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Series Aims and Scopes; Preface; Contents; Part I: Thermodynamics; Chapter 1: The First Law of Thermodynamics; 1.1 Heat and Work; 1.1.1 Temperature and Specific Heat; 1.1.2 Absolute Work; 1.1.3 p-V Diagram; 1.2 First Law of Thermodynamics; 1.3 Work by Fluids; 1.3.1 Open Flow System; 1.3.2 Steady Flow; 1.3.3 Low-Speed Flow; 1.3.4 Adiabatic Flow; 1.4 Enthalpy; Chapter 2: Ideal Gas and Steam; 2.1 Ideal Gas; 2.1.1 Equation of State for an Ideal Gas; 2.1.1.1 Boyleś Law; 2.1.1.2 Charlesś Law (Gay-Lussacś Law); 2.1.2 State Change of an Ideal Gas; 2.1.2.1 Isothermal Change.
2.1.2.2 Constant-Pressure Change2.1.2.3 Constant-Volume Change; 2.1.2.4 Adiabatic Change; 2.1.2.5 Polytropic Change; 2.2 Steam; 2.2.1 Basic Nature of Steam; 2.2.2 State Quantity of Steam; 2.2.3 Steam Tables and Steam Diagrams; Chapter 3: Second Law of Thermodynamics; 3.1 Second Law of Thermodynamics; 3.2 Reversible Change and Irreversible Change; 3.3 Thermal Engine; 3.4 Carnot Cycle; 3.5 Entropy; Chapter 4: Gas Turbine Cycles and Steam Cycles; 4.1 Gas Turbine Cycles; 4.1.1 Brayton Cycle; 4.1.2 Regenerating Brayton Cycle; 4.1.3 Actual Cycles; 4.2 Steam Cycles; 4.2.1 Method of Generating Steam.
4.2.2 Rankine Cycle4.2.3 Reheating Cycle; 4.2.4 Other Cycles; Part II: Fluid Dynamics; Chapter 5: Fundamental Equations of Flow; 5.1 Physical Properties of Fluids; 5.1.1 Continuum; 5.1.2 Forces Exerted on a Fluid; 5.1.3 Ideal Fluid and Viscous Fluid; 5.1.4 Newtonian and Non-Newtonian Fluids; 5.1.5 Compressible and Incompressible Fluids; 5.1.6 Steady and Unsteady States; 5.1.7 Developed Flow and Flow in an Entrance Region; 5.2 Derivation of Fundamental Equations of Flow; 5.2.1 Methods to Describe Flow Motion; 5.2.2 Mass Conservation Equation of the Continuum (Equation of Continuity).
5.2.3 Motion Equation of the Continuum (Navier-Stokes Equation)5.2.4 Mechanical Energy Conservation Equation; 5.3 Boundary Conditions; 5.3.1 Initial Condition; 5.3.2 Boundary Conditions; 5.3.2.1 Solid Surface; 5.3.2.2 Solid Surface (in the Case of Viscous Fluid); Chapter 6: Bernoulliś Equation (Mechanics of Ideal Fluids); 6.1 Eulerś Equations of Motion; 6.2 Equation of Motion Along a Streamline; 6.3 Bernoulliś Theorem and Its Application; 6.3.1 Pitot Tube; 6.3.2 Torricelliś Theorem; 6.3.3 Venturi Tube; Chapter 7: Law of Momentum; 7.1 Law of Momentum; 7.2 Application of the Law of Momentum.
7.2.1 Forces Exerted on a Wall Surface by a Free Jet7.2.1.1 Force Exerted on a Fixed Flat Plate; 7.2.1.2 Force Exerted on a Moving Flat Plate; 7.2.1.3 Force Exerted on a Fixed Curved Plate; 7.2.1.4 Force Exerted on a Moving Curved Plate; 7.2.2 Force Exerted on a Curved Tube; 7.2.3 Losses at an Sudden Expansion Area of a Tube; 7.2.4 Drag Exerted on an Object and Momentum Flux; 7.2.5 Reaction of a Jet; 7.2.5.1 Thrust Exerted on a Water Tank; 7.2.5.2 Thrust of Rockets; 7.2.5.3 Impulse Turbine; Chapter 8: Hydrodynamics of Viscous Fluid; 8.1 Exact Solution of Navier-Stokes Equations.
2.1.2.2 Constant-Pressure Change2.1.2.3 Constant-Volume Change; 2.1.2.4 Adiabatic Change; 2.1.2.5 Polytropic Change; 2.2 Steam; 2.2.1 Basic Nature of Steam; 2.2.2 State Quantity of Steam; 2.2.3 Steam Tables and Steam Diagrams; Chapter 3: Second Law of Thermodynamics; 3.1 Second Law of Thermodynamics; 3.2 Reversible Change and Irreversible Change; 3.3 Thermal Engine; 3.4 Carnot Cycle; 3.5 Entropy; Chapter 4: Gas Turbine Cycles and Steam Cycles; 4.1 Gas Turbine Cycles; 4.1.1 Brayton Cycle; 4.1.2 Regenerating Brayton Cycle; 4.1.3 Actual Cycles; 4.2 Steam Cycles; 4.2.1 Method of Generating Steam.
4.2.2 Rankine Cycle4.2.3 Reheating Cycle; 4.2.4 Other Cycles; Part II: Fluid Dynamics; Chapter 5: Fundamental Equations of Flow; 5.1 Physical Properties of Fluids; 5.1.1 Continuum; 5.1.2 Forces Exerted on a Fluid; 5.1.3 Ideal Fluid and Viscous Fluid; 5.1.4 Newtonian and Non-Newtonian Fluids; 5.1.5 Compressible and Incompressible Fluids; 5.1.6 Steady and Unsteady States; 5.1.7 Developed Flow and Flow in an Entrance Region; 5.2 Derivation of Fundamental Equations of Flow; 5.2.1 Methods to Describe Flow Motion; 5.2.2 Mass Conservation Equation of the Continuum (Equation of Continuity).
5.2.3 Motion Equation of the Continuum (Navier-Stokes Equation)5.2.4 Mechanical Energy Conservation Equation; 5.3 Boundary Conditions; 5.3.1 Initial Condition; 5.3.2 Boundary Conditions; 5.3.2.1 Solid Surface; 5.3.2.2 Solid Surface (in the Case of Viscous Fluid); Chapter 6: Bernoulliś Equation (Mechanics of Ideal Fluids); 6.1 Eulerś Equations of Motion; 6.2 Equation of Motion Along a Streamline; 6.3 Bernoulliś Theorem and Its Application; 6.3.1 Pitot Tube; 6.3.2 Torricelliś Theorem; 6.3.3 Venturi Tube; Chapter 7: Law of Momentum; 7.1 Law of Momentum; 7.2 Application of the Law of Momentum.
7.2.1 Forces Exerted on a Wall Surface by a Free Jet7.2.1.1 Force Exerted on a Fixed Flat Plate; 7.2.1.2 Force Exerted on a Moving Flat Plate; 7.2.1.3 Force Exerted on a Fixed Curved Plate; 7.2.1.4 Force Exerted on a Moving Curved Plate; 7.2.2 Force Exerted on a Curved Tube; 7.2.3 Losses at an Sudden Expansion Area of a Tube; 7.2.4 Drag Exerted on an Object and Momentum Flux; 7.2.5 Reaction of a Jet; 7.2.5.1 Thrust Exerted on a Water Tank; 7.2.5.2 Thrust of Rockets; 7.2.5.3 Impulse Turbine; Chapter 8: Hydrodynamics of Viscous Fluid; 8.1 Exact Solution of Navier-Stokes Equations.