Entropy Generation Minimization The Method of Thermodynamic Optimization of Finite-Size Systems and Finite-Time Processes

Presents the diverse field of Entropy Generation Minimization (EGM), the method of thermodynamic optimization of real devices. This book combines the fundamental principles of thermodynamics, heat transfer, and fluid mechanics.

This book presents the diverse and rapidly expanding field of Entropy Generation Minimization (EGM), the method of thermodynamic optimization of real devices. The underlying principles of the EGM method - also referred to as "thermodynamic optimization," "thermodynamic design," and "finite time thermodynamics" - are thoroughly discussed, and the method's applications to real devices are clearly illustrated. The EGM field has experienced tremendous growth during the 1980s and 1990s. This book places EGM's growth in perspective by reviewing both sides of the field - engineering and physics. Special emphasis is given to chronology and to the relationship between the more recent work and the pioneering work that outlined the method and the field. Entropy Generation Minimization combines the fundamental principles of thermodynamics, heat transfer, and fluid mechanics. EGM applies these principles to the modeling and optimization of real systems and processes that are characterized by finite size and finite time constraints, and are limited by heat and mass transfer and fluid flow irreversibilities.Entropy Generation Minimization provides a straightforward presentation of the principles of the EGM method, and features examples that elucidate concepts and identify recent EGM advances in engineering and physics. Modern advances include the optimization of storage by melting and solidification; heat exchanger design; power from hot-dry-rock deposits; the on & off operation of defrosting refrigerators and power plants with fouled heat exchangers; the production of ice and other solids; the maximization of power output in simple power plant models with heat transfer irreversibilities; the minimization of refrigerator power input in simple models; and the optimal collection and use of solar energy.

List of SymbolsThermodynamics Concepts and LawsDefinitionsClosed SystemsOpen SystemsThe Momentum TheoremUseful Steps in Problem SolvingThe Temperature-Energy Interaction Diagram, and the Entropy Interaction-Energy Interaction DiagramProblemsEntropy Generation and Exergy DestructionThe Gouy-Stodola TheoremSystems Communicating with More than One Heat ReservoirAdiabatic SystemsExergy Analysis of Steady Flow ProcessesExergy Analysis of Non-Flow ProcessesCharacteristic Features of Irreversible Systems and ProcessesProblemsEntropy Generation in Fluid FlowRelationship between Entropy Generation and Viscous DissipationLaminar FlowTurbulent FlowThe TransitionBuckling Theory of Turbulent FlowEntropy Generation in "Isothermal" Turbulent FlowThe Bernoulli EquationEntropy Generation in Heat TransferThe Local Rate of Entropy Generation in Convective Heat TransferFluid Friction vs. Heat Transfer IrreversibilityInternal FlowsExternal FlowsConduction Heat TransferConvective Mass TransferGeneral Heat Exchanger PassageHeat Transfer Augmentation TechniquesProblemsHeat ExchangersCounterflow Heat ExchangersHeat Exchangers with Negligible Pressure Drop IrreversibilityThe Three-Part Structure of Heat Exchanger IrreversibilityTwo-Phase-Flow Heat ExchangersOther Heat Exchanger Entropy Generation StudiesDistribution of Heat Exchanger Area on the Absolute Temperature ScaleDistribution of Heat Transfer Area in Counterflow Heat ExchangersProblemsInsulation SystemsPower Plants and Refrigeration Plants as Insulation SystemsThe Generation of Entropy in an Insulation with Fixed GeometryOptimum Continuous Cooling RegimeCounterflow Heat Exchangers as One-Dimensional InsulationsParallel InsulationsIntermediate Cooling or Heating of Insulation Systems for Power and Refrigeration PlantsProblemsStorage SystemsSensible Heat StorageOptimum Heating and Cooling Processes Subject to Time ConstraintHot Storage vs. Cold StorageLatent Heat StoragePower GenerationModel with Bypass Heat Leak and Two Finite-Size Heat ExchangersPower Plant Viewed as an Insulation Between Heat Source and AmbientCombined-Cycle Power PlantOptimal Combustion Chamber TemperatureOther Power Plant Optimization StudiesWhy Maximum Power Means Minimum Entropy Generation RateMaximum Power from Fluid FlowProblemsSolar-Thermal Power GenerationModels with Collector Heat Loss to the AmbientCollector-Ambient Heat Loss and Collector-Engine Heat ExchangerCollector-Ambient Heat Loss and Engine-Ambient Heat ExchangerStorage by MeltingExtraterrestrial Solar Power PlantNonisothermal CollectorsTime-Varying ConditionsOther Areas of Solar Power Conversion StudyProblemsRefrigerationRefrigeration Plant Model with Heat Transfer IrreversibilitiesModel with Heat Leak in Parallel with Reversible CompartmentModel with Cold End Heat Exchanger and Room Temperature Heat ExchangerMinimization of the Heat-Leak Entropy GenerationProblemsTime-Dependent OperationDefrosting RefrigeratorsCleaning the Heat Exchanger of a Power PlantPower Plants Driven by Heating from a Bed of Hot Dry RockMaximum Rate of Ice ProductionProblemsAppendicesLocal Entropy Generation RateVariational CalculusAuthor IndexSubject Index