Distillation design and control using Aspen simulation /

Mostrar otras versiones (2)

The 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...

Descripción completa

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Luyben, William L.
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Hoboken, N.J. : Wiley, ©2013.
©2013
Edición:2nd ed.
Temas:
Distillation apparatus > Design and construction.
Chemical process control > Simulation methods.
Petroleum > Refining.
Procédés chimiques > Contrôle > Méthodes de simulation.
Pétrole > Raffinage.
SCIENCE > Chemistry > Industrial & Technical.
TECHNOLOGY & ENGINEERING > Chemical & Biochemical.
Distillation apparatus > Design and construction
Petroleum > Refining
Acceso en línea:Texto completo

MARC

LEADER 00000cam a2200000Ia 4500
001 KNOVEL_ocn841908822
003 OCoLC
005 20231027140348.0
006 m o d
007 cr |n|||||||||
008 130505s2013 njua ob 001 0 eng d
010 |a  2012030047 
040 |a YDXCP  |b eng  |e pn  |c YDXCP  |d OCLCO  |d TXA  |d CUS  |d DG1  |d OCLCQ  |d RRP  |d DEBSZ  |d N$T  |d OCLCQ  |d SFB  |d DG1  |d LIP  |d COCUF  |d ZCU  |d MERUC  |d KNOVL  |d OCLCQ  |d OCLCF  |d CEF  |d ICG  |d VTS  |d OCLCQ  |d INT  |d VT2  |d AU@  |d OCLCQ  |d U3W  |d OCLCQ  |d DKC  |d OCLCQ  |d UKAHL  |d OCLCO  |d OCLCQ  |d OCLCO 
019 |a 959801008  |a 1055360857  |a 1081201121  |a 1228578648 
020 |a 9781118510193  |q (electronic bk.) 
020 |a 1118510097  |q (electronic bk.) 
020 |a 9781118510094  |q (electronic bk.) 
020 |a 1118510194  |q (electronic bk.) 
020 |a 9781523110629  |q (electronic bk.) 
020 |a 1523110627  |q (electronic bk.) 
020 |z 9781118411438  |q (cloth) 
020 |z 1118411439  |q (cloth) 
029 1 |a AU@  |b 000052185328 
029 1 |a AU@  |b 000058064067 
029 1 |a AU@  |b 000060074701 
029 1 |a CHBIS  |b 010131677 
029 1 |a CHNEW  |b 000941755 
029 1 |a CHVBK  |b 480220328 
029 1 |a DEBBG  |b BV044062616 
029 1 |a DEBSZ  |b 431397295 
029 1 |a DEBSZ  |b 485036703 
029 1 |a NZ1  |b 15341612 
029 1 |a DKDLA  |b 820120-katalog:999934707905765 
035 |a (OCoLC)841908822  |z (OCoLC)959801008  |z (OCoLC)1055360857  |z (OCoLC)1081201121  |z (OCoLC)1228578648 
050 4 |a TP159.D5 
072 7 |a SCI  |x 013060  |2 bisacsh 
072 7 |a TEC  |x 009010  |2 bisacsh 
082 0 4 |a 660/.28425  |2 23 
049 |a UAMI 
100 1 |a Luyben, William L. 
245 1 0 |a Distillation design and control using Aspen simulation /  |c William L Luyben. 
250 |a 2nd ed. 
260 |a Hoboken, N.J. :  |b Wiley,  |c ©2013. 
264 4 |c ©2013 
300 |a 1 online resource (xix, 498 pages) :  |b illustrations 
336 |a text  |b txt  |2 rdacontent 
337 |a computer  |b c  |2 rdamedia 
338 |a online resource  |b cr  |2 rdacarrier 
500 |a "AIChE." 
504 |a Includes bibliographical references and index. 
588 0 |a Online resource; title from PDF title page (Wiley, viewed September 24, 2013). 
505 0 |a 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 -- 2. Analysis of Distillation Columns -- 2.1. Design Degrees of Freedom -- 2.2. Binary McCabe -- Thiele Method -- 2.2.1. Operating Lines -- 2.2.2.q-Line -- 2.2.3. Stepping Off Trays -- 2.2.4. Effect of Parameters -- 2.2.5. Limiting Conditions -- 2.3. Approximate Multicomponent Methods -- 2.3.1. Fenske Equation for Minimum Number of Trays -- 2.3.2. Underwood Equations for Minimum Reflux Ratio -- 2.4. Conclusions -- 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. 
505 8 |a 3.4. Specifying Parameters of Equipment -- 3.4.1. Column C1 -- 3.4.2. Valves and Pumps -- 3.5. Running the Simulation -- 3.6. Using Design Spec/Vary Function -- 3.7. Finding the Optimum Feed Tray and Minimum Conditions -- 3.7.1. Optimum Feed Tray -- 3.7.2. Minimum Reflux Ratio -- 3.7.3. Minimum Number of Trays -- 3.8. Column Sizing -- 3.8.1. Length -- 3.8.2. Diameter -- 3.9. Conceptual Design -- 3.10. Conclusions -- 4. Distillation Economic Optimization -- 4.1. Heuristic Optimization -- 4.1.1. Set Total Trays to Twice Minimum Number of Trays -- 4.1.2. Set Reflux Ratio to 1.2 Times Minimum Reflux Ratio -- 4.2. Economic Basis -- 4.3. Results -- 4.4. Operating Optimization -- 4.5. Optimum Pressure for Vacuum Columns -- 4.6. Conclusions -- 5. More Complex Distillation Systems -- 5.1. Extractive Distillation -- 5.1.1. Design -- 5.1.2. Simulation Issues -- 5.2. Ethanol Dehydration -- 5.2.1. VLLE Behavior -- 5.2.2. Process Flowsheet Simulation -- 5.2.3. Converging the Flowsheet. 
505 8 |a 5.3. Pressure-Swing Azeotropic Distillation -- 5.4. Heat-Integrated Columns -- 5.4.1. Flowsheet -- 5.4.2. Converging for Neat Operation -- 5.5. Conclusions -- 6. Steady-State Calculations for Control Structure Selection -- 6.1. Control Structure Alternatives -- 6.1.1. Dual-Composition Control -- 6.1.2. Single-End Control -- 6.2. Feed Composition Sensitivity Analysis (ZSA) -- 6.3. Temperature Control Tray Selection -- 6.3.1. Summary of Methods -- 6.3.2. Binary Propane/Isobutane System -- 6.3.3. Ternary BTX System -- 6.3.4. Ternary Azeotropic System -- 6.4. Conclusions -- Reference -- 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 Dynamics -- 7.4. Installing Basic Controllers -- 7.4.1. Reflux -- 7.4.2. Issues -- 7.5. Installing Temperature and Composition Controllers -- 7.5.1. Tray Temperature Control -- 7.5.2.Composition Control. 
505 8 |a 7.5.3.Composition/Temperature Cascade Control -- 7.6. Performance Evaluation -- 7.6.1. Installing a Plot -- 7.6.2. Importing Dynamic Results into Matlab -- 7.6.3. Reboiler Heat Input to Feed Ratio -- 7.6.4.Comparison of Temperature Control with Cascade CC/TC -- 7.7. Conclusions -- 8. Control of More Complex Columns -- 8.1. Extractive Distillation Process -- 8.1.1. Design -- 8.1.2. Control Structure -- 8.1.3. Dynamic Performance -- 8.2. Columns with Partial Condensers -- 8.2.1. Total Vapor Distillate -- 8.2.2. Both Vapor and Liquid Distillate Streams -- 8.3. Control of Heat-Integrated Distillation Columns -- 8.3.1. Process Studied -- 8.3.2. Heat Integration Relationships -- 8.3.3. Control Structure -- 8.3.4. Dynamic Performance -- 8.4. Control of Azeotropic Columns/Decanter System -- 8.4.1. Converting to Dynamics and Closing Recycle Loop -- 8.4.2. Installing the Control Structure -- 8.4.3. Performance -- 8.4.4. Numerical Integration Issues -- 8.5. Unusual Control Structure. 
505 8 |a 8.5.1. Process Studied -- 8.5.2. Economic Optimum Steady-State Design -- 8.5.3. Control Structure Selection -- 8.5.4. Dynamic Simulation Results -- 8.5.5. Alternative Control Structures -- 8.5.6. Conclusions -- 8.6. Conclusions -- References -- 9. Reactive Distillation -- 9.1. Introduction -- 9.2. Types of Reactive Distillation Systems -- 9.2.1. Single-Feed Reactions -- 9.2.2. Irreversible Reaction with Heavy Product -- 9.2.3. Neat Operation Versus Use of Excess Reactant -- 9.3. TAME Process Basics -- 9.3.1. Prereactor -- 9.3.2. Reactive Column C1 -- 9.4. TAME Reaction Kinetics and VLE -- 9.5. Plantwide Control Structure -- 9.6. Conclusions -- References -- 10. Control of Sidestream Columns -- 10.1. Liquid Sidestream Column -- 10.1.1. Steady-State Design -- 10.1.2. Dynamic Control -- 10.2. Vapor Sidestream Column -- 10.2.1. Steady-State Design -- 10.2.2. Dynamic Control -- 10.3. Liquid Sidestream Column with Stripper -- 10.3.1. Steady-State Design -- 10.3.2. Dynamic Control. 
505 8 |a 10.4. Vapor Sidestream Column with Rectifier -- 10.4.1. Steady-State Design -- 10.4.2. Dynamic Control -- 10.5. Sidestream Purge Column -- 10.5.1. Steady-State Design -- 10.5.2. Dynamic Control -- 10.6. Conclusions -- 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 -- 11.5.1. Overview of Steady-State Design -- 11.5.2. Configuring the Pipestill in Aspen Plus -- 11.5.3. Effects of Design Parameters -- 11.6. Control of Pipestill -- 11.7. Conclusions -- References -- 12. Divided-Wall (Petlyuk) Columns -- 12.1. Introduction -- 12.2. Steady-State Design -- 12.2.1. MultiFrac Model -- 12.2.2. RadFrac Model -- 12.3. Control of the Divided-Wall Column -- 12.3.1. Control Structure -- 12.3.2. Implementation in Aspen Dynamics -- 12.3.3. Dynamic Results -- 12.4. Control of the Conventional Column Process. 
505 8 |a 12.4.1. Control Structure -- 12.4.2. Dynamic Results and Comparisons -- 12.5. Conclusions and Discussion -- References -- 13. Dynamic Safety Analysis -- 13.1. Introduction -- 13.2. Safety Scenarios -- 13.3. Process Studied -- 13.4. Basic RadFrac Models -- 13.4.1. Constant Duty Model -- 13.4.2. Constant Temperature Model -- 13.4.3. LMTD Model -- 13.4.4. Condensing or Evaporating Medium Models -- 13.4.5. Dynamic Model for Reboiler -- 13.5. RadFrac Model with Explicit Heat-Exchanger Dynamics -- 13.5.1. Column -- 13.5.2. Condenser -- 13.5.3. Reflux Drum -- 13.5.4. Liquid Split -- 13.5.5. Reboiler -- 13.6. Dynamic Simulations -- 13.6.1. Base Case Control Structure -- 13.6.2. Rigorous Case Control Structure -- 13.7.Comparison of Dynamic Responses -- 13.7.1. Condenser Cooling Failure -- 13.7.2. Heat-Input Surge -- 13.8. Other Issues -- 13.9. Conclusions -- Reference -- 14. Carbon Dioxide Capture -- 14.1. Carbon Dioxide Removal in Low-Pressure Air Combustion Power Plants. 
505 8 |a 14.1.1. Process Design -- 14.1.2. Simulation Issues -- 14.1.3. Plantwide Control Structure -- 14.1.4. Dynamic Performance -- 14.2. Carbon Dioxide Removal in High-Pressure IGCC Power Plants -- 14.2.1. Design -- 14.2.2. Plantwide Control Structure -- 14.2.3. Dynamic Performance -- 14.3. Conclusions -- References -- 15. Distillation Turndown -- 15.1. Introduction -- 15.2. Control Problem -- 15.2.1. Two-Temperature Control -- 15.2.2. Valve-Position Control -- 15.2.3. Recycle Control -- 15.3. Process Studied -- 15.4. Dynamic Performance for Ramp Disturbances -- 15.4.1. Two-Temperature Control -- 15.4.2. VPC Control -- 15.4.3. Recycle Control -- 15.4.4.Comparison -- 15.5. Dynamic Performance for Step Disturbances -- 15.5.1. Two-Temperature Control -- 15.5.2. VPC Control -- 15.5.3. Recycle Control -- 15.6. Other Control Structures -- 15.6.1. No Temperature Control -- 15.6.2. Dual Temperature Control -- 15.7. Conclusions -- References. 
505 8 |a 16. Pressure-Compensated Temperature Control in Distillation Columns -- 16.1. Introduction -- 16.2. Numerical Example Studied -- 16.3. Conventional Control Structure Selection -- 16.4. Temperature/Pressure/Composition Relationships -- 16.5. Implementation in Aspen Dynamics -- 16.6.Comparison of Dynamic Results -- 16.6.1. Feed Flow Rate Disturbances -- 16.6.2. Pressure Disturbances -- 16.7. Conclusions -- References -- 17. Ethanol Dehydration -- 17.1. Introduction -- 17.2. Optimization of the Beer Still (Preconcentrator) -- 17.3. Optimization of the Azeotropic and Recovery Columns -- 17.3.1. Optimum Feed Locations -- 17.3.2. Optimum Number of Stages -- 17.4. Optimization of the Entire Process -- 17.5. Cyclohexane Entrainer -- 17.6. Flowsheet Recycle Convergence -- 17.7. Conclusions -- References -- 18. External Reset Feedback to Prevent Reset Windup -- 18.1. Introduction -- 18.2. External Reset Feedback Circuit Implementation -- 18.2.1. Generate the Error Signal. 
505 8 |a 18.2.2. Multiply by Controller Gain -- 18.2.3. Add the Output of Lag -- 18.2.4. Select Lower Signal -- 18.2.5. Setting up the Lag Block -- 18.3. Flash Tank Example -- 18.3.1. Process and Normal Control Structure -- 18.3.2. Override Control Structure Without External Reset Feedback -- 18.3.3. Override Control Structure with External Reset Feedback -- 18.4. Distillation Column Example -- 18.4.1. Normal Control Structure -- 18.4.2. Normal and Override Controllers Without External Reset -- 18.4.3. Normal and Override Controllers with External Reset Feedback -- 18.5. Conclusions -- References. 
520 |a The 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. 
590 |a Knovel  |b ACADEMIC - Mechanics & Mechanical Engineering 
650 0 |a Distillation apparatus  |x Design and construction. 
650 0 |a Chemical process control  |x Simulation methods. 
650 0 |a Petroleum  |x Refining. 
650 6 |a Procédés chimiques  |x Contrôle  |x Méthodes de simulation. 
650 6 |a Pétrole  |x Raffinage. 
650 7 |a SCIENCE  |x Chemistry  |x Industrial & Technical.  |2 bisacsh 
650 7 |a TECHNOLOGY & ENGINEERING  |x Chemical & Biochemical.  |2 bisacsh 
650 7 |a Distillation apparatus  |x Design and construction  |2 fast 
650 7 |a Petroleum  |x Refining  |2 fast 
776 0 8 |i Print version:  |a Luyben, William L.  |t Distillation design and control using Aspen simulation.  |d Hoboken, New Jersey : John Wiley & Sons, [2013]  |z 9781118411438  |z 1118411439  |w (DLC) 2012030047  |w (OCoLC)811238959 
856 4 0 |u https://appknovel.uam.elogim.com/kn/resources/kpDDCUASEI/toc  |z Texto completo 
938 |a Askews and Holts Library Services  |b ASKH  |n AH25494691 
938 |a EBSCOhost  |b EBSC  |n 1102199 
938 |a YBP Library Services  |b YANK  |n 9571196 
938 |a YBP Library Services  |b YANK  |n 10585385 
994 |a 92  |b IZTAP 

Ejemplares similares