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101 0 $aeng
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181   $2rdacontent
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200 10$aAdvanced engineering thermodynamics /$fAdrian Bejan
205   $a4th ed
210   $aHoboken, N.J.$cWiley$dc2016
210  1$aHoboken, New Jersey :$cJohn Wiley & Sons, Inc.,$d2016.
210  4$d©2016
215   $a1 online resource (789 p.)
300   $aIncludes bibliographical references and index
311 08$a9781119052098 
311 08$a1119052092 
320   $aIncludes bibliographical references at the end of each chapters and index.
327   $aCover; Title Page; Copyright; Contents; Preface to the First Edition; Preface to the Second Edition; Preface to the Third Edition; Preface; Acknowledgments; Chapter 1 The First Law; 1.1 Terminology; 1.2 Closed Systems; 1.3 Work Transfer; 1.4 Heat Transfer; 1.5 Energy Change; 1.6 Open Systems; 1.7 History; References; Problems; Chapter 2 The Second Law; 2.1 Closed Systems; 2.1.1 Cycle in Contact with One Temperature Reservoir; 2.1.2 Cycle in Contact with Two Temperature Reservoirs; 2.1.3 Cycle in Contact with Any Number of Temperature Reservoirs
327   $a2.1.4 Process in Contact with Any Number of Temperature Reservoirs2.2 Open Systems; 2.3 Local Equilibrium; 2.4 Entropy Maximum and Energy Minimum; 2.5 Carathe?odory's Two Axioms; 2.6 A Heat Transfer Man's Two Axioms; 2.7 History; References; Problems; Chapter 3 Entropy Generation, or Exergy Destruction; 3.1 Lost Available Work; 3.2 Cycles; 3.2.1 Heat Engine Cycles; 3.2.2 Refrigeration Cycles; 3.2.3 Heat Pump Cycles; 3.3 Nonflow Processes; 3.4 Steady-Flow Processes; 3.5 Mechanisms of Entropy Generation; 3.5.1 Heat Transfer across a Temperature Difference; 3.5.2 Flow with Friction; 3.5.3 Mixing
327   $a3.6 Entropy Generation Minimization3.6.1 The Method; 3.6.2 Tree-Shaped Fluid Flow; 3.6.3 Entropy Generation Number; References; Problems; Chapter 4 Single-Phase Systems; 4.1 Simple System; 4.2 Equilibrium Conditions; 4.3 The Fundamental Relation; 4.3.1 Energy Representation; 4.3.2 Entropy Representation; 4.3.3 Extensive Properties versus Intensive Properties; 4.3.4 The Euler Equation; 4.3.5 The Gibbs-Duhem Relation; 4.4 Legendre Transforms; 4.5 Relations between Thermodynamic Properties; 4.5.1 Maxwell's Relations; 4.5.2 Relations Measured during Special Processes; 4.5.3 Bridgman's Table
327   $a4.5.4 Jacobians in Thermodynamics4.6 Partial Molal Properties; 4.7 Ideal Gas Mixtures; 4.8 Real Gas Mixtures; References; Problems; Chapter 5 Exergy Analysis; 5.1 Nonflow Systems; 5.2 Flow Systems; 5.3 Generalized Exergy Analysis; 5.4 Air Conditioning; 5.4.1 Mixtures of Air and Water Vapor; 5.4.2 Total Flow Exergy of Humid Air; 5.4.3 Total Flow Exergy of Liquid Water; 5.4.4 Evaporative Cooling; References; Problems; Chapter 6 Multiphase Systems; 6.1 The Energy Minimum Principle; 6.1.1 The Energy Minimum; 6.1.2 The Enthalpy Minimum; 6.1.3 The Helmholtz Free-Energy Minimum
327   $a6.1.4 The Gibbs Free-Energy Minimum6.1.5 The Star Diagram; 6.2 The Stability of a Simple System; 6.2.1 Thermal Stability; 6.2.2 Mechanical Stability; 6.2.3 Chemical Stability; 6.3 The Continuity of the Vapor and Liquid States; 6.3.1 The Andrews Diagram and J. Thomson's Theory; 6.3.2 The van der Waals Equation of State; 6.3.3 Maxwell's Equal-Area Rule; 6.3.4 The Clapeyron Relation; 6.4 Phase Diagrams; 6.4.1 The Gibbs Phase Rule; 6.4.2 Single-Component Substances; 6.4.3 Two-Component Mixtures; 6.5 Corresponding States; 6.5.1 Compressibility Factor; 6.5.2 Analytical P(v, T) Equations of State
327   $a6.5.3 Calculation of Properties Based on P(v, T) and Specific Heat
330   $aMoving effortlerssly among analysis, essay and graphics, this streamlined edition of Adrian Bejan's powerful presentation is aimed at students in all areas of engineering, physics and life sciences. An advanced, practical approach to the first and second laws of thermodynamicsAdvanced Engineering Thermodynamics bridges the gap between engineering applications and the first and second laws of thermodynamics. Going beyond the basic coverage offered by most textbooks, this authoritative treatment delves into the advanced topics of energy and work as they relate to various engineering fields. This practical approach describes real-world applications of thermodynamics concepts, including solar energy, refrigeration, air conditioning, thermofluid design, chemical design, constructal design, and more. This new fourth edition has been updated and expanded to include current developments in energy storage, distributed energy systems, entropy minimization, and industrial applications, linking new technologies in sustainability to fundamental thermodynamics concepts. Worked problems have been added to help students follow the thought processes behind various applications, and additional homework problems give them the opportunity to gauge their knowledge. The growing demand for sustainability and energy efficiency has shined a spotlight on the real-world applications of thermodynamics. This book helps future engineers make the fundamental connections, and develop a clear understanding of this complex subject. Delve deeper into the engineering applications of thermodynamics Work problems directly applicable to engineering fields Integrate thermodynamics concepts into sustainability design and policy Understand the thermodynamics of emerging energy technologiesCondensed introductory chapters allow students to quickly review the fundamentals before diving right into practical applications. Designed expressly for engineering students, this book offers a clear, targeted treatment of thermodynamics topics with detailed discussion and authoritative guidance toward even the most complex concepts. Advanced Engineering Thermodynamics is the definitive modern treatment of energy and work for today's newest engineers.
606   $6880-03/$1$aThermodynamics
615  0$aThermodynamics.
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996   $aAdvanced engineering thermodynamics$94388694
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