Advances in distillation retrofit / Nguyen Van Duc Long, Moonyong Lee.
Long, Nguyen Van Duc.; Lee, Moonyong.
2017
TP156.D5
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Title Advances in distillation retrofit / Nguyen Van Duc Long, Moonyong Lee.
Author Long, Nguyen Van Duc.
ISBN 9789811059018 (electronic book)
9811059012 (electronic book)
9789811058998
9811058997
Publication Details Singapore : Springer, 2017.
Language English
Description 1 online resource.
Call Number TP156.D5
Dewey Decimal Classification 542/.4
540
Summary This book describes the current state of the art in the retrofit of existing distillation processes using advanced distillation techniques. Highlighting concept and practical application rather than theory, it emphasizes the use of advanced process integration and intensification techniques, such as multi-effect distillation, heat pump assisted distillation, thermally coupled distillation, dividing wall column, reactive distillation, and innovative hybrid systems. As a thermal separation method, distillation is one of the most important and widely used technologies in the chemical process industry. While it has many advantages, one major drawback is its large energy requirement, which can significantly influence overall plant profitability. The increasing cost of energy has forced industry to reduce its energy requirement, but simultaneously there has been a need to increase capacity and output due to heightened demand. To accomplish this, the retrofit of distillation processes to increase efficiency and output has become a crucial issue. This book describes the use of advanced process integration and process intensification techniques to carry out effective distillation retrofit. Written by leading researchers in distillation process, process integration, process intensification, and process retrofit, the book presents a comprehensive review of contemporary advanced distillation techniques which can be employed in grass-root systems and retrofit. It is a valuable source of information for undergraduate and postgraduate students of chemical engineering, practicing process designers and chemical engineers.
Access Note Access limited to authorized users.
Added Author Lee, Moonyong.
Available in Other Form Print version: 9811058997
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Preface; List of Abbreviations and Greek Letters; Contents; About the Authors; 1 Introduction; 1.1 Introduction; 1.2 Distillation Fundamentals and Principles; 1.2.1 Vapor Pressure; 1.2.2 Vapor-Liquid Equilibrium; 1.2.3 Dew Point and Bubble Point; 1.2.4 Equilibrium Flash Calculations; 1.3 Distillation Design; 1.3.1 Shortcut Methods; 1.3.2 Rigorous Methods; 1.4 Distillation Simulation; 1.4.1 Azeotrope Search; 1.4.2 Physical Property Methods; 1.4.3 Binary Parameters; 1.5 Distillation Process Retrofit/Revamp and Debottlenecking; 1.5.1 Process Integration; 1.5.2 Process Intensification

1.5.3 Combination of Heat Integration and Process Intensification1.6 Concluding Remarks; References; 2 Retrofit and Debottlenecking by Modifying Column Internal; 2.1 Introduction; 2.2 Types of Column Internal; 2.2.1 Trays; 2.2.2 Packings; 2.2.3 Column Internal Performances; 2.2.3.1 Hydraulic; 2.2.3.2 Efficiency; 2.2.3.3 Capacity; 2.2.4 Criteria for Selection of Vapor-Liquid Contactors; 2.3 Retrofit and Debottlenecking by Modifying Column Internal; 2.3.1 Using High Capacity/Efficiency Trays; 2.3.2 Using High Capacity/Efficiency Packings; 2.3.3 Column Internal Structure Modifications

2.3.4 Industrial Cases2.4 Case Study; 2.4.1 Existing Conventional Distillation; 2.4.2 Retrofitted Distillation; 2.5 Concluding Remarks; References; 3 Promising Retrofit Technologies for Single Column; 3.1 Introduction; 3.2 Heat Pump Assisted Distillation; 3.2.1 Introduction; 3.2.2 Working Principle of MVR; 3.2.3 MVR Configuration; 3.2.4 Pros and Cons of MVRs; 3.2.5 Case Study; 3.2.5.1 Existing Conventional Distillation; 3.2.5.2 Heat Pump Assisted Distillation; 3.3 Self-Heat Recuperation Technology; 3.3.1 Introduction; 3.3.2 Case Study; 3.4 Feed Thermal Condition; 3.4.1 Introduction

3.4.2 Case Study3.5 Side Reboiler and Side Condenser; 3.5.1 Introduction; 3.6 Operating Pressure Changing; 3.6.1 Introduction; 3.7 Multi-Effect Distillation; 3.7.1 Introduction; 3.7.2 Case Study; 3.7.2.1 Existing Conventional Distillation; 3.7.2.2 Debottlenecking; 3.8 Cyclic Distillation; 3.8.1 Introduction; 3.8.2 Retrofit to Cyclic Distillation; 3.9 Concluding Remarks; References; 4 Promising Retrofit Technologies for Multi-Column System; 4.1 Introduction; 4.2 Re-Arranging the Distillation Sequence; 4.2.1 Introduction; 4.2.2 Case Study; 4.2.2.1 Existing Conventional Distillation Sequence

4.2.2.2 Retrofitted Distillation Sequence4.3 Prefractionator Arrangement; 4.3.1 Introduction; 4.3.2 Case Study; 4.4 Thermally Coupled Distillation Sequence; 4.4.1 Introduction; 4.4.2 Retrofit to Thermally Coupled Distillation Sequence; 4.4.2.1 Design; 4.4.2.2 Optimization; 4.4.3 Case Study; 4.4.3.1 Existing Plant Subject to Retrofit Study; 4.4.3.2 Retrofitted Thermally Coupled Distillation Sequence; 4.4.3.3 Retrofitted Thermally Coupled Distillation Sequence with Side Reboiler; 4.5 Alternative Coupled Schemes of the Petlyuk Column; 4.5.1 Introduction; 4.6 Dividing Wall Column

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