from a sphere
  • 7.8 General energy equation
  • 7.9 Heat transfer from a vertical plate by natural convection
  • 7.10 Heat transfer from cylinders by natural convection
  • 7.11 Summary
  • Problems
  • 8. Transient heat flow
  • 8.1 Introduction
  • 8.2 Lumped capacitance method; Newtonian cooling
  • 8.3 Non-Newtonian cooling in semi-infinite systems
  • 8.4 Non-Newtonian cooling in a one-dimensional finite systems
  • 8.5 Non-Newtonian cooling in a two-dimensional finite systems
  • 8.6 Solidification of metal castings
  • 8.7 Summary
  • Problems
  • 9. Heat transport by thermal radiation
  • 9.1 Introduction
  • 9.2 Intensity and emissive power
  • 9.3 Blackbody radiation
  • 9.4 Emissivity
  • 9.5 Absorptivity, reflectivity, and transmissivity
  • 9.6 Kirchhoff's law and the Hohlraum
  • 9.7 Radiation exchange between surfaces
  • 9.8 Radiation exchange between blackbodies
  • 9.9 Radiation exchange between diffuse-gray surfaces
  • 9.10 Electric analogy
  • 9.11 Radiation shields
  • 9.12 Reradiating surface
  • 9.13 Heat transfer from a surface by convection and radiation
  • 9.14 Summary
  • Problems
  • 10. Mass transport by diffusion in the solid state
  • 10.1 Introduction
  • 10.2 Atomic diffusion as a random-walk process
  • 10.3 Fick 's first law of diffusion
  • 10.4 One-dimensional non-steady-state diffusion in a solid; Fick's second law of diffusion
  • 10.5 Infinite diffusion couple
  • 10.6 One-dimensional diffusion in a semi-infinite system involving a change of phase
  • 10.7 Steady-state diffusion through a composite wall
  • 10.8 Diffusion in substitutional solid solutions
  • 10.9 Darken's analysis
  • 10.10 Self-diffusion coefficient
  • 10.11 Measurement of the interdifussion coefficient: Boltzmann-Matano analysis
  • 10.12 Influence of temperature on the diffusion coefficient
  • 10.13 Summary
  • Problems
  • 11. Mass transport in fluids
  • 11.1 Introduction
  • 11.2 Mass and molar fluxes in a fluid
  • 11.3 Equations of diffusion with convection in a binary mixture A-B
  • 11.4 One-dimensional transport in a binary mixture of ideal gases
  • 11.5 Equimolar counterdiffusion
  • 11.6 One-dimensional steady-state diffusion of gas A through stationary gas B
  • 11.7 Sublimation of a sphere into a stationary gas
  • 11.8 Film model
  • 11.9 Catalytic surface reactions
  • 11.10 Diffusion and chemical reaction in stagnant film
  • 11.11 Mass transfer at large fluxes and large concentrations
  • 11.12 Influence of mass transport on heat transfer in stagnant film
  • 11.13 Diffusion into a falling film of liquid
  • 11.14 Diffusion and the kinetic theory of gases
  • 11.15 Mass transfer coefficient and concentration boundary layer on a flat plate
  • 11.16 Approximate integral method
  • 11.17 Mass transfer by free convection
  • 11.18 Simultaneous heat and mass transfer: evaporate cooling
  • 11.19 Chemical reaction and mass transfer: mixed control
  • 11.20 Dissolution of pure metal A in liquid B: mixed control
  • 11.21 Summary
  • Problems
  • 12. Condensation and boiling
  • 12.1 Introduction
  • 12.2 Dimensionless parameters in boiling and condensation
  • 12.3 Modes of boiling
  • 12.4 Pool boiling correlations
  • 12.5 Summary
  • Problems
  • Appendix A. Elementary and derived SI units and symbols
  • Appendix B. Prefixes and symbols for multiples and submultiples of SI units
  • Appendix C. Conversion from British and U.S. units to SI units
  • Appendix D. Properties of solid metals
  • Appendix E. Properties of nonmetallic solids
  • Appendix F. Properties of gases at 1 Atm pressure
  • Appendix G. Properties of saturated liquids
  • Appendix H. Properties of liquid metals
  • Recommended readings
  • Answers to problems
  • Index.

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