05617nam 2200697 450 991014160790332120200520144314.01-5231-1062-71-118-51019-41-118-51013-51-118-51009-7(CKB)2670000000355901(EBL)1175202(OCoLC)841908822(SSID)ssj0000873421(PQKBManifestationID)11957768(PQKBTitleCode)TC0000873421(PQKBWorkID)10878010(PQKB)10090340(MiAaPQ)EBC1175202(Au-PeEL)EBL1175202(CaPaEBR)ebr11099342(PPN)223548367(EXLCZ)99267000000035590120160415h20132013 uy 0engurcnu||||||||txtccrDistillation design and control using Aspen simulation /William L. LuybenSecond edition.Hoboken, New Jersey :AlChE :Wiley,2013.©20131 online resource (742 p.)Description based upon print version of record.1-118-41143-9 Includes bibliographical references and index.Cover; Title Page; Copyright; Dedication; Preface to the Second Edition; Preface to the First Edition; Chapter 1: Fundamentals of Vapor-Liquid-Equilibrium (VLE); 1.1 Vapor Pressure; 1.2 Binary VLE Phase Diagrams; 1.3 Physical Property Methods; 1.4 Relative Volatility; 1.5 Bubble Point Calculations; 1.6 Ternary Diagrams; 1.7 VLE Nonideality; 1.8 Residue Curves for Ternary Systems; 1.9 Distillation Boundaries; 1.10 Conclusions; Reference; Chapter 2: Analysis of Distillation Columns; 2.1 Design Degrees of Freedom; 2.2 Binary Mccabe-Thiele Method; 2.3 Approximate Multicomponent Methods2.4 Conclusions Chapter 3: Setting Up a Steady-State Simulation; 3.1 Configuring a New Simulation; 3.2 Specifying Chemical Components and Physical Properties; 3.3 Specifying Stream Properties; 3.4 Specifying Parameters of Equipment; 3.5 Running the Simulation; 3.6 Using Design Spec/Vary Function; 3.7 Finding the Optimum Feed Tray and Minimum Conditions; 3.8 Column Sizing; 3.9 Conceptual Design; 3.10 Conclusions; Chapter 4: Distillation Economic Optimization; 4.1 Heuristic Optimization; 4.2 Economic Basis; 4.3 Results; 4.4 Operating Optimization; 4.5 Optimum Pressure for Vacuum Columns4.6 Conclusions Chapter 5: More Complex Distillation Systems; 5.1 Extractive Distillation; 5.2 Ethanol Dehydration; 5.3 Pressure-Swing Azeotropic Distillation; 5.4 Heat-Integrated Columns; 5.5 Conclusions; Chapter 6: Steady-State Calculations for Control Structure Selection; 6.1 Control Structure Alternatives; 6.2 Feed Composition Sensitivity Analysis (ZSA); 6.3 Temperature Control Tray Selection; 6.4 Conclusions; Reference; Chapter 7: Converting From Steady-State to Dynamic Simulation; 7.1 Equipment Sizing; 7.2 Exporting to Aspen Dynamics; 7.3 Opening the Dynamic Simulation in Aspen Dynamics7.4 Installing Basic Controllers 7.5 Installing Temperature and Composition Controllers; 7.6 Performance Evaluation; 7.7 Conclusions; Chapter 8: Control of More Complex Columns; 8.1 Extractive Distillation Process; 8.2 Columns with Partial Condensers; 8.3 Control of Heat-Integrated Distillation Columns; 8.4 Control of Azeotropic Columns/Decanter System; 8.5 Unusual Control Structure; 8.6 Conclusions; References; Chapter 9: Reactive Distillation; 9.1 Introduction; 9.2 Types of Reactive Distillation Systems; 9.3 Tame Process Basics; 9.4 Tame Reaction Kinetics and Vle9.5 Plantwide Control Structure 9.6 Conclusions; References; Chapter 10: Control of Sidestream Columns; 10.1 Liquid Sidestream Column; 10.2 Vapor Sidestream Column; 10.3 Liquid Sidestream Column with Stripper; 10.4 Vapor Sidestream Column with Rectifier; 10.5 Sidestream Purge Column; 10.6 Conclusions; Chapter 11: Control of Petroleum Fractionators; 11.1 Petroleum Fractions; 11.2 Characterization Crude Oil; 11.3 Steady-State Design of Preflash Column; 11.4 Control of Preflash Column; 11.5 Steady-State Design of Pipestill; 11.6 Control of Pipestill; 11.7 Conclusions; ReferencesChapter 12: Divided-Wall (Petlyuk) ColumnsThe new edition of this book greatly updates and expands the previous edition. It boasts new chapters on the divided wall column and carbon dioxide capture from stack gas, revises the design and control of distillation systems, and explains the use of dynamic simulation to study safety issues in the event of operating failures. Using Aspen Plus to develop rigorous simulations of single distillation columns and sequences of columns, the book considers the economics of capital investment and energy costs to create an optimal system for separation methods in the chemical and petroleum industries.Distillation apparatusDesign and constructionChemical process controlSimulation methodsPetroleumRefiningDistillation apparatusDesign and construction.Chemical process controlSimulation methods.PetroleumRefining.660/.28425Luyben William L.16520American Institute of Chemical Engineers.MiAaPQMiAaPQMiAaPQBOOK9910141607903321Distillation Design and Control Using Aspen SImulation716264UNINA