Abstract
The theoretical analysis for the design of microreactors in biodiesel production is a complicated task due to the complex liquid-liquid flow and mass transfer processes, and the transesterification reaction that takes place within these microsystems. Thus, computational simulation is an important tool that aids in understanding the physical-chemical phenomenon and, consequently, in determining the suitable conditions that maximize the conversion of triglycerides during the biodiesel synthesis. A diffusive-convective-reactive coupled nonlinear mathematical model, that governs the mass transfer process during the transesterification reaction in parallel plates microreactors, under isothermal conditions, is here described. A hybrid numerical-analytical solution via the Generalized Integral Transform Technique (GITT) for this partial differential system is developed and the eigenfunction expansions convergence rates are extensively analyzed and illustrated. The heuristic method of Particle Swarm Optimization (PSO) is applied in the inverse analysis of the proposed direct problem, to estimate the reaction kinetics constants, which is a critical step in the design of such microsystems. The results present a good agreement with the limited experimental data in the literature, but indicate that the GITT methodology combined with the PSO approach provide a reliable computational algorithm for direct-inverse analysis in such reactive mass transfer problems.
Highlights
Biodiesel is a biodegradable and non-toxic product with physico-chemical properties very similar to conventional diesel fuel and which can be obtained from renewable energy sources [1]
This work presents an approach to estimate the kinetic constants in highly nonlinear models using a hybrid method to solve the mass transfer direct problem, associated with a heuristic method for optimization of the objective function, resulting in an interesting and effective approach to carry out the inverse analysis in such class of problems
The Particle Swarm Optimization (PSO) was applied considering a swarm with 200 particles distributed in a region established by the parameter coefficient k i range, from 1 to 9
Summary
Biodiesel is a biodegradable and non-toxic product with physico-chemical properties very similar to conventional diesel fuel and which can be obtained from renewable energy sources [1]. Determining the kinetic constants is not an easy task, since besides an adequate experimental apparatus, it is necessary to formulate a mathematical model to represent the complex liquid-liquid flow that is established within the microreactors with the associated mass transfer and chemical reaction effects This model, under the hypothesis of second order chemical reactions [2,3], presents nonlinearities that couple the species balance equations involved in the transesterification reaction, requiring the use of numeric or hybrid (numeric-analytical) solution methods. This work presents an approach to estimate the kinetic constants in highly nonlinear models using a hybrid method to solve the mass transfer direct problem, associated with a heuristic method for optimization of the objective function, resulting in an interesting and effective approach to carry out the inverse analysis in such class of problems. This method is based on the social behavior of various species and it has successfully solved a number of complex optimization and parameter estimation problems [5,6,11]
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