Fluid and Thermodynamics : Volume 1: Basic Fluid Mechanics / / by Kolumban Hutter, Yongqi Wang |
Autore | Hutter Kolumban |
Edizione | [1st ed. 2016.] |
Pubbl/distr/stampa | Cham : , : Springer International Publishing : , : Imprint : Springer, , 2016 |
Descrizione fisica | 1 online resource (XIX, 639 p. 340 illus., 109 illus. in color.) |
Disciplina | 620.106 |
Collana | Advances in Geophysical and Environmental Mechanics and Mathematics |
Soggetto topico |
Geophysics
Mathematical physics Fluid mechanics Fluids Geophysics/Geodesy Mathematical Applications in the Physical Sciences Engineering Fluid Dynamics Fluid- and Aerodynamics |
ISBN | 3-319-33633-9 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto | Introduction -- Hydrostatics -- Hydrodynamics of Ideal Liquids -- Conservation of Angular Momentum – Vorticity -- An Almanac of Simple Flow Problems of Ideal Fluids -- Function-Theoretical Methods Applied to Plane Potential Flows -- Viscous Fluids -- Simple Two- and Three-Dimensional Flow Problems of the Navier-Stokes Equations -- Simple Solutions of Boundary Layer Equations -- Pipe Flows. |
Record Nr. | UNINA-9910254130703321 |
Hutter Kolumban
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Cham : , : Springer International Publishing : , : Imprint : Springer, , 2016 | ||
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Lo trovi qui: Univ. Federico II | ||
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Fluid and Thermodynamics : Volume 2: Advanced Fluid Mechanics and Thermodynamic Fundamentals / / by Kolumban Hutter, Yongqi Wang |
Autore | Hutter Kolumban |
Edizione | [1st ed. 2016.] |
Pubbl/distr/stampa | Cham : , : Springer International Publishing : , : Imprint : Springer, , 2016 |
Descrizione fisica | 1 online resource (XX, 633 p. 196 illus., 50 illus. in color.) |
Disciplina | 620.106 |
Collana | Advances in Geophysical and Environmental Mechanics and Mathematics |
Soggetto topico |
Geophysics
Fluid mechanics Thermodynamics Mathematical physics Geophysics/Geodesy Engineering Fluid Dynamics Mathematical Applications in the Physical Sciences |
ISBN | 3-319-33636-3 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto | Creeping Motion around Spheres at Rest in a Newtonian Fluid -- Three-Dimensional Creeping Flow – Systematic Derivation of the Shallow Flow Approximations -- Shallow Rapid Granular Avalanches -- Uniqueness and Stability -- Turbulent Modeling -- Turbulent Mixing Length Models and Their Applications to Elementary Flow Configurations -- Thermodynamics – Fundamentals -- Thermodynamics – Field Formulation -- Gas Dynamics -- Dimensional Analysis, Similitude and Physical Experiments at Laboratory Scale. |
Record Nr. | UNINA-9910254125703321 |
Hutter Kolumban
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Cham : , : Springer International Publishing : , : Imprint : Springer, , 2016 | ||
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Lo trovi qui: Univ. Federico II | ||
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Fluid flow, heat and mass transfer at bodies of different shapes : numerical solutions / / Kuppalapalle Vajravelu, Swati Mukhopadhyay |
Autore | Vajravelu Kuppalapalle |
Pubbl/distr/stampa | Amsterdam, [Netherlands] : , : Academic Press, , 2016 |
Descrizione fisica | 1 online resource (0 p.) |
Disciplina | 620.106 |
Soggetto topico | Fluid mechanics - Mathematical models |
ISBN | 0-12-803785-7 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Record Nr. | UNINA-9910797686803321 |
Vajravelu Kuppalapalle
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Amsterdam, [Netherlands] : , : Academic Press, , 2016 | ||
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Lo trovi qui: Univ. Federico II | ||
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Fluid flow, heat and mass transfer at bodies of different shapes : numerical solutions / / Kuppalapalle Vajravelu, Swati Mukhopadhyay |
Autore | Vajravelu Kuppalapalle |
Pubbl/distr/stampa | Amsterdam, [Netherlands] : , : Academic Press, , 2016 |
Descrizione fisica | 1 online resource (0 p.) |
Disciplina | 620.106 |
Soggetto topico | Fluid mechanics - Mathematical models |
ISBN | 0-12-803785-7 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Record Nr. | UNINA-9910822647903321 |
Vajravelu Kuppalapalle
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Amsterdam, [Netherlands] : , : Academic Press, , 2016 | ||
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Lo trovi qui: Univ. Federico II | ||
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Fluid mechanics / J. F. Douglas, J. M. Gasiorek and J. A. Swaffield |
Autore | Douglas, John Francis |
Edizione | [3. ed] |
Pubbl/distr/stampa | Harlow : Longman, 1995 |
Descrizione fisica | XXIII, 819 p. : ill. ; 26 cm. |
Disciplina | 620.106 |
Altri autori (Persone) |
Gasiorek, Janusz M.
Swaffield, J. A. |
ISBN | 05-8223-408-5 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Record Nr. | UNICAMPANIA-SUN0033419 |
Douglas, John Francis
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Harlow : Longman, 1995 | ||
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Lo trovi qui: Univ. Vanvitelli | ||
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Fluid mechanics / J. F. Douglas, J. M. Gasiorek and J. A. Swaffield |
Autore | Douglas, John Francis |
Edizione | [3. ed] |
Pubbl/distr/stampa | Harlow, : Longman, 1995 |
Descrizione fisica | XXIII, 819 p. : ill. ; 26 cm |
Disciplina | 620.106 |
Altri autori (Persone) |
Gasiorek, Janusz M.
Swaffield, J. A. |
ISBN | 05-8223-408-5 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Titolo uniforme | |
Record Nr. | UNICAMPANIA-VAN0033419 |
Douglas, John Francis
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Harlow, : Longman, 1995 | ||
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Lo trovi qui: Univ. Vanvitelli | ||
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Fluid mechanics : an introduction to the theory of fluid flows / / Franz Durst |
Autore | Durst F. |
Edizione | [Second and extended edition.] |
Pubbl/distr/stampa | Berlin, Germany : , : Springer, , [2022] |
Descrizione fisica | 1 online resource (828 pages) : illustrations (black and white, and color) |
Disciplina | 620.106 |
Collana | Graduate texts in physics |
Soggetto topico |
Fluid mechanics
Hydraulic engineering Physics |
ISBN |
9783662639153
9783662639139 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Intro -- Preface to the German Edition -- Preface to the English Edition -- Preface to the Second Edition -- Contents -- 1 Introduction, Importance and Development of Fluid Mechanics -- Abstract -- 1.1 Fluid Flows and Their Significance -- 1.2 Sub-Domains of Fluid Mechanics -- 1.3 Historical Developments -- Further Readings -- 2 Mathematical Basics -- Abstract -- 2.1 Introduction and Definitions -- 2.2 Tensors of Zero Order (Scalars) -- 2.3 Tensors of First Order (Vectors) -- 2.4 Tensors of Second Order -- 2.5 Field Variables and Mathematical Operations -- 2.6 Substantial Quantities and Substantial Derivative -- 2.7 Gradient, Divergence, Rotation and Laplace Operators -- 2.8 Complex Numbers -- 2.8.1 Axiomatic Introduction to Complex Numbers -- 2.8.2 Graphical Representation of Complex Numbers -- 2.8.3 The Gauss Complex Number Plane -- 2.8.4 Trigonometric Representation -- 2.8.5 Stereographic Projection -- 2.8.6 Elementary Function -- Further Readings -- 3 Physical Basics -- Abstract -- 3.1 Solids and Fluids -- 3.2 Molecular Properties and Quantities of Continuum Mechanics -- 3.3 Transport Processes in Newtonian Fluids -- 3.3.1 General Considerations -- 3.3.2 Pressure in Gases -- 3.3.3 Molecular-Dependent Momentum Transport -- 3.3.4 Molecular Transport of Heat and Mass in Gases -- 3.4 Viscosity of Fluids -- 3.5 Balance Considerations and Conservation Laws -- 3.6 Thermodynamic Considerations -- Further Readings -- 4 Basics of Fluid Kinematics -- Abstract -- 4.1 General Considerations -- 4.2 Substantial Derivatives -- 4.3 Motion of Fluid Elements -- 4.3.1 Path Lines of Fluid Elements -- 4.3.2 Streak Lines of Locally Injected Tracers -- 4.4 Kinematic Quantities of Flow Fields -- 4.4.1 Stream Lines of a Velocity Field -- 4.4.2 Stream Function and Stream Lines of Two-Dimensional Flow Fields -- 4.4.3 Divergence of a Flow Field.
4.5 Translation, Deformation and Rotation of Fluid Elements -- 4.6 Relative Motions -- Further Readings -- 5 Basic Equations of Fluid Mechanics -- Abstract -- 5.1 General Considerations -- 5.2 Mass Conservation (Continuity Equation) -- 5.3 Newton's Second Law (Momentum Equation) -- 5.4 The Navier-Stokes Equations -- 5.5 Mechanical Energy Equation -- 5.6 Thermal Energy Equation -- 5.7 Basic Equations in Different Coordinate Systems -- 5.7.1 Continuity Equation -- 5.7.2 Navier-Stokes Equations -- 5.8 Special Forms of the Basic Equations -- 5.8.1 Transport Equation for Vorticity -- 5.8.2 The Bernoulli Equation -- 5.8.3 Crocco Equation -- 5.8.4 Further Forms of the Energy Equation -- 5.9 Transport Equation for Chemical Species -- Further Readings -- 6 Extended Basic Equations of Fluid Mechanics -- Abstract -- 6.1 General Introduction -- 6.2 Extended Diffusive Transport Equations -- 6.2.1 Mass Transport Equations -- 6.2.2 Heat Transport Equations -- 6.2.3 Momentum Transport Equations -- 6.3 Analytical and Numerical Treatments of Micro-Channel and Micro-Capillary Flows -- 6.3.1 Summary of Numerical Investigations -- 6.3.1.1 Self-Diffusion in Ideal Gas Flows -- 6.3.1.2 Numerical Predictions and Results -- 6.3.2 Analytical Treatments -- 6.3.2.1 Micro-Channel Flows -- 6.3.2.2 Micro-Capillary Flows -- 6.4 Pressure Gradient Versus Wall Reflection Effects -- Further Readings -- 7 Hydrostatics and Aerostatics -- Abstract -- 7.1 Hydrostatics -- 7.2 Connected Containers and Pressure-Measuring Instruments -- 7.2.1 Interconnected Containers -- 7.2.2 Pressure-Measuring Instruments -- 7.3 Free Fluid Surfaces -- 7.3.1 Surface Tension -- 7.3.2 Water Columns in Tubes and Between Plates -- 7.3.3 Bubble Formation on Nozzles -- 7.4 Aerostatics -- 7.4.1 Pressure in the Atmosphere -- 7.4.2 Rotating Containers -- 7.4.3 Aerostatic Buoyancy. 7.4.4 Conditions for Aerostatics: Stability of Layers -- Further Readings -- 8 Similarity Theory -- Abstract -- 8.1 Introduction -- 8.2 Dimensionless Form of the Differential Equations -- 8.2.1 General Remarks -- 8.3 Dimensionless Form of the Differential Equations -- 8.3.1 Considerations in the Presence of Geometric and Kinematic Similarities -- 8.3.2 Importance of Viscous Velocity, Time and Length Scales -- 8.4 Dimensional Analysis and π-Theorem -- Further Readings -- 9 Integral Forms of the Basic Equations -- Abstract -- 9.1 Integral Form of the Continuity Equation -- 9.2 Integral Form of the Momentum Equation -- 9.3 Integral Form of the Mechanical Energy Equation -- 9.4 Integral Form of the Thermal Energy Equation -- 9.5 Applications of the Integral Form of the Basic Equations -- 9.5.1 Outflow from Containers -- 9.5.2 Exit Velocity of a Nozzle -- 9.5.3 Momentum on a Plane Vertical Plate -- 9.5.4 Momentum on an Inclined Plane Plate -- 9.5.5 Jet Deflection by an Edge -- 9.5.6 Mixing Process in a Channel of Constant Cross-Section in the Flow Direction -- 9.5.7 Force on a Turbine Blade in a Viscosity-Free Fluid -- 9.5.8 Force on a Grid with Periodical Blades -- 9.5.9 Euler's Turbine Equation -- 9.5.10 Power of Flow Machines -- Further Readings -- 10 Stream Tube Theory -- Abstract -- 10.1 General Considerations -- 10.2 Derivations of the Basic Equations -- 10.2.1 Continuity Equation -- 10.2.2 Momentum Equation -- 10.2.3 Bernoulli Equation -- 10.2.4 Total Energy Equation -- 10.3 Incompressible Flows -- 10.3.1 Hydromechanical Nozzle Flows -- 10.3.2 Sudden Cross-Sectional Area Extension -- 10.4 Compressible Flows -- 10.4.1 Influences of Area Changes on Flows -- 10.4.2 Pressure-Driven Flows Through Converging Nozzles -- Further Readings -- 11 Potential Flows -- Abstract -- 11.1 Potential and Stream Functions -- 11.2 Potential and Complex Functions. 11.3 Uniform Flow -- 11.4 Corner and Sector Flows -- 11.5 Source or Sink Flows and Potential Vortex Flow -- 11.6 Dipole-Generated Flow -- 11.7 Potential Flow Around a Cylinder -- 11.8 Flow Around a Cylinder With Circulation -- 11.9 Summary of Important Potential Flows -- 11.10 Flow Forces on Bodies -- Further Readings -- 12 Wave Motions in Non-Viscous Fluids -- Abstract -- 12.1 General Considerations -- 12.2 Longitudinal Waves: Sound Waves in Gases -- 12.3 Transverse Waves: Surface Waves -- 12.3.1 General Solution Approach -- 12.4 Plane Standing Waves -- 12.5 Plane Progressing Waves -- 12.6 References to Further Wave Motions -- Further Readings -- 13 Introduction to Gas Dynamics -- Abstract -- 13.1 Introductory Considerations -- 13.2 Mach Lines and Mach Cone -- 13.3 Non-Linear Wave Propagation, Formation of Shock Waves -- 13.4 Alternative Forms of the Bernoulli Equation -- 13.5 Flow with Heat Transfer (Pipe Flow) -- 13.5.1 Subsonic Flow -- 13.5.2 Supersonic Flow -- 13.6 Rayleigh and Fanno Relations -- Further Readings -- 14 Stationary One-Dimensional Fluid Flows of Incompressible Viscous Fluids -- Abstract -- 14.1 General Considerations -- 14.1.1 Equations for Plane Fluid Flows -- 14.1.2 Cylindrical Fluid Flows -- 14.2 Derivations of the Basic Equations for Fully Developed Fluid Flows -- 14.2.1 Equations for Plane Fluid Flows -- 14.2.2 Equations for Cylindrical Fluid Flows -- 14.3 Plane Couette Flow -- 14.4 Plane Fluid Flow Between Plates -- 14.5 Plane Film Flow on an Inclined Plate -- 14.6 Axisymmetric Film Flow -- 14.7 Pipe Flow (Hagen-Poiseuille Flow) -- 14.8 Axial Flow Between Two Cylinders -- 14.9 Film Flows with Two Layers -- 14.10 Two-Phase Plane Channel Flow -- Further Readings -- 15 Time-Dependent, One-Dimensional Flows of Viscous Fluids -- Abstract -- 15.1 General Considerations -- 15.2 Accelerated and Decelerated Fluid Flows. 15.2.1 Stokes First Problem -- 15.2.2 Diffusion of a Vortex Layer -- 15.2.3 Channel Flow Induced by Movements of Plates -- 15.2.4 Pipe Flow Induced by the Pipe Wall Motion -- 15.3 Oscillating Fluid Flows -- 15.3.1 Stokes Second Problem -- 15.4 Pressure Gradient-Driven Fluid Flows -- 15.4.1 Starting Flow in a Channel -- 15.4.2 Starting Pipe Flow -- Further Readings -- 16 Fluid Flows of Small Reynolds Numbers -- Abstract -- 16.1 General Considerations -- 16.2 Creeping Fluid Flows Between Two Plates -- 16.3 Plane Lubrication Films -- 16.4 Theory of Lubrication in Roller Bearings -- 16.5 The Slow Rotation of a Sphere -- 16.6 The Slow Translatory Motion of a Sphere -- 16.7 The Slow Rotational Motion of a Cylinder -- 16.8 The Slow Translatory Motion of a Cylinder -- 16.9 Diffusion and Convection Influences on Flow Fields -- Further Readings -- 17 Flows of Large Reynolds Number Boundary-Layer Flows -- Abstract -- 17.1 General Considerations and Derivations -- 17.2 Solutions of the Boundary-Layer Equations -- 17.3 Flat Plate Boundary Layer (Blasius Solution) -- 17.4 Integral Properties of Wall Boundary Layers -- 17.5 The Laminar, Plane, Two-Dimensional Free Shear Layer -- 17.6 The Plane, Two-Dimensional, Laminar Free Jet -- 17.7 Plane, Two-Dimensional Wake Flow -- 17.8 Converging Channel Flow -- Further Readings -- 18 Unstable Flows and Laminar-Turbulent Transition -- Abstract -- 18.1 General Considerations -- 18.2 Causes of Flow Instabilities -- 18.2.1 Stability of Atmospheric Temperature Distributions -- 18.2.2 Gravitationally Caused Instabilities -- 18.2.3 Instabilities in Annular Clearances Caused by Rotation -- 18.3 Generalized Instability Considerations (Orr-Sommerfeld Equation) -- 18.4 Classifications of Instabilities -- 18.5 Transitional Boundary-Layer Flows -- Further Readings -- 19 Turbulent Flows -- Abstract -- 19.1 General Considerations. 19.2 Statistical Description of Turbulent Flows. |
Record Nr. | UNINA-9910584482803321 |
Durst F.
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Berlin, Germany : , : Springer, , [2022] | ||
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Lo trovi qui: Univ. Federico II | ||
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Fluid mechanics : an introduction to the theory of fluid flows / / Franz Durst |
Autore | Durst F. |
Edizione | [Second and extended edition.] |
Pubbl/distr/stampa | Berlin, Germany : , : Springer, , [2022] |
Descrizione fisica | 1 online resource (828 pages) : illustrations (black and white, and color) |
Disciplina | 620.106 |
Collana | Graduate texts in physics |
Soggetto topico |
Fluid mechanics
Hydraulic engineering Physics |
ISBN |
9783662639153
9783662639139 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Intro -- Preface to the German Edition -- Preface to the English Edition -- Preface to the Second Edition -- Contents -- 1 Introduction, Importance and Development of Fluid Mechanics -- Abstract -- 1.1 Fluid Flows and Their Significance -- 1.2 Sub-Domains of Fluid Mechanics -- 1.3 Historical Developments -- Further Readings -- 2 Mathematical Basics -- Abstract -- 2.1 Introduction and Definitions -- 2.2 Tensors of Zero Order (Scalars) -- 2.3 Tensors of First Order (Vectors) -- 2.4 Tensors of Second Order -- 2.5 Field Variables and Mathematical Operations -- 2.6 Substantial Quantities and Substantial Derivative -- 2.7 Gradient, Divergence, Rotation and Laplace Operators -- 2.8 Complex Numbers -- 2.8.1 Axiomatic Introduction to Complex Numbers -- 2.8.2 Graphical Representation of Complex Numbers -- 2.8.3 The Gauss Complex Number Plane -- 2.8.4 Trigonometric Representation -- 2.8.5 Stereographic Projection -- 2.8.6 Elementary Function -- Further Readings -- 3 Physical Basics -- Abstract -- 3.1 Solids and Fluids -- 3.2 Molecular Properties and Quantities of Continuum Mechanics -- 3.3 Transport Processes in Newtonian Fluids -- 3.3.1 General Considerations -- 3.3.2 Pressure in Gases -- 3.3.3 Molecular-Dependent Momentum Transport -- 3.3.4 Molecular Transport of Heat and Mass in Gases -- 3.4 Viscosity of Fluids -- 3.5 Balance Considerations and Conservation Laws -- 3.6 Thermodynamic Considerations -- Further Readings -- 4 Basics of Fluid Kinematics -- Abstract -- 4.1 General Considerations -- 4.2 Substantial Derivatives -- 4.3 Motion of Fluid Elements -- 4.3.1 Path Lines of Fluid Elements -- 4.3.2 Streak Lines of Locally Injected Tracers -- 4.4 Kinematic Quantities of Flow Fields -- 4.4.1 Stream Lines of a Velocity Field -- 4.4.2 Stream Function and Stream Lines of Two-Dimensional Flow Fields -- 4.4.3 Divergence of a Flow Field.
4.5 Translation, Deformation and Rotation of Fluid Elements -- 4.6 Relative Motions -- Further Readings -- 5 Basic Equations of Fluid Mechanics -- Abstract -- 5.1 General Considerations -- 5.2 Mass Conservation (Continuity Equation) -- 5.3 Newton's Second Law (Momentum Equation) -- 5.4 The Navier-Stokes Equations -- 5.5 Mechanical Energy Equation -- 5.6 Thermal Energy Equation -- 5.7 Basic Equations in Different Coordinate Systems -- 5.7.1 Continuity Equation -- 5.7.2 Navier-Stokes Equations -- 5.8 Special Forms of the Basic Equations -- 5.8.1 Transport Equation for Vorticity -- 5.8.2 The Bernoulli Equation -- 5.8.3 Crocco Equation -- 5.8.4 Further Forms of the Energy Equation -- 5.9 Transport Equation for Chemical Species -- Further Readings -- 6 Extended Basic Equations of Fluid Mechanics -- Abstract -- 6.1 General Introduction -- 6.2 Extended Diffusive Transport Equations -- 6.2.1 Mass Transport Equations -- 6.2.2 Heat Transport Equations -- 6.2.3 Momentum Transport Equations -- 6.3 Analytical and Numerical Treatments of Micro-Channel and Micro-Capillary Flows -- 6.3.1 Summary of Numerical Investigations -- 6.3.1.1 Self-Diffusion in Ideal Gas Flows -- 6.3.1.2 Numerical Predictions and Results -- 6.3.2 Analytical Treatments -- 6.3.2.1 Micro-Channel Flows -- 6.3.2.2 Micro-Capillary Flows -- 6.4 Pressure Gradient Versus Wall Reflection Effects -- Further Readings -- 7 Hydrostatics and Aerostatics -- Abstract -- 7.1 Hydrostatics -- 7.2 Connected Containers and Pressure-Measuring Instruments -- 7.2.1 Interconnected Containers -- 7.2.2 Pressure-Measuring Instruments -- 7.3 Free Fluid Surfaces -- 7.3.1 Surface Tension -- 7.3.2 Water Columns in Tubes and Between Plates -- 7.3.3 Bubble Formation on Nozzles -- 7.4 Aerostatics -- 7.4.1 Pressure in the Atmosphere -- 7.4.2 Rotating Containers -- 7.4.3 Aerostatic Buoyancy. 7.4.4 Conditions for Aerostatics: Stability of Layers -- Further Readings -- 8 Similarity Theory -- Abstract -- 8.1 Introduction -- 8.2 Dimensionless Form of the Differential Equations -- 8.2.1 General Remarks -- 8.3 Dimensionless Form of the Differential Equations -- 8.3.1 Considerations in the Presence of Geometric and Kinematic Similarities -- 8.3.2 Importance of Viscous Velocity, Time and Length Scales -- 8.4 Dimensional Analysis and π-Theorem -- Further Readings -- 9 Integral Forms of the Basic Equations -- Abstract -- 9.1 Integral Form of the Continuity Equation -- 9.2 Integral Form of the Momentum Equation -- 9.3 Integral Form of the Mechanical Energy Equation -- 9.4 Integral Form of the Thermal Energy Equation -- 9.5 Applications of the Integral Form of the Basic Equations -- 9.5.1 Outflow from Containers -- 9.5.2 Exit Velocity of a Nozzle -- 9.5.3 Momentum on a Plane Vertical Plate -- 9.5.4 Momentum on an Inclined Plane Plate -- 9.5.5 Jet Deflection by an Edge -- 9.5.6 Mixing Process in a Channel of Constant Cross-Section in the Flow Direction -- 9.5.7 Force on a Turbine Blade in a Viscosity-Free Fluid -- 9.5.8 Force on a Grid with Periodical Blades -- 9.5.9 Euler's Turbine Equation -- 9.5.10 Power of Flow Machines -- Further Readings -- 10 Stream Tube Theory -- Abstract -- 10.1 General Considerations -- 10.2 Derivations of the Basic Equations -- 10.2.1 Continuity Equation -- 10.2.2 Momentum Equation -- 10.2.3 Bernoulli Equation -- 10.2.4 Total Energy Equation -- 10.3 Incompressible Flows -- 10.3.1 Hydromechanical Nozzle Flows -- 10.3.2 Sudden Cross-Sectional Area Extension -- 10.4 Compressible Flows -- 10.4.1 Influences of Area Changes on Flows -- 10.4.2 Pressure-Driven Flows Through Converging Nozzles -- Further Readings -- 11 Potential Flows -- Abstract -- 11.1 Potential and Stream Functions -- 11.2 Potential and Complex Functions. 11.3 Uniform Flow -- 11.4 Corner and Sector Flows -- 11.5 Source or Sink Flows and Potential Vortex Flow -- 11.6 Dipole-Generated Flow -- 11.7 Potential Flow Around a Cylinder -- 11.8 Flow Around a Cylinder With Circulation -- 11.9 Summary of Important Potential Flows -- 11.10 Flow Forces on Bodies -- Further Readings -- 12 Wave Motions in Non-Viscous Fluids -- Abstract -- 12.1 General Considerations -- 12.2 Longitudinal Waves: Sound Waves in Gases -- 12.3 Transverse Waves: Surface Waves -- 12.3.1 General Solution Approach -- 12.4 Plane Standing Waves -- 12.5 Plane Progressing Waves -- 12.6 References to Further Wave Motions -- Further Readings -- 13 Introduction to Gas Dynamics -- Abstract -- 13.1 Introductory Considerations -- 13.2 Mach Lines and Mach Cone -- 13.3 Non-Linear Wave Propagation, Formation of Shock Waves -- 13.4 Alternative Forms of the Bernoulli Equation -- 13.5 Flow with Heat Transfer (Pipe Flow) -- 13.5.1 Subsonic Flow -- 13.5.2 Supersonic Flow -- 13.6 Rayleigh and Fanno Relations -- Further Readings -- 14 Stationary One-Dimensional Fluid Flows of Incompressible Viscous Fluids -- Abstract -- 14.1 General Considerations -- 14.1.1 Equations for Plane Fluid Flows -- 14.1.2 Cylindrical Fluid Flows -- 14.2 Derivations of the Basic Equations for Fully Developed Fluid Flows -- 14.2.1 Equations for Plane Fluid Flows -- 14.2.2 Equations for Cylindrical Fluid Flows -- 14.3 Plane Couette Flow -- 14.4 Plane Fluid Flow Between Plates -- 14.5 Plane Film Flow on an Inclined Plate -- 14.6 Axisymmetric Film Flow -- 14.7 Pipe Flow (Hagen-Poiseuille Flow) -- 14.8 Axial Flow Between Two Cylinders -- 14.9 Film Flows with Two Layers -- 14.10 Two-Phase Plane Channel Flow -- Further Readings -- 15 Time-Dependent, One-Dimensional Flows of Viscous Fluids -- Abstract -- 15.1 General Considerations -- 15.2 Accelerated and Decelerated Fluid Flows. 15.2.1 Stokes First Problem -- 15.2.2 Diffusion of a Vortex Layer -- 15.2.3 Channel Flow Induced by Movements of Plates -- 15.2.4 Pipe Flow Induced by the Pipe Wall Motion -- 15.3 Oscillating Fluid Flows -- 15.3.1 Stokes Second Problem -- 15.4 Pressure Gradient-Driven Fluid Flows -- 15.4.1 Starting Flow in a Channel -- 15.4.2 Starting Pipe Flow -- Further Readings -- 16 Fluid Flows of Small Reynolds Numbers -- Abstract -- 16.1 General Considerations -- 16.2 Creeping Fluid Flows Between Two Plates -- 16.3 Plane Lubrication Films -- 16.4 Theory of Lubrication in Roller Bearings -- 16.5 The Slow Rotation of a Sphere -- 16.6 The Slow Translatory Motion of a Sphere -- 16.7 The Slow Rotational Motion of a Cylinder -- 16.8 The Slow Translatory Motion of a Cylinder -- 16.9 Diffusion and Convection Influences on Flow Fields -- Further Readings -- 17 Flows of Large Reynolds Number Boundary-Layer Flows -- Abstract -- 17.1 General Considerations and Derivations -- 17.2 Solutions of the Boundary-Layer Equations -- 17.3 Flat Plate Boundary Layer (Blasius Solution) -- 17.4 Integral Properties of Wall Boundary Layers -- 17.5 The Laminar, Plane, Two-Dimensional Free Shear Layer -- 17.6 The Plane, Two-Dimensional, Laminar Free Jet -- 17.7 Plane, Two-Dimensional Wake Flow -- 17.8 Converging Channel Flow -- Further Readings -- 18 Unstable Flows and Laminar-Turbulent Transition -- Abstract -- 18.1 General Considerations -- 18.2 Causes of Flow Instabilities -- 18.2.1 Stability of Atmospheric Temperature Distributions -- 18.2.2 Gravitationally Caused Instabilities -- 18.2.3 Instabilities in Annular Clearances Caused by Rotation -- 18.3 Generalized Instability Considerations (Orr-Sommerfeld Equation) -- 18.4 Classifications of Instabilities -- 18.5 Transitional Boundary-Layer Flows -- Further Readings -- 19 Turbulent Flows -- Abstract -- 19.1 General Considerations. 19.2 Statistical Description of Turbulent Flows. |
Record Nr. | UNISA-996483071903316 |
Durst F.
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Berlin, Germany : , : Springer, , [2022] | ||
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Lo trovi qui: Univ. di Salerno | ||
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Fluid mechanics / Robert A. Granger |
Autore | Granger, Robert A. |
Pubbl/distr/stampa | New York : Dover, copyr. 1995 |
Disciplina | 620.106 |
Soggetto non controllato | fluidi meccanica |
ISBN | 0-486-68356-7 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Record Nr. | UNISA-990000151520203316 |
Granger, Robert A.
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New York : Dover, copyr. 1995 | ||
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Lo trovi qui: Univ. di Salerno | ||
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Fluid mechanics / / Pijush K. Kundu, Ira M. Cohen ; with contributions by P.S. Ayyaswamy and H.H. Hu |
Autore | Kundu Pijush K |
Edizione | [4th ed.] |
Pubbl/distr/stampa | Amsterdam ; ; Boston, : Academic Press, c2008 |
Descrizione fisica | 1 online resource (901 p.) |
Disciplina |
620.1/06
620.106 |
Altri autori (Persone) | CohenIra M |
Soggetto topico | Fluid mechanics |
ISBN |
1-282-54038-6
9786612540387 0-08-055583-7 |
Formato | Materiale a stampa ![]() |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Front Cover; Fluid Mechanics; Copyright Page; Dedication; About the Author; Table of Contents; Preface; Preface to Third Edition; Preface to Second Edition; Preface to First Edition; Author's Notes; Chapter 1. Introduction; 1. Fluid Mechanics; 2. Units of Measurement; 3. Solids, Liquids, and Gases; 4. Continuum Hypothesis; 5. Transport Phenomena; 6. Surface Tension; 7. Fluid Statics; 8. Classical Thermodynamics; 9. Perfect Gas; 10. Static Equilibrium of a Compressible Medium; Exercises; Literature Cited; Supplemental Reading; Chapter 2. Cartesian Tensors; 1. Scalars and Vectors
2. Rotation of Axes: Formal Definition of a Vector3. Multiplication of Matrices; 4. Second-Order Tensor; 5. Contraction and Multiplication; 6. Force on a Surface; 7. Kronecker Delta and Alternating Tensor; 8. Dot Product; 9. Cross Product; 10. Operator ?: Gradient, Divergence, and Curl; 11. Symmetric and Antisymmetric Tensors; 12. Eigenvalues and Eigenvectors of a Symmetric Tensor; 13. Gauss' Theorem; 14. Stokes' Theorem; 15. Comma Notation; 16. Boldface vs Indicial Notation; Exercises; Literature Cited; Supplemental Reading; Chapter 3. Kinematics; 1. Introduction 2. Lagrangian and Eulerian Specifications3. Eulerian and Lagrangian Descriptions: The Particle Derivative; 4. Streamline, Path Line, and Streak Line; 5. Reference Frame and Streamline Pattern; 6. Linear Strain Rate; 7. Shear Strain Rate; 8. Vorticity and Circulation; 9. Relative Motion near a Point: Principal Axes; 10. Kinematic Considerations of Parallel Shear Flows; 11. Kinematic Considerations of Vortex Flows; 12. One-, Two-, and Three-Dimensional Flows; 13. The Streamfunction; 14. Polar Coordinates; Exercises; Supplemental Reading; Chapter 4. Conservation Laws; 1. Introduction 2. Time Derivatives of Volume Integrals3. Conservation of Mass; 4. Streamfunctions: Revisited and Generalized; 5. Origin of Forces in Fluid; 6. Stress at a Point; 7. Conservation of Momentum; 8. Momentum Principle for a Fixed Volume; 9. Angular Momentum Principle for a Fixed Volume; 10. Constitutive Equation for Newtonian Fluid; 11. Navier-Stokes Equation; 12. Rotating Frame; 13. Mechanical Energy Equation; 14. First Law of Thermodynamics: Thermal Energy Equation; 15. Second Law of Thermodynamics: Entropy Production; 16. Bernoulli Equation; 17. Applications of Bernoulli's Equation 18. Boussinesq Approximation19. Boundary Conditions; Exercises; Literature Cited; Supplemental Reading; Chapter 5. Vorticity Dynamics; 1. Introduction; 2. Vortex Lines and Vortex Tubes; 3. Role of Viscosity in Rotational and Irrotational Vortices; 4. Kelvin's Circulation Theorem; 5. Vorticity Equation in a Nonrotating Frame; 6. Velocity Induced by a Vortex Filament: Law of Biot and Savart; 7. Vorticity Equation in a Rotating Frame; 8. Interaction of Vortices; 9. Vortex Sheet; Exercises; Literature Cited; Supplemental Reading; Chapter 6. Irrotational Flow 1. Relevance of Irrotational Flow Theory |
Record Nr. | UNINA-9910811989803321 |
Kundu Pijush K
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Amsterdam ; ; Boston, : Academic Press, c2008 | ||
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Lo trovi qui: Univ. Federico II | ||
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