Synthesis of intensified simple column configurations for multicomponent distillations

Chemical Engineering and Processing: Process Intensification

Volumn 62, Issue , 2012, Pages 1-17

  Rong, Ben Guang ^a   Errico, Massimiliano ^a  

^a UNIVERSITY OF SOUTHERN DENMARK   (Denmark)

Author keywords

Intensified simple column configurations; Multicomponent distillation; Process intensification; Systematic procedure; Thermal coupling

Indexed keywords

INTENSIFIED SIMPLE COLUMN CONFIGURATIONS; MULTICOMPONENTS; PROCESS INTENSIFICATION; SYSTEMATIC PROCEDURE; THERMAL COUPLING;

DISTILLATION; ENERGY UTILIZATION;

DISTILLATION COLUMNS;

EID: 84869868839     PISSN: 02552701     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.cep.2012.10.005     Document Type: Article

References (27)

1. Caballero J.A., Grossmann I.E. Design of distillation sequences: from conventional to fully thermally coupled distillation systems. Computers and Chemical Engineering 2004, 28:2307-2329.
2. Thompson R.W., King C.J. Systematic synthesis of separation schemes. AIChE Journal 1972, 18:941-948.
3. Seader J.D., Westerberg A.W. A combined heuristic and evolutionary strategy for the synthesis of simple separation sequences. AIChE Journal 1977, 23:951-954.
4. Henley E.J., Seader J.D. Equilibrium-stage Separation Operations in Chemical Engineering 1981, John Wiley & Sons, Inc, New York.
5. Nath R., Motard R.L. Evolutionary synthesis of separation processes. AIChE Journal 1981, 27:578-587.
6. Nadgir V.M., Liu Y.A. Studies in chemical process design and synthesis: PART V: a simple heuristic method for systematic synthesis of initial sequences for multicomponent separations. AIChE Journal 1983, 29:926-934.
7. Rathore R.N.S., VanWormer K.A., Powers G.J. Synthesis strategies for multicomponent separation systems with energy integration. AIChE Journal 1974, 20:491-502.
8. Errico M., Rong B.-G. Modified simple column configurations for quaternary distillations. Computers and Chemical Engineering 2012, 36:160-173.
9. Tedder D.W., Rudd D.F. Parametric studies in industrial distillations: Part I. design comparisons. AIChE Journal 1978, 24:303-315.
10. Rong B.-G., Kraslawski A. Optimal design of distillation flowsheets with a lower number of thermal couplings for multicomponent separations. Industrial and Engineering Chemistry Research 2002, 41:5716-5726.
11. Agrawal R. Synthesis of multicomponent distillation column configurations. AIChE Journal 2003, 49:379-401.
12. Agrawal R. Synthesis of distillation column configurations for a multicomponent separation. Industrial and Engineering Chemistry Research 1996, 35:1059-1071.
13. Agrawal R. A method to draw fully thermally coupled distillation column configurations for multicomponent distillation. Chemical Engineering Research and Design 2000, 78:454-464.
14. Agrawal R. Thermally coupled distillation with reduced number of intercolumn vapor transfers. AIChE Journal 2000, 46:2198-2210.
15. Caballero J.A., Grossmann I.E. Generalized disjunctive programming model for the optimal synthesis of thermally linked distillation columns. Industrial and Engineering Chemistry Research 2001, 40:2260-2274.
16. Caballero J.A., Grossmann I.E. Thermodynamically equivalent configurations for thermally coupled distillation. AIChE Journal 2003, 49:2864-2884.
17. Caballero J.A., Grossmann I.E. Structural considerations and modeling in the synthesis of heat-integrated thermally coupled distillation sequences. Industrial and Engineering Chemistry Research 2006, 45:8454-8474.
18. Rong B.-G., Kraslawski A., Turunen I. Synthesis of functionally distinct thermally coupled configurations for quaternary distillations. Industrial and Engineering Chemistry Research 2003, 42:1204-1214.
19. Rong B.-G., Turunen I. Synthesis of new distillation systems by simultaneous thermal coupling and heat integration. Industrial and Engineering Chemistry Research 2006, 45:3830-3842.
20. Segovia-Hernandez J.G., Ledezma-Martinez M., Carrera-Rodriguez M., Hernandez S. Controllability analysis of thermally coupled distillation systems: five-component mixtures. Industrial and Engineering Chemistry Research 2007, 46:211-219.
21. Hernandez S., Gudino-Mares I.R., Cardenas J.C., Segovia-Hernandez J.G., Rico-Ramirez V. A short note on control structures for thermally coupled distillation sequences for four-component mixtures. Industrial and Engineering Chemistry Research 2005, 44:5857-5863.
22. Calzon-McConville C.J., Rosalez-Zamora M.B., Segovia-Hernandez J.G., Hernandez S., Rico-Ramirez V. Design and optimization of thermally coupled distillation schemes for the separation of multicomponent mixtures. Industrial and Engineering Chemistry Research 2006, 45:724-732.
23. Christiansen A.C., Skogestad S., Lien K. Complex distillation arrangements: extending the Petlyuk ideas. Computers and Chemical Engineering 1997, 21:S237-S242.
24. Halvorsen I.J., Skogestad S. Minimum energy consumption in multicomponentdistillation. III. More than three products and generalized Petlyuk arrangements. Industrial and Engineering Chemistry Research 2003, 42:616-629.
25. Rong B.-G., Kraslawski A., Turunen I. Synthesis and optimal design of thermodynamically equivalent thermally coupled distillation systems. Industrial and Engineering Chemistry Research 2004, 43:5904-5915.
26. Rong B.-G., Kraslawski A. Synthesis of thermodynamically efficient distillation schemes for multicomponent separations. Computer-Aided Chemical Engineering, ESCAPE-12 2002, 319-324. Elsevier Science B.V, Amsterdam. J. Grievink, J.V. Schijndel (Eds.).
27. Rong B.-G., Kraslawski A., Turunen I. Systematic synthesis of functionally distinct new distillation systems for five-component separations. Computer-Aided Chemical Engineering, ESCAPE-15 2005, 823-828. Elsevier Science B.V, Amsterdam. L. Puigjaner, A. Espuna (Eds.).