Optimization of Continuous Distillation Columns Using Stochastic Optimization Approaches

Optimization of Continuous Distillation Columns Using Stochastic Optimization Approaches

The present work describes the use of two stochastic optimization formalisms, namely, genetic algorithms (GAs) and simultaneous perturbation stochastic approximation (SPSA), for the optimization of continuous distillation columns. Both the simple and azeotropic systems are considered in the analysis...

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Bibliographic Details
Published in:Chemical engineering research & design Vol. 79; no. 3; pp. 310 - 322
Main Authors: Ramanathan, S.P., Mukherjee, S., Dahule, R.K., Ghosh, S., Rahman, I., Tambe, S.S., Ravetkar, D.D., Kulkarni, B.D.
Format: Journal Article
Language:English
Published: Rugby Elsevier B.V 01-04-2001
Institution of Chemical Engineers
Subjects:
Applied sciences
azeotropic distillation
Chemical engineering
continuous distillation
Distillation
distillation optimization
Exact sciences and technology
genetic algorithms
Napthali-Sandholm model
simultaneous perturbation stochastic approximation
distillation optimization
Napthali-Sandholm model
genetic algorithms
simultaneous perturbation stochastic approximation
continuous distillation
azeotropic distillation
Distillation
Water
Ethanol
Multicomponent mixture
Ternary mixture
Stochastic approximation
Stochastic method
Optimization
Azeotropic distillation
Continuous process
Binary mixture
Genetic algorithm
Benzene
Objective function
Acetic acid
Gradient method
Methanol
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Summary:The present work describes the use of two stochastic optimization formalisms, namely, genetic algorithms (GAs) and simultaneous perturbation stochastic approximation (SPSA), for the optimization of continuous distillation columns. Both the simple and azeotropic systems are considered in the analysis. In particular, for a specified degree of separation the problem of finding the optimal values of: (i) the number of stages, (ii) reflux ratio (entrainer quantity in the case of azeotropic distillation), (iii) feed location(s), have been addressed. The GA-based optimization has several attractive features such as: (i) convergence to the global rather than to a local minimum, (ii) the objective function need not satisfy smoothness, differentiability, and continuity criteria, (iii) robustness of the algorithm. The other optimization technique used in the study i.e., SPSA, is a rapid gradient-descent related method for multivariate optimization and is especially well-suited in situations where direct computation of the objective function gradient is not feasible, or the objective function measurements could be noisy. The feasibility of utilizing the GA and SPSA techniques has been demonstrated by considering the separation of three binary and two azeotropic systems of industrial relevance.
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ISSN:0263-8762
DOI:10.1205/026387601750281671