Advanced Thermodynamics for Engineers
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portes grátis
Advanced Thermodynamics for Engineers
Winterbone, D.; Turan, Ali
Elsevier Science & Technology
02/2015
578
Mole
Inglês
9780444633736
15 a 20 dias
1060
Descrição não disponível.
1. Introduction and Revision 2. The Second Law and Equilibrium 3. Engine Cycles and Their Efficiencies 4. Availability and Exergy 5. Rational Efficiency and Powerplant 6. Finite Time (or endoreversible) Thermodynamics (FTT) 7. General Thermodynamic Relationships: for single component systems, or systems of constant composition 8. Equations of State 9. Thermodynamic Properties of Ideal Gases and Ideal Gas Mixtures of Constant Composition 10. Thermodynamics of Combustion 11. Chemistry of Combustion 12. Chemical Equilibrium and Dissociation 13. Effect of Dissociation on Combustion Parameters 14. Chemical Kinetics 15. Combustion and Flames 16. Reciprocating Internal Combustion Engines 17. Gas Turbines 18. Liquefaction of Gases 19. Pinch Technology 20. Irreversible Thermodynamics 21. Fuel Cells
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
Air-fuel ratio; Air-standard cycles; Aircraft gas turbines; Analysis of engine cycle; Availability; Bond energy; Carbon dioxide-dry ice; Carnot cycle; Chemical kinetics; Chemical potential; Chemical structure; Clausius-Clapeyron equation; Combined cycle; Combustion; Combustion chamber; Compression ratio; Datum levels; Diesel engine; Diffusion and heat transfer; Diffusion flames; Direct methanol; Dissociation; Dufour; Effect of friction; Efficiency of fuel cell; Electric cells; Electrochemical potential; Electromotive force (emf); Engine speed; Enthalpy; Enthalpy of reaction; Entropy; Entropy flow; Entropy of ideal gas; Entropy production; Equilibrium; Equilibrium combustion; Equilibrium constant, Kp; Equivalence ratios; Exchange current; Exergy; Exhaust gas recirculation; Explosion limits; Fossil fuels; Fuel cells-alkaline; Gas turbine combustion chamber; Gas turbine cycle; Gas turbine cycles; Gibbs energy; Gibbs energy and stability of isotherm; Gibbs energy of ideal gas; Gibbs-Dalton law; heat cascading; Heat engines; Heat of formation; Heat pumps; heat transfer networks; Heats of reaction and formation; Helmholtz energy; Hess' law; Ideal and perfect gas laws; Ideal gases; Ignition timing; Inefficiencies; Intercooled cycle; Internal energy; Internal energy and enthalpy; Irreversibility; Irreversible thermodynamics; Joule-Thomson effect; Laminar flame speed; Law of corresponding states; Law of mass action; Laws of thermodynamics; Linde liquefaction plant analysis; Liquefaction; Liquefying van der Waals gas; Losses in cells; Maximum and minimum inversion temperatures; Maxwell relationships; Mean temperature of energy addition and rejection; Methane; Mixtures; Molar concentration; Molten carbonate; Nitric oxide; Nitric oxide formation; Numerical examples; Octane; Onsager's reciprocal relationship; Otto, diesel, dual combustion cycles; Peltier; Perfect, ideal van der Waals gases; Phosphoric acid; pinch point; pinch technology; Pollutants from chemical kinetics; Practical engine; Premixed and diffusion flames; Products of combustion; Properties; Quality of energy; Rankine cycle; Rational efficiency; Reaction order; Reaction rates; Realistic engine cycle; Refrigerators; Regenerated gas turbine; Reheat cycle; Reversibility; Reversible and irreversible processes; Rich and lean mixtures; Second law (of thermodynamics); Second law of thermodynamics; Seebeck; Solid oxide; Solid polymer; Soret; Sources of hydrogen; Spark ignition engine; Specific heat capacity at constant volume and pressure; Stability; Steady state thermodynamics; Stoichiometry; Systems; Tables of properties for ideal gas; Tafel constant; Temperature scale; Thermal efficiency; Thermal equilibrium; Thermocouple; Thermodynamic forces and velocities; Thermodynamic relationships; Thermodynamics of combustion; Thermodynamics of fuel cell in steady state; Thermoelectricity; Thomson; Turbofan; Turbojet; Turbulent flame speed; Two-phase region; Unavailable energy; Unsteady flow energy equation; Useful work; van der Waals equation; van't Hoff relationship
1. Introduction and Revision 2. The Second Law and Equilibrium 3. Engine Cycles and Their Efficiencies 4. Availability and Exergy 5. Rational Efficiency and Powerplant 6. Finite Time (or endoreversible) Thermodynamics (FTT) 7. General Thermodynamic Relationships: for single component systems, or systems of constant composition 8. Equations of State 9. Thermodynamic Properties of Ideal Gases and Ideal Gas Mixtures of Constant Composition 10. Thermodynamics of Combustion 11. Chemistry of Combustion 12. Chemical Equilibrium and Dissociation 13. Effect of Dissociation on Combustion Parameters 14. Chemical Kinetics 15. Combustion and Flames 16. Reciprocating Internal Combustion Engines 17. Gas Turbines 18. Liquefaction of Gases 19. Pinch Technology 20. Irreversible Thermodynamics 21. Fuel Cells
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
Air-fuel ratio; Air-standard cycles; Aircraft gas turbines; Analysis of engine cycle; Availability; Bond energy; Carbon dioxide-dry ice; Carnot cycle; Chemical kinetics; Chemical potential; Chemical structure; Clausius-Clapeyron equation; Combined cycle; Combustion; Combustion chamber; Compression ratio; Datum levels; Diesel engine; Diffusion and heat transfer; Diffusion flames; Direct methanol; Dissociation; Dufour; Effect of friction; Efficiency of fuel cell; Electric cells; Electrochemical potential; Electromotive force (emf); Engine speed; Enthalpy; Enthalpy of reaction; Entropy; Entropy flow; Entropy of ideal gas; Entropy production; Equilibrium; Equilibrium combustion; Equilibrium constant, Kp; Equivalence ratios; Exchange current; Exergy; Exhaust gas recirculation; Explosion limits; Fossil fuels; Fuel cells-alkaline; Gas turbine combustion chamber; Gas turbine cycle; Gas turbine cycles; Gibbs energy; Gibbs energy and stability of isotherm; Gibbs energy of ideal gas; Gibbs-Dalton law; heat cascading; Heat engines; Heat of formation; Heat pumps; heat transfer networks; Heats of reaction and formation; Helmholtz energy; Hess' law; Ideal and perfect gas laws; Ideal gases; Ignition timing; Inefficiencies; Intercooled cycle; Internal energy; Internal energy and enthalpy; Irreversibility; Irreversible thermodynamics; Joule-Thomson effect; Laminar flame speed; Law of corresponding states; Law of mass action; Laws of thermodynamics; Linde liquefaction plant analysis; Liquefaction; Liquefying van der Waals gas; Losses in cells; Maximum and minimum inversion temperatures; Maxwell relationships; Mean temperature of energy addition and rejection; Methane; Mixtures; Molar concentration; Molten carbonate; Nitric oxide; Nitric oxide formation; Numerical examples; Octane; Onsager's reciprocal relationship; Otto, diesel, dual combustion cycles; Peltier; Perfect, ideal van der Waals gases; Phosphoric acid; pinch point; pinch technology; Pollutants from chemical kinetics; Practical engine; Premixed and diffusion flames; Products of combustion; Properties; Quality of energy; Rankine cycle; Rational efficiency; Reaction order; Reaction rates; Realistic engine cycle; Refrigerators; Regenerated gas turbine; Reheat cycle; Reversibility; Reversible and irreversible processes; Rich and lean mixtures; Second law (of thermodynamics); Second law of thermodynamics; Seebeck; Solid oxide; Solid polymer; Soret; Sources of hydrogen; Spark ignition engine; Specific heat capacity at constant volume and pressure; Stability; Steady state thermodynamics; Stoichiometry; Systems; Tables of properties for ideal gas; Tafel constant; Temperature scale; Thermal efficiency; Thermal equilibrium; Thermocouple; Thermodynamic forces and velocities; Thermodynamic relationships; Thermodynamics of combustion; Thermodynamics of fuel cell in steady state; Thermoelectricity; Thomson; Turbofan; Turbojet; Turbulent flame speed; Two-phase region; Unavailable energy; Unsteady flow energy equation; Useful work; van der Waals equation; van't Hoff relationship
