Abstract
In the search of clean, sustainable and renewable energy sources, at present the use of bio-diesel from vegetable oils is one of the possibilities being considered. The knowledge of phase equilibrium in mixtures found in the bio-diesel production is essential for the correct design and operation of the process. However, there is still a lack of information about the parameter values for the models used to describe the phase equilibrium, which could lead to incorrect design of the reactors and the separation processes, and to low efficiency caused by low mass transfer due to the presence of heterogeneous mixtures. In this study, two algorithms are described for the model fitting and parameter estimation, which were used to estimate the values of the parameters in the UNIQUAC and NRTL model for a mixture of vegetable oils and bio-diesel. One of the algorithms uses the Simulated Annealing (SA) method, to find good initial estimates, without any previous knowledge of the parameters. Another algorithm uses Successive Quadratic Programming, using the estimates calculated in the SA algorithm to refine these estimates. In both algorithms, the criterion for fitting is the minimization of the square of the difference between calculated and experimental values. In both algorithms, the equilibrium is calculated using the direct global minimization of the Gibbs free energy with respect to the number of moles of each component, at constant T and P, for a given set of model parameters. The results obtained were able to correctly reproduce the experimental values of phase equilibrium composition.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aarts E, Korst J (1989) Simulated annealing and Boltzmann machines: a stochastic approach to combinatorial optimization and neural computing. Wiley, New York
Barbosa DD, Serra TM, Meneghetti SMP, Meneghetti MR (2010) Biodiesel production by ethanolysis of mixed castor and soybean oils. Fuels 89:3791–3794
Batista E, Monnerat S, Kato K, Stragevitch L, Meirelles AJA (1999) Liquid–liquid equilibrium for systems of canola oil, oleic acid, and short-chain alcohols. J Chem Eng Data 44:1360–1364
Castier M, Rasmussen P, Fredenslund A (1989) Calculation of simulataneous chemical and phase equilibria in nonideal systems. Chem Eng Sci 44:237–248
Chouinard-Dussault P, Bradt L, Ponce-Ortega JM, El-Halwagi MM (2011) Incorporation of process integration into life cycle analysis for the production of biofuels. Clean Technol Environ Policy 13:673–685
Elms RD, El-Halwagi MM (2010) The effect of greenhouse gas policy on the design and scheduling of biodiesel plants with multiple feedstocks. Clean Technol Environ Policy 12:547–560
Glaser JA (2009) Carbon dioxide recycling. Clean Technol Environ Policy 11:253–257
Liu X, Piao X, Wang Y, Zhu S (2008) Liquid-liquid equilibrium for systems of (fatty acid ethyl esters + ethanol + soybean oil and fatty acid ethyl esters + ethanol + glycerol). J Chem Eng Data 53:359–362
Mata TM, Martins AA, Sikdar SK, Costa CAV (2011) Sustainability considerations of biodiesel based on supply chain analysis. Clean Technol Environ Policy 13:655–671
Myint LL, El-Halwagi MM (2009) Process analysis and optimization of biodiesel production from soybean oil. Clean Technol Environ Policy 11:263–276
Ng JH, Ng HK, Gan S (2010) Recent trends in policies, socioeconomy and future directions of the biodiesel industry. Clean Technol Environ Policy 12:213–238
Parawira W (2010) Biodiesel production from jatropha curcas: a review. Sci Res Essays 5:1796–1808
Porte AF, Scheneider RDD, Kaercher JA, Klamt RA, Schmatz WL, da Silva WLT, Severo WA (2010) Sunflower biodiesel production and application in family farms in Brazil. Fuel 89:3718–3724
Ramos LP, Kucek KT, Domigos AK, Wilheim HM (2003) Biodiesel: Um projeto de sustentabilidade econômica e sócio-ambinetal para o Brasil. Biotecn Ciênc Desenv 31:27–37 (in Brazil)
Rodrigues CEC, Peixoto ECD, Meirelles AJA (2007) Phase equilibrium for systems composed by refined soybean oil + commercial linoleic acid + ethanol + water, at 323.2K. Fluid Phase Equilib 261:122–128
Smith WR (1980) The computation of chemical equilibria in complex systems. Ind Eng Chem Fund 19:1–10
Smith WR, Missen RW (1982) Chemical reaction equilibrium analysis: theory and algorithms. Wiley, New York
Sun H, Hu K, Lou H, Zheng X (2008) Biodiesel production from transesterification of rapeseed oil using KF/Eu2O3 as a catalyst. Energ Fuels 22:2756–2760
Valle P, Velez A, Hegel P, Mabe G, Brignole EA (2010) Biodiesel production using supercritical alcohols with a non-edible vegetable oil in a batch reactor. J Supercrit Fluid 54:61–70
Van Ness HC, Abbott MM (1982) Classical themodinamics of nonelectrolyte solutions: with applications to phase equilibria. McGraw-Hill Book Company, New York
Acknowledgments
This research study was supported by FAPESP—Fundação de Amparo à Pesquisa do Estado de São Paulo.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Rossi, C.C.R.S., Cardozo-Filho, L. & Guirardello, R. Parameter estimation and thermodynamic model fitting for components in mixtures for bio-diesel production. Clean Techn Environ Policy 14, 435–442 (2012). https://doi.org/10.1007/s10098-012-0463-8
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10098-012-0463-8