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Pinch analysis for energy and carbon...

Kemp, Ian C.

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Pinch analysis for energy and carbon footprint reduction = user guide to process integration for the efficient use of energy /

Record Type:	Electronic resources : Monograph/item
Title/Author:	Pinch analysis for energy and carbon footprint reduction/ Ian C. Kemp, Jeng Shiun Lim.
Reminder of title:	user guide to process integration for the efficient use of energy /
Author:	Kemp, Ian C.
other author:	Shiun Lim, Jeng.
Published:	Amsterdam :Butterworth-Heinemann, : 2020.,
Description:	1 online resource.
Notes:	Previous edition: published as Pinch analysis and process integration. 2007.
[NT 15003449]:	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 1.7 Learning and applying the techniques 1.8 A note on terminology 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 2.5 Components of carbon footprint 2.6 Carbon pinch and emissions targeting 2.7 Energy costs 2.8 Conclusions 3.
[NT 15003449]:	Key concepts of pinch analysis 3.1 Heat recovery and heat exchange 3.2 The pinch and its significance 3.3 Heat exchanger network design 3.4 Choosing [delta]Tmin: supertargeting 3.5 Methodology of pinch analysis 3.6 Worked exercise 4. Data extraction and energy targeting 4.1 Data extraction 4.2 Case study - organics distillation plant 4.3 Energy targeting 4.4 Multiple utilities 4.5 More advanced energy targeting 4.6 Targeting heat exchange units, area and shells 4.7 Supertargeting; cost targeting for optimal [delta]Tmin 4.8 Targeting for organics distillation plant case study 4.9 Exercises Appendix -- Algorithms for Problem Table and composite curves 5.
[NT 15003449]:	Heat exchanger network design 5.1 Introduction 5.2 Heat exchange equipment 5.3 Stream splitting and cyclic matching 5.4 Network relaxation 5.5 More complex designs 5.6 Multiple pinches and near-pinches 5.7 Retrofit design 5.8 Operability; multiple base case design 5.9 Network design for organics distillation case study 5.10 Conclusions 5.11 Exercises 6. Utilities, heat and power systems 6.1 Concepts 6.2 Combined heat and power systems 6.3 Heat pumps and refrigeration systems 6.4 Total site analysis 6.5 Worked example -- organics distillation unit 6.6 Worked case study and example for total site problem table algorithm 6.7 Case studies and examples 6.8 Exercises 7.
[NT 15003449]:	Process change and evolution 7.1 Concepts 7.2 General principles 7.3 Reactor systems 7.4 Distillation columns 7.5 Evaporator systems 7.6 Flash systems 7.7 Solids drying 7.8 Other separation methods 7.9 Application to the organics distillation process case study 7.10 Summary and conclusions 7.11 Exercises 8. Batch and time-dependent processes 8.1 Introduction 8.2 Concepts 8.3 Types of streams in batch processes 8.4 Time intervals 8.5 Calculating energy targets 8.6 Heat exchanger network design 8.7 Rescheduling 8.8 Debottlenecking 8.9 Other time-dependent applications 8.10 Conclusions 9.
[NT 15003449]:	Water, hydrogen, and carbon pinch 9.1 Introduction 9.2 Concepts 9.3 Key steps in mass pinch analysis 9.4 Application and case study for water pinch analysis (Glove Industry) 9.5 Application and case study for hydrogen pinch analysis 9.6 Conclusions for water and hydrogen pinch analysis 9.7 Carbon pinch 10. Applying the technology in practice 10.1 Introduction 10.2 How to do a pinch study 10.3 Heat and mass balance 10.4 Stream data extraction 10.5 Targeting and network design 10.6 Project evaluation and costing 10.7 Targeting software 10.8 Exercises 11.
[NT 15003449]:	Industrial experience 11.1 Overview 11.2 Oil refining 11.3 Bulk chemicals -- continuous 11.4 Speciality and batch chemicals and pharmaceuticals 11.5 Pulp and paper 11.6 Food and beverage 11.7 Consumer products and textiles 11.8 Minerals and metals 11.9 Heat and power utilities 11.10 Buildings 11.11 Waste processing and sewage 12. Case studies 12.1 Introduction 12.2 Crude preheat train 12.3 Aromatics plant 12.4 Evaporator/dryer plant 12.5 Organic chemicals manufacturing site 12.6 Food processing plant 12.7 Hospital site 12.8 Conclusions 12.9 Exercises 13. Conclusions Notation Further reading Appendix 1. Using the spreadsheet software Appendix 2. Answers to selected exercises Index.
Subject:	Chemical plants - Energy conservation. -
Online resource:	https://www.sciencedirect.com/science/book/9780081025369
ISBN:	9780081025376 (electronic bk.)

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

Pinch analysis for energy and carbon footprint reductionuser guide to process integration for the efficient use of energy /[electronic resource] :Ian C. Kemp, Jeng Shiun Lim. - 3rd ed. - Amsterdam :Butterworth-Heinemann,2020. - 1 online resource. - IChemE. - Butterworth-Heinemann/IChemE series..

Previous edition: published as Pinch analysis and process integration. 2007.

Includes bibliographical references and index.

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 1.7 Learning and applying the techniques 1.8 A note on terminology 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 2.5 Components of carbon footprint 2.6 Carbon pinch and emissions targeting 2.7 Energy costs 2.8 Conclusions 3.

ISBN: 9780081025376 (electronic bk.)

Nat. Bib. No.: GBC087810bnbSubjects--Topical Terms:

1613361
Chemical plants
--Energy conservation.Index Terms--Genre/Form:

542853
Electronic books.

LC Class. No.: TJ163.5.C54

Dewey Class. No.: 660.2812

Pinch analysis for energy and carbon footprint reduction = user guide to process integration for the efficient use of energy /
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505 0 $a 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 1.7 Learning and applying the techniques 1.8 A note on terminology 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 2.5 Components of carbon footprint 2.6 Carbon pinch and emissions targeting 2.7 Energy costs 2.8 Conclusions 3.
505 0 $a Key concepts of pinch analysis 3.1 Heat recovery and heat exchange 3.2 The pinch and its significance 3.3 Heat exchanger network design 3.4 Choosing [delta]Tmin: supertargeting 3.5 Methodology of pinch analysis 3.6 Worked exercise 4. Data extraction and energy targeting 4.1 Data extraction 4.2 Case study - organics distillation plant 4.3 Energy targeting 4.4 Multiple utilities 4.5 More advanced energy targeting 4.6 Targeting heat exchange units, area and shells 4.7 Supertargeting; cost targeting for optimal [delta]Tmin 4.8 Targeting for organics distillation plant case study 4.9 Exercises Appendix -- Algorithms for Problem Table and composite curves 5.
505 0 $a Heat exchanger network design 5.1 Introduction 5.2 Heat exchange equipment 5.3 Stream splitting and cyclic matching 5.4 Network relaxation 5.5 More complex designs 5.6 Multiple pinches and near-pinches 5.7 Retrofit design 5.8 Operability; multiple base case design 5.9 Network design for organics distillation case study 5.10 Conclusions 5.11 Exercises 6. Utilities, heat and power systems 6.1 Concepts 6.2 Combined heat and power systems 6.3 Heat pumps and refrigeration systems 6.4 Total site analysis 6.5 Worked example -- organics distillation unit 6.6 Worked case study and example for total site problem table algorithm 6.7 Case studies and examples 6.8 Exercises 7.
505 0 $a Process change and evolution 7.1 Concepts 7.2 General principles 7.3 Reactor systems 7.4 Distillation columns 7.5 Evaporator systems 7.6 Flash systems 7.7 Solids drying 7.8 Other separation methods 7.9 Application to the organics distillation process case study 7.10 Summary and conclusions 7.11 Exercises 8. Batch and time-dependent processes 8.1 Introduction 8.2 Concepts 8.3 Types of streams in batch processes 8.4 Time intervals 8.5 Calculating energy targets 8.6 Heat exchanger network design 8.7 Rescheduling 8.8 Debottlenecking 8.9 Other time-dependent applications 8.10 Conclusions 9.
505 0 $a Water, hydrogen, and carbon pinch 9.1 Introduction 9.2 Concepts 9.3 Key steps in mass pinch analysis 9.4 Application and case study for water pinch analysis (Glove Industry) 9.5 Application and case study for hydrogen pinch analysis 9.6 Conclusions for water and hydrogen pinch analysis 9.7 Carbon pinch 10. Applying the technology in practice 10.1 Introduction 10.2 How to do a pinch study 10.3 Heat and mass balance 10.4 Stream data extraction 10.5 Targeting and network design 10.6 Project evaluation and costing 10.7 Targeting software 10.8 Exercises 11.
505 0 $a Industrial experience 11.1 Overview 11.2 Oil refining 11.3 Bulk chemicals -- continuous 11.4 Speciality and batch chemicals and pharmaceuticals 11.5 Pulp and paper 11.6 Food and beverage 11.7 Consumer products and textiles 11.8 Minerals and metals 11.9 Heat and power utilities 11.10 Buildings 11.11 Waste processing and sewage 12. Case studies 12.1 Introduction 12.2 Crude preheat train 12.3 Aromatics plant 12.4 Evaporator/dryer plant 12.5 Organic chemicals manufacturing site 12.6 Food processing plant 12.7 Hospital site 12.8 Conclusions 12.9 Exercises 13. Conclusions Notation Further reading Appendix 1. Using the spreadsheet software Appendix 2. Answers to selected exercises Index.
650 0 $a Chemical plants $x Energy conservation. $3 1613361
650 0 $a Chemical processes. $3 711045
650 0 $a Chemical process control. $3 663129
655 4 $a Electronic books. $2 lcsh $3 542853
700 1 $a Shiun Lim, Jeng. $3 3614957
830 0 $a Butterworth-Heinemann/IChemE series. $3 1639406
856 4 0 $u https://www.sciencedirect.com/science/book/9780081025369