Title Pinch analysis for energy and carbon footprint reduction user guide to process integration for the efficient use of energy / Ian C. Kemp, Jeng Shiun Lim

Edition Third edition Published Amsterdam : Butterworth-Heinemann, 2020

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Description 1 online resource Contents Intro -- Pinch Analysis for Energy and Carbon Footprint Reduction: User Guide to Process Integration for the Efficient Use of Energy -- Copyright -- Contents -- Foreword to the first edition -- Foreword to the second edition -- Preface -- Acknowledgements -- Figure acknowledgements -- Abbreviations -- Chapter 1: Introduction -- 1.1. What is pinch analysis? -- 1.2. Historical development and industrial experience -- 1.3. Why does pinch analysis work? -- 1.4. The concept of process synthesis -- 1.5. Hierarchy of energy reduction -- 1.6. The role of thermodynamics in process design 1.6.1. How can we apply thermodynamics practically? -- 1.6.2. Capital and energy costs -- 1.7. Learning and applying the techniques -- 1.8. A note on terminology -- References -- Chapter 2: Carbon footprint and primary energy -- 2.1. Introduction -- 2.2. Definition of carbon footprint -- 2.3. Primary energy -- 2.4. Carbon dioxide emissions and carbon footprint -- 2.4.1. Carbon footprint of fuel and electricity -- 2.4.2. Lifecycle emissions -- 2.5. Components of carbon footprint -- 2.6. Carbon pinch and emissions targeting -- 2.7. Energy costs -- 2.8. Conclusions -- References Chapter 3: Key concepts of pinch analysis -- 3.1. Heat recovery and heat exchange -- 3.1.1. Basic concepts of heat exchange -- 3.1.2. The temperature-enthalpy diagram -- 3.1.3. Composite curves -- 3.1.4. A targeting procedure -- the ̀̀problem table ́́ -- 3.1.5. The grand composite curve and shifted composite curves -- 3.2. The pinch and its significance -- 3.3. Heat exchanger network design -- 3.3.1. Network grid representation -- 3.3.2. A ̀̀commonsense ́́network design -- 3.3.3. Design for maximum energy recovery -- 3.3.4. A word about design strategy -- 3.4. Choosing DeltaTmin: supertargeting 3.4.1. Further implications of the choice of DeltaTmin -- 3.5. Methodology of pinch analysis -- 3.5.1. The range of pinch analysis techniques -- 3.5.2. How to do a Pinch Study -- 3.6. Exercise -- References -- Chapter 4: Data extraction and energy targeting -- 4.1. Data extraction -- 4.1.1. Heat and mass balance -- 4.1.2. Stream data extraction -- 4.1.3. Calculating heat loads and heat capacities -- 4.1.4. Choosing streams -- 4.1.5. Mixing -- 4.1.6. Heat losses -- 4.1.7. Summary guidelines -- 4.2. Case study -- organics distillation plant -- 4.2.1. Process description 4.2.2. Heat and mass balance -- 4.2.3. Stream data extraction -- 4.2.4. Cost data -- 4.3. Energy targeting -- 4.3.1. DeltaTmin contributions for individual streams -- 4.3.2. Threshold problems -- 4.4. Multiple utilities -- 4.4.1. Types of utility -- 4.4.2. The Appropriate Placement principle -- 4.4.3. Constant temperature utilities -- 4.4.4. Utility pinches -- 4.4.5. Variable temperature utilities -- 4.4.5.1. Once-through streams -- 4.4.5.2. Recirculating systems -- 4.4.6. Balanced composite and grand composite curves -- 4.4.7. Choice of multiple utility levels Subject Chemical plants -- Energy conservation Chemical processes. Chemical process control. Chemical plants -- Energy conservation Chemical process control Chemical processes Form Electronic book Author Shiun Lim, Jeng, author ISBN 9780081025376 0081025378

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