Advanced thermodynamics for engineers

Advanced thermodynamics for engineers

Advanced Thermodynamics for Engineers, Second Edition introduces the basic concepts of thermodynamics and applies them to a wide range of technologies. Authors Desmond Winterbone and Ali Turan also include a detailed study of combustion to show how the chemical energy in a fuel is converted into the...

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Detalles Bibliográficos
Otros Autores: Winterbone, D. E., author (author), Turan, Ali, author
Formato: Libro electrónico
Idioma:Inglés
Publicado: Oxford, [England] ; Waltham, Massachusetts : Butterworth-Heinemann 2015.
Edición:Second edition
Materias:
Thermodynamics.
Ver en Biblioteca Universitat Ramon Llull:https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009644259006719
Tabla de Contenidos:
  • Front Cover; Advanced Thermodynamics for Engineers; Copyright; Contents; Preface - First Edition; Preface - Second Edition; Structure of the Book; Notation; CHAPTER 1 - INTRODUCTION AND REVISION; 1.1 THERMODYNAMICS; 1.2 DEFINITIONS; 1.3 THERMAL EQUILIBRIUM AND THE ZEROTH LAW; 1.4 TEMPERATURE SCALES; 1.5 INTERACTIONS BETWEEN SYSTEMS AND SURROUNDINGS; 1.6 CONCLUDING REMARKS; 1.7 PROBLEMS; CHAPTER 2 - THE SECOND LAW AND EQUILIBRIUM; 2.1 THERMAL EFFICIENCY; 2.2 HEAT ENGINE; 2.3 SECOND LAW OF THERMODYNAMICS; 2.4 THE CONCEPT OF THE HEAT ENGINE: DERIVED BY ANALOGY WITH A HYDRAULIC DEVICE (TABLE 2.1)
  • 2.5 THE ABSOLUTE TEMPERATURE SCALE2.6 ENTROPY; 2.7 REPRESENTATION OF HEAT ENGINES; 2.8 REVERSIBILITY AND IRREVERSIBILITY (FIRST COROLLARY OF SECOND LAW); 2.9 EQUILIBRIUM; 2.10 HELMHOLTZ ENERGY (HELMHOLTZ FUNCTION); 2.11 GIBBS ENERGY; 2.12 GIBBS ENERGY AND PHASES; 2.13 EXAMPLES OF DIFFERENT FORMS OF EQUILIBRIUM MET IN THERMODYNAMICS; 2.14 CONCLUDING REMARKS; 2.15 PROBLEMS; CHAPTER 3 - ENGINE CYCLES AND THEIR EFFICIENCIES; 3.1 HEAT ENGINES; 3.2 AIR-STANDARD CYCLES; 3.3 GENERAL COMMENTS ON EFFICIENCIES; 3.4 REVERSED HEAT ENGINES; 3.5 CONCLUDING REMARKS; 3.6 PROBLEMS
  • CHAPTER 4 - AVAILABILITY AND EXERGY4.1 DISPLACEMENT WORK; 4.2 AVAILABILITY; 4.3 EXAMPLES; 4.4 AVAILABLE AND NON-AVAILABLE ENERGY; 4.5 IRREVERSIBILITY; 4.6 GRAPHICAL REPRESENTATION OF AVAILABLE ENERGY AND IRREVERSIBILITY; 4.7 AVAILABILITY BALANCE FOR A CLOSED SYSTEM; 4.8 AVAILABILITY BALANCE FOR AN OPEN SYSTEM; 4.9 EXERGY; 4.10 THE VARIATION OF FLOW EXERGY FOR A PERFECT GAS; 4.11 CONCLUDING REMARKS; 4.12 PROBLEMS; CHAPTER 5 - RATIONAL EFFICIENCY OF POWER PLANT; 5.1 THE INFLUENCE OF FUEL PROPERTIES ON THERMAL EFFICIENCY; 5.2 RATIONAL EFFICIENCY; 5.3 RANKINE CYCLE; 5.4 EXAMPLES
  • 5.5 CONCLUDING REMARKS5.6 PROBLEMS; CHAPTER 6 - FINITE TIME (OR ENDOREVERSIBLE) THERMODYNAMICS; 6.1 GENERAL CONSIDERATIONS; 6.2 EFFICIENCY AT MAXIMUM POWER; 6.3 EFFICIENCY OF COMBINED CYCLE INTERNALLY REVERSIBLE HEAT ENGINES WHEN PRODUCING MAXIMUM POWER OUTPUT; 6.4 PRACTICAL SITUATIONS; 6.5 MORE COMPLEX EXAMPLE OF THE USE OF FTT; 6.6 CONCLUDING REMARKS; 6.7 PROBLEMS; CHAPTER 7 - GENERAL THERMODYNAMIC RELATIONSHIPS: FOR SINGLE COMPONENT SYSTEMS OR SYSTEMS OF CONSTANT COMPOSITION; 7.1 THE MAXWELL RELATIONSHIPS; 7.2 USES OF THE THERMODYNAMIC RELATIONSHIPS; 7.3 TDS RELATIONSHIPS
  • 7.4 RELATIONSHIPS BETWEEN SPECIFIC HEAT CAPACITIES7.5 THE CLAUSIUS-CLAPEYRON EQUATION; 7.6 CONCLUDING REMARKS; 7.7 PROBLEMS; CHAPTER 8 - EQUATIONS OF STATE; 8.1 IDEAL GAS LAW; 8.2 VAN DER WAALS EQUATION OF STATE; PROBLEM; 8.3 LAW OF CORRESPONDING STATES; 8.4 ISOTHERMS OR ISOBARS IN THE TWO-PHASE REGION; 8.5 CONCLUDING REMARKS; 8.6 PROBLEMS; CHAPTER 9 - THERMODYNAMIC PROPERTIES OF IDEAL GASES AND IDEAL GAS MIXTURES OF CONSTANT COMPOSITION; 9.1 MOLECULAR WEIGHTS; 9.2 STATE EQUATION FOR IDEAL GASES; 9.3 TABLES OF U(T) AND H(T) AGAINST T; 9.4 MIXTURES OF IDEAL GASES; 9.5 ENTROPY OF MIXTURES
  • 9.6 CONCLUDING REMARKS

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