利用实验设计和人工神经网络优化橡胶籽油酯交换制生物柴油

K. Kouassi, Abollé Abollé, K. Yao, D. Boa, K. Adouby, P. Drogui, R. Tyagi
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引用次数: 3

摘要

对温室效应的担忧和对农业生物质的开发机会的兴趣推动了生物燃料的发展。为了通过建模和优化来提高生物柴油的产率和质量,一些研究正在进行中。本文采用Plackett-Burman实验设计、全因子设计、中心复合设计和人工神经网络(ANN)结合遗传算法(GA)对橡胶籽油均相酯交换法制备生物柴油进行了研究。研究了温度、搅拌速度、反应时间、醇类和催化剂类型等变量,以获得最佳比重和运动粘度。乙醇类型和催化剂类型对这两种反应的影响最大,其中乙醇(酒精)和硫酸(催化剂)产生的效果最好。在酯交换过程中记录的比重和运动粘度变化分别符合一阶和二阶多项式模型。采用人工神经网络和遗传算法同时优化两个响应。当温度为90°C,搅拌速度为305 rpm,处理时间为141 min时,所记录的比重(0.883)和运动粘度(6.76 cSt)的全局最优值。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Optimization of Rubber Seed Oil Transesterification to Biodiesel Using Experimental Designs and Artificial Neural Networks
The development of biofuels is driven both by concern about the greenhouse effect and by interest in the opportunities for exploitation of biomass of agricultural origin. In order to improve the yield and quality of biodiesel through modeling and optimization, several studies are in progress. In this paper, biodiesel produced from rubber seed oil in the homogeneous transesterification is studied using a Plackett-Burman experimental design, a full factorial design, a central composite design and an Artificial Neural Network (ANN) coupled with a Genetic Algorithm (GA).Variables such as temperature, stirring speed, reaction time, type of alcohol, and type of catalyst are studied to obtain the best specific gravity and kinematic viscosity. Type of alcohol and type of catalyst have the greatest effect on the two responses, with ethanol (alcohol) and sulphuric acid (catalyst) producing the best results. The specific gravity and kinematic viscosity changes recorded during the transesterification process followed the first and second order polynomial models, respectively. The ANN coupled with GA was used to optimize the two responses simultaneously. Global optimal values of specific gravity (0.883) and kinematic viscosity (6.76 cSt) were recorded when a temperature of 90°C, a stirring speed of 305 rpm, and a treatment time of 141 min were imposed.
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