Luyben大师的新作,2008年的新书,是和一个名叫Cheng-Ching Yu的国立台湾大学的台巴子合作的,内容丰富,详见目录,一共6部分,18章,574页
压缩文件共7个,约27MB
Reactive distillation design and control/William L. Luyben, Cheng-Ching Yu.
p. cm.
Includes index.
ISBN 978-0-470-22612-4 (cloth)
List Price: $130.00
Hardcover: 574 pages
Publisher: Wiley-AIChE (October 24, 2008)
Language: English
ISBN-10: 0470226129
ISBN-13: 978-0470226124
Product Dimensions: 10 x 7.1 x 1.4 inches
table of content
PREFACE xvii
1 INTRODUCTION 1
1.1 History 2
1.2 Basics of Reactive Distillation 3
1.3 Neat Operation Versus Excess Reactant 7
1.4 Limitations 8
1.4.1 Temperature Mismatch 8
1.4.2 Unfavorable Volatilities 9
1.4.3 Slow Reaction Rates 9
1.4.4 Other Restrictions 9
1.5 Scope 9
1.6 Computational Methods 10
1.6.1 Matlab Programs for Steady-State Design 10
1.6.2 Aspen Simulations 10
1.7 Reference Materials 11
PART I STEADY-STATE DESIGN OF IDEAL QUATERNARY SYSTEM 15
2 PARAMETER EFFECTS 17
2.1 Effect of Holdup on Reactive Trays 20
2.2 Effect of Number of Reactive Trays 22
2.3 Effect of Pressure 24
2.4 Effect of Chemical Equilibrium Constant 27
2.5 Effect of Relative Volatilities 29
2.5.1 Constant Relative Volatilities 30
2.5.2 Temperature-Dependent Relative Volatilities 30
2.6 Effect of Number of Stripping and Rectifying Trays 32
2.7 Effect of Reactant Feed Location 33
2.7.1 Reactant A Feed Location (NFA) 33
2.7.2 Reactant B Feed Location (NFB) 35
2.8 Conclusion 36
3 ECONOMIC COMPARISON OF REACTIVE DISTILLATION WITH A CONVENTIONAL PROCESS 37
3.1 Conventional Multiunit Process 38
3.1.1 Assumptions and Specifications 38
3.1.2 Steady-State Design Procedure 40
3.1.3 Sizing and Economic Equations 42
3.2 Reactive Distillation Design 43
3.2.1 Assumptions and Specifications 44
3.2.2 Steady-State Design Procedure 45
3.3 Results for Different Chemical Equilibrium Constants 47
3.3.1 Conventional Process 47
3.3.2 Reactive Distillation Process 54
3.3.3 Comparisons 61
3.4 Results for Temperature-Dependent Relative Volatilities 61
3.4.1 Relative Volatilities 62
3.4.2 Optimum Steady-State Designs 64
3.4.3 Real Chemical Systems 69
3.5 Conclusion 70
4 NEAT OPERATION VERSUS USING EXCESS REACTANT 71
4.1 Introduction 72
4.2 Neat Reactive Column 72
4.3 Two-Column System with Excess B 75
4.3.1 20% Excess B Case 76
4.3.2 10% Excess B Case 78
4.4 Two-Column System with 20% Excess of A 81
4.5 Economic Comparison 85
4.6 Conclusion 86
PART II STEADY-STATE DESIGN OF OTHER
IDEAL SYSTEMS 87
5 TERNARY REACTIVE DISTILLATION SYSTEMS 89
5.1 Ternary System Without Inerts 90
5.1.1 Column Configuration 90
5.1.2 Chemistry and Phase Equilibrium Parameters 90
5.1.3 Design Parameters and Procedure 92
5.1.4 Effect of Pressure 94
5.1.5 Holdup on Reactive Trays 94
5.1.6 Number of Reactive Trays 94
5.1.7 Number of Stripping Trays 94
5.2 Ternary System With Inerts 99
5.2.1 Column Configuration 99
5.2.2 Chemistry and Phase Equilibrium Parameters 99
5.2.3 Design Parameters and Procedure 100
5.2.4 Effect of Pressure 102
5.2.5 Control Tray Composition 103
5.2.6 Reactive Tray Holdup 105
5.2.7 Effect of Reflux 107
5.2.8 Chemical Equilibrium Constant 109
5.2.9 Feed Composition 109
5.2.10 Number of Reactive Trays 113
5.2.11 Number of Rectifying and Stripping Trays 113
5.3 Conclusion 116
6 TERNARY DECOMPOSITION REACTION 119
6.1 Ternary Decomposition Reaction: Intermediate-Boiling Reactant 120
6.1.1 Column Configuration 120
6.1.2 Chemistry and Phase Equilibrium Parameters 120
6.1.3 Design Parameters and Procedure 121
6.1.4 Holdup on Reactive Trays 123
6.1.5 Number of Reactive Trays 124
6.1.6 Number of Rectifying and Stripping Trays 126
6.1.7 Location of Feed Tray 126
6.2 Ternary Decomposition Reaction: Heavy Reactant with
Two-Column Configurations 127
6.2.1 Column Configurations 127
6.2.2 Chemistry and Phase Equilibrium Parameters 128
6.2.3 Design Parameters and Procedure 128
6.2.4 Reactive Holdup 129
6.2.5 Number of Reactive Trays 131
6.2.6 Number of Rectifying Trays 132
6.3 Ternary Decomposition Reaction: Heavy Reactant with
One-Column Configurations 134
6.3.1 Feasibility Analysis 134
6.3.2 Column Configuration 139
6.3.3 Design Parameters and Procedure 139
6.3.4 Reactive Tray Holdup 139
6.3.5 Number of Reactive Trays 139
6.3.6 Number of Rectifying Trays 140
6.3.7 Location of Feed Tray 143
6.3.8 Comparison Between These Two Flowsheets 143
6.4 Conclusion 143
PART III STEADY-STATE DESIGN OF REAL
CHEMICAL SYSTEMS 145
7 STEADY-STATE DESIGN FOR ACETIC ACID
ESTERIFICATION 147
7.1 Reaction Kinetics and Phase Equilibria 147
7.1.1 Reaction Kinetics 147
7.1.2 Phase Equilibria 149
7.2 Process Flowsheets 153
7.2.1 Type I Flowsheet: MeAc 153
7.2.2 Type II Flowsheet: EtAc and IPAc 156
7.2.3 Type III Flowsheet: BuAc and AmAc 157
7.3 Steady-State Design 158
7.3.1 Design Procedure 158
7.3.2 Optimized Design 160
7.4 Process Characteristics 168
7.4.1 Type I: MeAc 168
7.4.2 Type II: EtAc and IPAc 168
7.4.3 Type III: BuAc and AmAc 170
7.5 Discussion 175
7.6 Conclusion 177
8 DESIGN OF TAME REACTIVE DISTILLATION SYSTEMS 179
8.1 Chemical Kinetics and Phase Equilibrium 180
8.1.1 Chemical Kinetics 180
8.1.2 Phase Equilibrium Using Aspen Plus 181
8.1.3 Conceptual Design 186
8.2 Component Balances 194
8.3 Prereactor and Reactive Column 195
8.3.1 Base Case Design of Reactive Column 195
8.3.2 Effect of Design Parameters on Reactive Column 199
8.4 Pressure-Swing Methanol Separation Section 208
8.5 Extractive Distillation Methanol Separation Section 209
8.6 Economic Comparison 210
8.7 Conclusion 212
9 DESIGN OF MTBE AND ETBE REACTIVE
DISTILLATION COLUMNS 213
9.1 MTBE Process 213
9.1.1 Phase Equilibrium 214
9.1.2 Reaction Kinetics 214
9.1.3 Aspen Plus Simulation Issues 214
9.1.4 Setting up the Aspen Plus Simulation 215
9.1.5 Effect of Design Parameters 221
9.1.6 Chemical Equilibrium Model 229
9.2 ETBE Process 231
9.2.1 Kinetic Model 231
9.2.2 Process Studied 232
9.2.3 User Subroutine for ETBE 232
9.2.4 Chemical Equilibrium Model 234
9.2.5 Effects of Design Parameters 236
9.3 Conclusion 237
PART IV CONTROL OF IDEAL SYSTEMS 239
10 CONTROL OF QUATERNARY REACTIVE
DISTILLATION COLUMNS 241
10.1 Introduction 242
10.2 Steady-State Design 243
10.3 Control Structures 245
10.4 Selection of Control Tray Location 246
10.5 Closed-Loop Performance 247
10.5.1 CS7-R Structure 247
10.5.2 CS7-RR Structure 248
10.6 Using More Reactive Trays 249
10.6.1 Steady-State Design 249
10.6.2 SVD Analysis 250
10.6.3 Dynamic Performance of CS7-RR 253
10.7 Increasing Holdup on Reactive Trays 254
10.8 Rangeability 256
10.9 Conclusion 259
11 CONTROL OF EXCESS REACTANT SYSTEMS 261
11.1 Control Degrees of Freedom 261
11.2 Single Reactive Column Control Structures 263
11.2.1 Two-Temperature Control Structure 265
11.2.2 Internal Composition Control Structure 272
11.3 Control of Two-Column System 278
11.3.1 Two-Temperature Control 279
11.3.2 Temperature/Composition Cascade Control 285
11.4 Conclusion 292
12 CONTROL OF TERNARY REACTIVE
DISTILLATION COLUMNS 293
12.1 Ternary System Without Inerts 293
12.1.1 Column Configuration 293
12.1.2 Control Structure CS1 296
12.1.3 Control Structure CS2 300
12.1.4 Control Structure CS3 303
12.2 Ternary System With Inerts 310
12.2.1 Column Configuration 310
12.2.2 Control Structure CS1 310
12.2.3 Control Structure CS2 314
12.2.4 Control Structure CS3 320
12.2.5 Conclusion for Ternary A t B ,C System 322
12.3 Ternary A , B t C System: Intermediate-Boiling Reactant 324
12.3.1 Column Configuration 324
12.3.2 Control Structure CS1 326
12.3.3 Control Structure CS2 329
12.3.4 Control Structure CS3 334
12.4 Ternary A , B t C System: Heavy Reactant
With Two-Column Configuration 334
12.4.1 Column Configuration 334
12.4.2 Control Structure CS1 334
12.4.3 Control Structure CS2 335
12.5 Ternary A , B t C System: Heavy Reactant
With One-Column Configuration 342
12.5.1 Column Configuration 342
12.5.2 Control Structure CS1 342
12.5.3 Control Structure CS2 344
12.5.4 Control Structure CS3 345
12.5.5 Conclusion for Ternary A ,B t C System 352
帖子过长,截断,余下的见第二部分的目录
[ 本帖最后由 Arabicus 于 2009-7-6 17:27 编辑 ] |