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A real-time approach to distillation process control / Brent R. Young, University of Auckland New Zealand, Michael A. Taube, S&D Consulting, Inc, Isuru A. Udugama, The University of Waikato, New Zealand.

By: Young, Brent R [author.]

Contributor(s): Taube, Michael A [author.] | Udugama, Isuru A [author.]

Language: English Publisher: Hoboken, NJ, USA : Wiley, 2023Description: 1 online resourceContent type: text Media type: computer Carrier type: online resourceISBN: 9781119669210 ; 9781119669272; 1119669278; 9781119669241; 1119669243; 9781394185948; 1394185944Subject(s): Distillation | Chemical process controlGenre/Form: Electronic books.DDC classification: 663/.506 LOC classification: TP156.D5Online resources: Full text is available at Wiley Online Library Click here to view.

Contents:

Table of Contents Dedication D.1 Preface P.i References P.iii Chapter 1: Introduction 1.1 1.1 The purpose of process control 1.1 1.1 Introduction to distillation 1.6 1.2 Distillation process control 1.9 1.3 A real-time approach to distillation process control education 1.10 Chapter 2: Fundamentals of Distillation Control 2.1 2.1 Mass & Energy balance: The only means to affect distillation tower's behavior 2.3 2.2 Control design procedure 2.8 2.3 Degrees of freedom 2.9 2.4 Pairing 2.14 2.5 Gain analysis 2.20 2.6 Common control configuration 2.22 2.7 Screening Control Strategies via Steady-State Simulation 2.25 Chapter 3: Control Hardware 3.1 3.1 Introduction 3.1 3.2 Control Hardware Overview 3.2 3.3 Sensors 3.3 3.4 Final Control Elements 3.15 3.5 Controllers/CPU 3.17 3.6 Modern Trends 3.22 Chapter 4: Inventory Control 4.1 4.1 Pressure control 4.1 4.2 Level control 4.12 Chapter 5: Distillation Composition Control 5.1 5.1 Temperature control 5.1 5.2 Actual composition control 5.10 5.3 More complex control configurations 5.13 5.4 Distillation control scheme design using steady state models 5.15 5.5 Performance Analysis using Steady-State Data for an Existing Distillation Tower 5.17 5.6 Distillation control scheme design using dynamic models 5.23 Chapter 6: Refinery Versus Chemical Plant Distillation Operations 6.1 6.1 New Generation of Refinery Controls 6.6 6.2 Improving thermodynamic efficiency through control 6.11 6.3 Blending and its implications on control 6.12 Chapter 7: Distillation Controller Tuning 7.1 7.1 Model identification: Step Testing 7.2 7.2 Typical process responses 7.5 7.3 Engineering Units versus Percent of Scale 7.6 7.4 Basics in PID Tuning 7.9 7.5 Tuning in distillation control 7.10 7.6 The role of tuning in a "value engineering" era 7.12 Chapter 8: Fine and Specialty Chemicals Distillation Control 8.1 8.1 Key Features 8.1 8.2 Measurement and Control Challenges 8.2 8.3 Nuances of Fine Chemicals Distillation 8.6 8.4 Side Draw Distillation 8.12 8.5 Composition Control in High Purity Side Draw Distillation 8.14 8.6 Advanced Distillation Column Configurations 8.17 8.7 Petlyuk and Divided Wall Columns 8.18 8.8 Optimal Design versus Optimal Operations 8.21 Chapter 9: Advanced Regulatory control 9.1 9.1 Introduction 9.1 9.2 Cascade Control 9.2 9.3 Ratio Control 9.8 9.4 Feedforward Control 9.12 9.4 Constraint/Override Control 9.15 9.5 Decoupling 9.17 Chapter 10: Model predictive control 10.1 10.1 Introduction to MPC 10.1 10.2 To MPC or not to MPC 10.2 10.3 MPC Fundamentals 10.3 10.4 Dynamic Matrix Control (DMC) 10.7 10.5 Setting up a MPC in Distillation 10.14 10.6 Digitalization and MPC10.20 Chapter 11: Plant wide control in distillation 11.1 11.1 Distillation column trains 11.2 11.2 Heat integration (energy recycle) 11.5 11. 3 Materials Recycling 11.17 Tutorial and Self-Study Questions 11.20 References 11.22 Workshop 1 -- Hands on Learning by Doing W1.1 Course philosophy W1.1 Key Learning Objectives W1.1 Book Coverage W1.1 Prerequisites W1.2 Study Material W1.2 Organization W1.3 Simulation Tool W1.3 Overall Learning Objectives W1.4 Tasks W1.5 1 -- Get familiar with the simulator W1.5 2 -- Steady state tutorial W1.5 3 --Transitioning from steady state to dynamics tutorial W1.6 Tutorial and Self-Study Questions W1.6 Workshop 2 -- Fundamental Distillation Column Control W2.1 Introduction W2.1 Key Learning Objectives W2.1 Tasks W2.1 1 -- Steady State W2.1 2 -- Converting to Dynamics W2.4 3 -- Dynamics Exercises W2.9 Workshop 3 -- Distillation Column Model Predictive Control W3.1 Introduction W3.1 Key Learning Objectives W3.1 Description W3.2 Tasks W3.3 Workshop 4 -- Distillation Column Control in a Plantwide Setting W4.1 Introduction W4.1 Key Learning Objectives W4.1 Description W4.1 Tasks W4.3 References W4.7 Appendix A -- P&ID Symbols A.1 Index I.1

Summary: "The book is a practical text incorporating hands-on or active learning using process simulation. The topics and their treatment are relevant to today's engineer providing them with the fundamental knowledge and tools to apply to modern distillation control. Unlike other texts that take a Laplace Transform or state-space-based approach this text presents a more balanced real-time approach with a good mix of fundamentals and practical insights. The text includes numerous exercises including up to date process simulation exercises. Finally, the process simulation exercises are designed to be simulator agnostic so that they can be performed on the process simulator locally available. Topics include An Introduction to the Real-Time Approach to Distillation Control, Distillation Control Hardware, Basic Distillation Control, Distillation Composition Control, Refinery Versus Chemical Plant Distillation Control, Distillation Control Tuning, Fine Chemical Distillation Control, Advanced Regulatory Control (ARC), Model Predictive Control (MPC), and Plant-Wide Control and Distillation"-- Provided by publisher.

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Item type	Current location	Home library	Call number	Status	Date due	Barcode	Item holds
EBOOK	COLLEGE LIBRARY	COLLEGE LIBRARY	663.506 Y841 2023 (Browse shelf)	Available

Total holds: 0

Includes bibliographical references and index.

Table of Contents

Dedication D.1

Preface P.i

References P.iii

Chapter 1: Introduction 1.1

1.1 The purpose of process control 1.1

1.1 Introduction to distillation 1.6

1.2 Distillation process control 1.9

1.3 A real-time approach to distillation process control education 1.10

Chapter 2: Fundamentals of Distillation Control 2.1

2.1 Mass & Energy balance: The only means to affect distillation tower's behavior 2.3

2.2 Control design procedure 2.8

2.3 Degrees of freedom 2.9

2.4 Pairing 2.14

2.5 Gain analysis 2.20

2.6 Common control configuration 2.22

2.7 Screening Control Strategies via Steady-State Simulation 2.25

Chapter 3: Control Hardware 3.1

3.1 Introduction 3.1

3.2 Control Hardware Overview 3.2

3.3 Sensors 3.3

3.4 Final Control Elements 3.15

3.5 Controllers/CPU 3.17

3.6 Modern Trends 3.22

Chapter 4: Inventory Control 4.1

4.1 Pressure control 4.1

4.2 Level control 4.12

Chapter 5: Distillation Composition Control 5.1

5.1 Temperature control 5.1

5.2 Actual composition control 5.10

5.3 More complex control configurations 5.13

5.4 Distillation control scheme design using steady state models 5.15

5.5 Performance Analysis using Steady-State Data for an Existing Distillation Tower 5.17

5.6 Distillation control scheme design using dynamic models 5.23

Chapter 6: Refinery Versus Chemical Plant Distillation Operations 6.1

6.1 New Generation of Refinery Controls 6.6

6.2 Improving thermodynamic efficiency through control 6.11

6.3 Blending and its implications on control 6.12

Chapter 7: Distillation Controller Tuning 7.1

7.1 Model identification: Step Testing 7.2

7.2 Typical process responses 7.5

7.3 Engineering Units versus Percent of Scale 7.6

7.4 Basics in PID Tuning 7.9

7.5 Tuning in distillation control 7.10

7.6 The role of tuning in a "value engineering" era 7.12

Chapter 8: Fine and Specialty Chemicals Distillation Control 8.1

8.1 Key Features 8.1

8.2 Measurement and Control Challenges 8.2

8.3 Nuances of Fine Chemicals Distillation 8.6

8.4 Side Draw Distillation 8.12

8.5 Composition Control in High Purity Side Draw Distillation 8.14

8.6 Advanced Distillation Column Configurations 8.17

8.7 Petlyuk and Divided Wall Columns 8.18

8.8 Optimal Design versus Optimal Operations 8.21

Chapter 9: Advanced Regulatory control 9.1

9.1 Introduction 9.1

9.2 Cascade Control 9.2

9.3 Ratio Control 9.8

9.4 Feedforward Control 9.12

9.4 Constraint/Override Control 9.15

9.5 Decoupling 9.17

Chapter 10: Model predictive control 10.1

10.1 Introduction to MPC 10.1

10.2 To MPC or not to MPC 10.2

10.3 MPC Fundamentals 10.3

10.4 Dynamic Matrix Control (DMC) 10.7

10.5 Setting up a MPC in Distillation 10.14

10.6 Digitalization and MPC10.20

Chapter 11: Plant wide control in distillation 11.1

11.1 Distillation column trains 11.2

11.2 Heat integration (energy recycle) 11.5

11. 3 Materials Recycling 11.17

Tutorial and Self-Study Questions 11.20

References 11.22

Workshop 1 -- Hands on Learning by Doing W1.1

Course philosophy W1.1

Key Learning Objectives W1.1

Book Coverage W1.1

Prerequisites W1.2

Study Material W1.2

Organization W1.3

Simulation Tool W1.3

Overall Learning Objectives W1.4

Tasks W1.5

1 -- Get familiar with the simulator W1.5

2 -- Steady state tutorial W1.5

3 --Transitioning from steady state to dynamics tutorial W1.6

Tutorial and Self-Study Questions W1.6

Workshop 2 -- Fundamental Distillation Column Control W2.1

Introduction W2.1

Key Learning Objectives W2.1

Tasks W2.1

1 -- Steady State W2.1

2 -- Converting to Dynamics W2.4

3 -- Dynamics Exercises W2.9

Workshop 3 -- Distillation Column Model Predictive Control W3.1

Introduction W3.1

Key Learning Objectives W3.1

Description W3.2

Tasks W3.3

Workshop 4 -- Distillation Column Control in a Plantwide Setting W4.1

Introduction W4.1

Key Learning Objectives W4.1

Description W4.1

Tasks W4.3

References W4.7

Appendix A -- P&ID Symbols A.1

Index I.1

"The book is a practical text incorporating hands-on or active learning using process simulation. The topics and their treatment are relevant to today's engineer providing them with the fundamental knowledge and tools to apply to modern distillation control. Unlike other texts that take a Laplace Transform or state-space-based approach this text presents a more balanced real-time approach with a good mix of fundamentals and practical insights. The text includes numerous exercises including up to date process simulation exercises. Finally, the process simulation exercises are designed to be simulator agnostic so that they can be performed on the process simulator locally available. Topics include An Introduction to the Real-Time Approach to Distillation Control, Distillation Control Hardware, Basic Distillation Control, Distillation Composition Control, Refinery Versus Chemical Plant Distillation Control, Distillation Control Tuning, Fine Chemical Distillation Control, Advanced Regulatory Control (ARC), Model Predictive Control (MPC), and Plant-Wide Control and Distillation"-- Provided by publisher.

About the Author

Brent R. Young, PhD, is Full Professor of Food and Process Systems Engineering at The University of Auckland. He has over 30 years’ postgraduate experience in academia and consulting in Australia, Canada, and New Zealand.

Michael A. Taube is Principal Consultant with S&D Consulting, Inc. He has over 30 years’ industrial experience working with clients including Alcoa, Aramco, BASF, CBI, ExxonMobil, and others.

Isuru A. Udugama, PhD, is Senior Lecturer at the University of Waikato. He is also a process control consultant with S&D Consulting in New Zealand and the United States.

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