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010   $a9786612168352
010   $a0-08-091442-X
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100   $a20081031d2009      uy         0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aEnergy optimization in process systems /$fStanislaw Sieniutycz
210   $aOxford ;$aAmsterdam $cElsevier$d2009
215   $a1 online resource (771 p.)
300   $aDescription based upon print version of record.
311   $a0-08-045141-1 
320   $aIncludes bibliographical references and index.
327   $aFront cover; Energy Optimization in Process Systems; Copyright; Contents; Preface; Acknowledgements; Chapter 1: Brief review of static optimization methods; 1.1. Introduction: Signifi cance of Mathematical Models; 1.2. Unconstrained Problems; 1.3. Equality Constraints and Lagrange Multipliers; 1.4. Methods of Mathematical Programming; 1.5. Iterative Search Methods; 1.6. On Some Stochastic Optimization Techniques; Chapter 2: Dynamic optimization problems; 2.1. Discrete Representations and Dynamic Programming Algorithms; 2.2. Recurrence Equations
327   $a2.3. Discrete Processes Linear with Respect to the Time Interval2.4. Discrete Algorithm of the Pontryagin's Type for Processes Linear in e?N; 2.5. Hamilton-Jacobi-Bellman Equations for Continuous Systems; 2.6. Continuous Maximum Principle; 2.7. Calculus of Variations; 2.8. Viscosity Solutions and Non-smooth Analyses; 2.9. Stochastic Control and Stochastic Maximum Principle; Chapter 3: Energy limits for thermal engines and heat-pumps at steady states; 3.1. Introduction: Role of Optimization in Determining Thermodynamic Limits; 3.2. Classical Problem of Thermal Engine Driven by Heat Flux
327   $a3.3. Toward Work Limits in Sequential Systems3.4. Energy Utilization and Heat-pumps; 3.5. Thermal Separation Processes; 3.6. Steady Chemical, Electrochemical and Other Systems; 3.7. Limits in Living Systems; 3.8. Final Remarks; Chapter 4: Hamiltonian optimization of imperfect cascades; 4.1. Basic Properties of Irreversible Cascade Operations with a Work Flux; 4.2. Description of Imperfect Units in Terms of Carnot Temperature Control; 4.3. Single-stage Formulae in a Model of Cascade Operation; 4.4. Work Optimization in Cascade by Discrete Maximum Principle; 4.5. Example
327   $a4.6. Continuous Imperfect System with Two Finite Reservoirs4.7. Final Remarks; Chapter 5: Maximum power from solar energy; 5.1. Introducing Carnot Controls for Modeling Solar-assisted Operations; 5.2. Thermodynamics of Radiation; 5.3. Classical Exergy of Radiation; 5.4. Flux of Classical Exergy; 5.5. Effi ciencies of Energy Conversion; 5.6. Towards a Dissipative Exergy of Radiation at Flow; 5.7. Basic Analytical Formulae of Steady Pseudo-Newtonian Model; 5.8. Steady Non-Linear Models applying Stefan-Boltzmann Equation; 5.9. Dynamical Theory for Pseudo-Newtonian Models
327   $a5.10. Dynamical Models using the Stefan-Boltzmann Equation5.11. Towards the Hamilton-Jacobi-Bellman Approaches; 5.12. Final Remarks; Chapter 6: Hamilton-Jacobi-Bellman theory of energy systems; 6.1. Introduction; 6.2. Dynamic Optimization of Power in a Finite-resource Process; 6.3. Two Different Works and Finite-Rate Exergies; 6.4. Some Aspects of Classical Analytical HJB Theory for Continuous Systems; 6.5. HJB Equations for Non-Linear Power Generation Systems; 6.6. Analytical Solutions in Systems with Linear Kinetics
327   $a6.7. Extensions for Systems with Non-Linear Kinetics and Internal Dissipation
330   $aThis book covers the optimization and integration of energy systems. The authors are world renowned specialists with extensive didactic experience. Their systematic approach uses thermodynamics, kinetics and economics to study the effect of equipment size, environmental parameters and economic factors on optimal power production and heat integration. They show that reduction of costs can be achieved, in particular costs of utilities common in chemical industry.Presents a unique synthesis of energy optimization and process integration that applies scientific information from thermodyna
606   $aEnergy conservation
606   $aEnergy transfer
615  0$aEnergy conservation.
615  0$aEnergy transfer.
676   $a660.281
676   $a660.281
686   $aVN 7300$2rvk
700   $aSieniutycz$b Stanislaw$0151702
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9911006628503321
996   $aEnergy optimization in process systems$94389065
997   $aUNINA