【Advanced distillation technologies : design, control and applications】
马后炮化工组织翻译新书校审工作进行。本书翻译作者:梁建成【Advanced distillation technologies : design, control and applications】
百度学术介绍地址:https://xueshu.baidu.com/usercenter/paper/show?paperid=5baccc3d8c24a8b619ad72badb550a8a&site=xueshu_se
作者:Anton Alexandru Kiss
摘要:Distillation has historically been the main method for separating mixtures in the chemical process industry. However, despite the flexibility and widespread use of distillation processes, they still remain extremely energy inefficient. Increased optimization and novel distillation concepts can deliver substantial benefits, not just in terms of significantly lower energy use, but also in reducing capital investment and improving eco-efficiency. While likely to remain the separation technology of choice for the next few decades, there is no doubt that distillation technologies need to make radical changes in order to meet the demands of the energy-conscious society.Advanced Distillation Technologies: Design, Control and Applications gives a deep and broad insight into integrated separations using non-conventional arrangements, including both current and upcoming process intensification technologies. It includes:Containing abundant examples and industrial case studies, this is a unique resource that tackles the most advanced distillation technologies - all the way from the conceptual design to practical implementation.The author of Advanced Distillation Technologies ,
英文目录如下:
Contents
Preface xiii
Acknowledgements xv
[*]1Basic Concepts in Distillation 1
[*]1.1Introduction 1
[*]1.2Physical Property Methods 2
[*]1.3Vapor Pressure 6
[*]1.4Vapor–Liquid Equilibrium and VLE Non-ideality 8
[*]1.4.1Vapor–Liquid Equilibrium 8
[*]1.4.2VLE Non-ideality 11
[*]1.5Relative Volatility 13
[*]1.6Bubble Point Calculations 14
[*]1.7Ternary Diagrams and Residue Curve Maps 16
[*]1.7.1Ternary Diagrams 16
[*]1.7.2Residue Curve Maps 18
[*]1.8Analysis of Distillation Columns 24
[*]1.8.1Degrees of Freedom Analysis 26
[*]1.8.2McCabe–Thiele Method 27
[*]1.8.3Approximate Multicomponent Methods 33
[*]1.9Concluding Remarks 34 References 35
[*]2Design, Control and Economics of Distillation 37
[*]2.1Introduction 37
[*]2.2Design Principles 38
[*]2.2.1Operating Pressure 39
[*]2.2.2Heuristic Optimization 40
viii
CONTENTS
3
[*]2.2.3Rigorous Optimization 41
[*]2.2.4Feed Preheating 42
[*]2.2.5Intermediate Reboilers and Condensers 42
[*]2.2.6Heat Integration 43
[*]2.3Basics of Distillation Control 44
[*]2.3.1Single-End Control 46
[*]2.3.2Dual-End Control 49
[*]2.3.3Alternative Control Structures 52
[*]2.3.4Constraint Control 53
[*]2.3.5Multivariable Control 54
[*]2.4Economic Evaluation 55
[*]2.4.1Equipment Sizing 56
[*]2.4.2Equipment Cost 59
[*]2.4.3Utilities and Energy Cost 62
[*]2.4.4Cost of Chemicals 63
[*]2.5Concluding Remarks 63 References 64
Dividing-Wall Column 67
[*]3.1Introduction 67
[*]3.2DWC Configurations 70
[*]3.3Design of DWCs 75
[*]3.3.1Heuristic Rules for DWC Design 77
[*]3.3.2Approximate Design Methods 78
[*]3.3.3Vmin Diagram Method 79
[*]3.3.4Optimal Design of a DWC 82
[*]3.4Modeling of a DWC 83
[*]3.4.1Pump-Around Model 84
[*]3.4.2Two Columns Sequence Model 84
[*]3.4.3Four Columns Sequence Model 85
[*]3.4.4Simultaneous Models 86
[*]3.4.5Simulation of a Four-Product DWC 86
[*]3.4.6Optimization Methods 86
[*]3.5DWC Equipment 87 3.5.1 Liquid/Reflux Splitter 89 3.5.2 Column Internals 91 3.5.3 Equipment Sizing 91 3.5.4 Constructional Aspects 94
[*]3.6Case Study: Separation of Aromatics 97
[*]3.7Concluding Remarks 103 References 107
CONTENTS ix
[*]4Optimal Operation and Control of DWC 111
[*]4.1Introduction 111
[*]4.2Degrees of Freedom Analysis 112
[*]4.3Optimal Operation and Vmin Diagram 114
[*]4.4Overview of DWC Control Structures 117
[*]4.4.1Three-Point Control Structure 118
[*]4.4.2Three-Point Control Structure with
Alternative Pairing 120
[*]4.4.3Four-Point Control Structure 121
[*]4.4.4Three-Point Control Structure with
Nested Loops 121
[*]4.4.5Performance Control of Prefractionator
Sub-system using the Liquid Split 122
[*]4.4.6Control Structures Based on Inferential
Temperature Measurements 123
[*]4.4.7Feedforward Control to Reject Frequent
Measurable Disturbances 126
[*]4.4.8Advanced Control Techniques 127
[*]4.5Control Guidelines and Rules 128
[*]4.6Case Study: Pentane–Hexane–Heptane Separation 129
[*]4.7Case Study: Energy Efficient Control of a BTX DWC 132
[*]4.7.1Energy Efficient Control Strategies 135
[*]4.7.2Dynamic Simulations 139
[*]4.8Concluding Remarks 148 References 149
[*]5Advanced Control Strategies for DWC 153
[*]5.1Introduction 153
[*]5.2Overview of Previous Work 154
[*]5.3Dynamic Model of a DWC 156
[*]5.4Conventional versus Advanced Control Strategies 163
[*]5.4.1PID Loops within a Multi-loop Framework 163
[*]5.4.2Linear Quadratic Gaussian Control 165
[*]5.4.3Generic Model Control 167
[*]5.4.4Multivariable Controller Synthesis 167
[*]5.5Energy Efficient Control Strategies 171
[*]5.5.1Background of Model Predictive Control 173
[*]5.5.2Controller Tuning Parameters 175
[*]5.5.3Dynamic Simulations 176
[*]5.6Concluding Remarks 180
x
CONTENTS
6
Notation 181 References 183
Applications of Dividing-Wall Columns 187
[*]6.1Introduction 187
[*]6.2Separation of Ternary and Multicomponent Mixtures 188
[*]6.3Reactive Dividing-Wall Column 195
[*]6.4Azeotropic Dividing-Wall Column 198
[*]6.5Extractive Dividing-Wall Column 199
[*]6.6Revamping of Conventional Columns to DWC 203
[*]6.7Case Study: Dimethyl Ether Synthesis by R-DWC 205
[*]6.8Case Study: Bioethanol Dehydration by A-DWC and
E-DWC 212
[*]6.9Concluding Remarks 223 References 223
Heat Pump Assisted Distillation 229
[*]7.1Introduction 229
[*]7.2Working Principle 231
[*]7.3Vapor (Re)compression 232
[*]7.3.1Vapor Compression 233
[*]7.3.2Mechanical Vapor Recompression 233
[*]7.3.3Thermal Vapor Recompression 234
[*]7.4Absorption–Resorption Heat Pumps 234
[*]7.4.1Absorption Heat Pump 234
[*]7.4.2Compression–Resorption Heat Pump 235
[*]7.5Thermo-acoustic Heat Pump 236
[*]7.6Other Heat Pumps 240
[*]7.6.1Stirling Cycle 240
[*]7.6.2Vuilleumier Cycle 241
[*]7.6.3Brayton Cycle 241
[*]7.6.4Malone Cycle 242
[*]7.6.5Solid–Sorption Cycle 242
[*]7.7Heat-Integrated Distillation Column 244
[*]7.8Technology Selection Scheme 245
[*]7.8.1Energy Efficient Distillation
Technologies 246
[*]7.8.2Multicomponent Separations 249
[*]7.8.3Binary Distillation 254
[*]7.8.4Selected Scheme Applications 263
7
CONTENTS xi 7.9 Concluding Remarks 265
References 265
[*]8Heat-Integrated Distillation Column 271
[*]8.1Introduction 271
[*]8.2Working Principle 273
[*]8.3Thermodynamic Analysis 277
[*]8.4Potential Energy Savings 280
[*]8.4.1Partial Heat Integrated Distillation Column (p-HIDiC) 280
[*]8.4.2Ideal Heat Integrated Distillation Column
(i-HIDiC) 281
[*]8.5Design and Construction Options 282
[*]8.5.1Inter-coupled Distillation Columns 284
[*]8.5.2Distillation Column with Partition Wall 285
[*]8.5.3Concentric Distillation Column 287
[*]8.5.4Concentric Column with Heat Panels 288
[*]8.5.5Shell & Tube Heat-Exchanger Column 289
[*]8.5.6Plate-Fin Heat-Exchanger Column 290
[*]8.5.7Heat Transfer Means 292
[*]8.6Modeling and Simulation 295
[*]8.7Process Dynamics, Control, and Operation 297
[*]8.8Applications of HIDiC 300
[*]8.9Concluding Remarks 304 References 305
[*]9Cyclic Distillation 311
[*]9.1Introduction 311
[*]9.2Overview of Cyclic Distillation Processes 313
[*]9.3Process Description 316
[*]9.4Mathematical and Hydrodynamic Model 319
[*]9.4.1Mathematical Model 319
[*]9.4.2Hydrodynamic Model 321
[*]9.4.3Sensitivity Analysis 323
[*]9.5Modeling and Design of Cyclic Distillation 327
[*]9.5.1Modeling Approach 329
[*]9.5.2Comparison with Classic Distillation 331
[*]9.5.3Design Methodology 331
[*]9.5.4Demonstration of the Design Procedure 333
[*]9.6Control of Cyclic Distillation 335
xii
CONTENTS
10
Reactive Distillation 353
[*]10.1Introduction 353
[*]10.2Principles of Reactive Distillation 354
[*]10.3Design, Control and Applications 357
[*]10.4Modeling Reactive Distillation 362
[*]10.5Feasibility and Technical Evaluation 364
[*]10.5.1Feasibility Evaluation 364
[*]10.5.2Technical Evaluation 367
[*]10.6Case Study: Advanced Control of a Reactive
Distillation Column 371
[*]10.6.1Mathematical Model 371
[*]10.6.2Open-Loop Dynamic Analysis 374
[*]10.6.3Closed-Loop Performance 374
[*]10.7Case Study: Biodiesel Production by
Heat-Integrated RD 378
[*]10.8Case Study: Fatty Esters Synthesis by Dual RD 383
[*]10.9Concluding Remarks 387 References 388
Index 393
点个赞 期待新書翻譯出來~ {:534:}不知道什么时候能出版 期待新书的出现,谢谢啊! {:528:}
先谢楼主分享 期待新書翻譯出來 翻译的书都很好! 看一看,学习 谢谢分享,dddddddd 坐等新書上市! 本帖最后由 surge 于 2021-4-11 20:28 编辑
这书中文出版了吗? 期待完成!购买学习! 坐等。。。。。。。。。。。。。。。 你好,尊敬的楼主,不知道是否可以分享英文版的原文件啊?感激不尽 好书,期待着! 看内容还是很不错的。 2013年出版的,讲DWC、热泵、热集成、循环、反应精馏。 好期待,翻译出来后买一本 怎么还不出版啊