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101 0 $aeng
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200 10$aPinch analysis and process integration$b[electronic resource] $ea user guide on process integration for the efficient use of energy /$fby Ian Kemp
205   $a2nd ed.
210   $aOxford $cButterworth-Heinemann$d2007
215   $a1 online resource (415 p.)
300   $aPrevious ed.: 1994, as by B. Linnhoff et al.
311   $a0-7506-8260-4 
320   $aIncludes bibliographical references and index.
327   $aFront Cover; Pinch Analysis and Process Integration; Copyright page; Contents; Foreword; Foreword to the first edition; Preface; Acknowledgements; Figure acknowledgements; Chapter 1: Introduction; 1.1 What is pinch analysis?; 1.2 History and industrial experience; 1.3 Why does pinch analysis work?; 1.4 The concept of process synthesis; 1.5 The role of thermodynamics in process design; 1.5.1 How can we apply thermodynamics practically?; 1.5.2 Capital and energy costs; 1.6 Learning and applying the techniques; Chapter 2: Key concepts of pinch analysis; 2.1 Heat recovery and heat exchange
327   $a2.1.1 Basic concepts of heat exchange 2.1.2 The temperature-enthalpy diagram; 2.1.3 Composite curves; 2.1.4 A targeting procedure: the ""Problem Table""; 2.1.5 The grand composite curve and shifted composite curves; 2.2 The pinch and its significance; 2.3 Heat exchanger network design; 2.3.1 Network grid representation; 2.3.2 A ""commonsense"" network design; 2.3.3 Design for maximum energy recovery; 2.3.4 A word about design strategy; 2.4 Choosing ?T[sub(min)]: supertargeting; 2.4.1 Further implications of the choice of ?T[sub(min)]; 2.5 Methodology of pinch analysis
327   $a2.5.1 The range of pinch analysis techniques 2.5.2 How to do a pinch study; Exercise; Chapter 3: Data extraction and energy targeting; 3.1 Data extraction; 3.1.1 Heat and mass balance; 3.1.2 Stream data extraction; 3.1.3 Calculating heat loads and heat capacities; 3.1.4 Choosing streams; 3.1.5 Mixing; 3.1.6 Heat losses; 3.1.7 Summary guidelines; 3.2 Case study: organics distillation plant; 3.2.1 Process description; 3.2.2 Heat and mass balance; 3.2.3 Stream data extraction; 3.2.4 Cost data; 3.3 Energy targeting; 3.3.1 ?T[sub(min)] contributions for individual streams; 3.3.2 Threshold problems
327   $a3.4 Multiple utilities 3.4.1 Types of utility; 3.4.2 The Appropriate Placement principle; 3.4.3 Constant-temperature utilities; 3.4.4 Utility pinches; 3.4.5 Variable-temperature utilities; 3.4.6 Balanced composite and grand composite curves; 3.4.7 Choice of multiple utility levels; 3.5 More advanced energy targeting; 3.5.1 Zonal targeting; 3.5.2 Pressure drop targeting; 3.6 Targeting heat exchange units, area and shells; 3.6.1 Targeting for number of units; 3.6.2 Targeting for the minimum number of units; 3.6.3 Area targeting; 3.6.4 Deviations from pure countercurrent flow
327   $a3.6.5 Number of shells targeting 3.6.6 Performance of existing systems; 3.6.7 Topology traps; 3.7 Supertargeting: cost targeting for optimal ?T[sub(min)]; 3.7.1 Trade-offs in choosing ?T[sub(min)]; 3.7.2 Illustration for two-stream example; 3.7.3 Factors affecting the optimal ?T[sub(min)]; 3.7.4 Approximate estimation of ideal ?T[sub(min)]; 3.8 Targeting for organics distillation plant case study; 3.8.1 Energy targeting; 3.8.2 Area targeting; 3.8.3 Cost targeting; 3.8.4 Zonal targeting; 3.8.5 Targeting with utility streams included
327   $a3.9 Appendix: Algorithms for Problem Table and composite curves
330   $aPinch analysis and related techniques are the key to design of inherently energy-efficient plants. This book shows engineers how to understand and optimize energy use in their processes, whether large or small. Energy savings go straight to the bottom line as increased profit, as well as reducing emissions.This is the key guide to process integration for both experienced and newly qualified engineers, as well as academics and students. It begins with an introduction to the main concepts of pinch analysis, the calculation of energy targets for a given process, the pinch temperature and
606   $aChemical plants$xEnergy conservation
606   $aChemical processes
606   $aChemical process control
608   $aElectronic books.
615  0$aChemical plants$xEnergy conservation.
615  0$aChemical processes.
615  0$aChemical process control.
676   $a660.281
700   $aKemp$b Ian C$0599765
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910457691603321
996   $aPinch analysis and process integration$91021479
997   $aUNINA