Advanced Thermodynamics for Engineers /

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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
Clasificación:Libro Electrónico
Autores principales: Winterbone, D. E. (Autor), Turan, Ali (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Kidlington, Oxford, UK : Butterworth-Heinemann, [2015]
Edición:Second edition.
Temas:
Thermodynamics.
Thermodynamics
Thermodynamique.
thermodynamics.
TECHNOLOGY & ENGINEERING > Mechanical.
Handbook
handbooks.
Handbooks and manuals
Handbooks and manuals.
Guides et manuels.
Acceso en línea:Texto completo
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.

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