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2 - Formulation of Optimization Problems in Chemical and Biochemical Engineering

Published online by Cambridge University Press:  05 February 2016

Suman Dutta
Suman Dutta
Affiliation:
Indian School of Mines
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Summary

Introduction

The major application of optimization in the chemical engineering field is minimizing energy consumption in process plant. Other applications include the optimum design of fluid flow systems, optimization of the separation process, and optimization of product concentration and reaction time in reacting systems. Estimation of the overall cost for any plant design is also a vital part. Optimization of process variables is the tool for the same. In biochemical engineering, optimization is required for finding the optimum operating conditions of a bioreactor, and parameter estimation in biochemical pathways. The process of optimization requires proper formulation of the objective function and necessary constraint functions. The objective function can be formulated in different ways based on the number of variables involve in the process. If the process mechanisms are known to us and the number of variables are less, then objective functions are formulated based on basic principles of science and technology (e.g., law of conservation, thermodynamic laws). Moreover, if the process mechanisms are complicated and not known to us, number of variables are large; statistical optimization methods like Response Surface Methodology (RSM) and Artificial Neural Network (ANN) are applicable for those processes.

Formulation of Optimization Problem

One of the important steps during the application of optimization technique to a practical problem is the formulation of objective functions. We have to develop the model equations based on the physical appearance of the system. When we are formulating the mathematical statement of the objective, we have to keep in mind that the complexity increases with the nonlinearity of the function. During optimization, more complex functions or more nonlinear functions are harder to solve. There are many modern optimization software (see chapter 12) that have been developed to solve highly nonlinear functions. Most of the optimization problems comprise one objective function. Even though some problems that involve multiple objective functions cannot be transformed into a single function with similar units (e.g., maximizing profit while simultaneously minimizing risk).

Fluid Flow System

Liquid storage and transportation trough pipeline is very common in chemical process industry. In this section, we will discuss about the design of optimization storage tank and optimum pump configuration.

Optimization of liquid storage tank

A cylindrical tank (Fig. 2.1) has a volume (V) that can be expressed by V = (π/4)D2L, and we are interested to calculate the diameter (D) and height (H) that minimize the cost of the tank.

Type
Chapter
Information
Optimization in Chemical Engineering , pp. 12 - 39
Publisher: Cambridge University Press
Print publication year: 2016

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References

Bracken, J. and McCormick, G. P. 1968. Selected Applications of Nonlinear Programming, New York : John Wiley and Sons.Google Scholar
Buskies, U. ‘Chemical Engineering TechnologyEconomic Process Optimization Strategies, 20(1997)63-70.Google Scholar
Coulson, J. M. and Richardson, J. F. 1985. Chemical Engineering, vol. 1, Oxford: Pergamon Press.Google Scholar
Edgar, T. F., Himmelblau, D. M., Lasdon, L. S.Optimization of Chemical Processes (2e), New York: McGraw-Hil.
Ghose, T. K. and Gosh, P. (1976). ‘Kinetic Analysis of Gluconic Acid Production by Pseudomonas Ovalis’, Journal of Applied Chemical Biotechnology, 26, 768-77.Google Scholar
Grewal, B. S.Higher Engineering Mathematics (37e), Delhi-110006: Khanna Publishers, India.
Griskey, R. G. 2002. Transport Phenomena and Unit Operations: A Combined Approach, New York: John Wiley and Sons.CrossRef
Gueddar, T., Dua V. Novel model reduction techniques for refinery-wide energy optimization, Applied Energy, 89(2012): 117-26.Google Scholar
Halsall-Whitney, H., Thibault, J.Multi-Objective Optimization for Chemical Processes and Controller Design: Approximating and Classifying the Pareto Domain, Computers and Chemical Engineering, 30(2006): 1155-68.Google Scholar
Johansen, T. A. and Foss, B. A. (1995). Semi-Empirical Modeling of Non-linear Dynamic Systems through Identification of Operating Regimes and Locals Models. In K., Hunt, G., Irwin, and K., Warwick (Eds.), Neural Network Engineering in Control Systems, Springer-Verlag, pp. 105-26.Google Scholar
Levenspiel, O.Chemical Reaction Engineering (3e), New Jersey: John Wiley and Sons, Inc.CrossRef
Peters, M. S., Timmerhaus, K., West, R. E.Plant Design and Economics for Chemical Engineers (5e), New York: McGraw-Hil.
Pettersson, F. and Westerlund, T. 1997. Global Optimization of Pump Configurations Using Binary Separable Programming, Computers Chemical Engineering, vol. 21, No. 5, pp. 521-29.Google Scholar
Rao, S. S.Engineering Optimization Theory and Practice, Fourth Edition, New Jersey: John Wiley and Sons, Inc.
Rezende, M. C. A. F., Costa, C. B. B., Costa, A. C., Maciel, M. R. W., Filho, R. M.Optimization of a Large Scale Industrial Reactor by Genetic Algorithms, Chemical Engineering Science, 63(2008): 330-41.Google Scholar
Roy, G. K. 2000. Solved Examples in Chemical Engineering (7e), Delhi: Khanna Publishers
Schmidt, L. D. 2005. The Engineering of Chemical Reactions (2e), New York: Oxford University Press.Google Scholar
Westerlund, T., Pettersson, F., Grossmann, I. E. 1994. Optimization of Pump Configurations as a MINLP Problem, Computers Them. Engng., vol. 18, No. 9, pp. 845-58.

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