A novel method for the synthesis of biodiesel as an eco-friendly and sustainable fuel

A. Shalmashi
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Abstract

Biodiesel is a green diesel fuel that is synthesized via the transesterification reaction of plant oils or animal fats with light alcohols, mainly methanol, in the presence of commonly homogeneous alkaline catalysts. One way to make the biodiesel synthesis process more eco-friendly is the use of heterogeneous catalysts as they are reusable. But with these catalysts, the transesterification reaction mixture will be a three-phase mixture containing methanol, oil and catalyst that leads to long reaction times and high process costs. In this study, the ultrasound waves were used to synthesis of the biodiesel from the Jatropha oil in the presence of CaO as a heterogeneous catalyst. The effect of two different co-solvents (acetone & hexane) on improving the homogeneity of the reaction mixture and therefore to enhance the conversion yield of the oil to biodiesel was considered. Experiments were carried out by a probe type ultrasonic instrument at an output power of 200 W and frequency of 20 kHz. The results showed that both of the considered co-solvents had positive effect on developing the conversion yield and the acetone was the more efficient one due to its moderate polarity, which could improve the miscibility of the oil with the methanol. A biodiesel sample with a conversion yield of 90.33% was synthesized under optimal operating conditions including 25% v/v acetone to methanol, 12:1 methanol to oil molar ratio, 4% w/w catalyst to oil, 55°C reaction temperature and 60 min reaction time. Hnmr and densitometry were used to determine the percentage of the synthesized biodiesel samples. Also, some of the physicochemical properties of the synthesized biodiesel were analyzed, which were in accordance with the ASTM and EN standards.
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一种合成生物柴油的新方法,作为一种环保和可持续的燃料
生物柴油是一种绿色柴油燃料,是在通常均相的碱性催化剂存在下,通过植物油或动物脂肪与轻醇(主要是甲醇)的酯交换反应合成的。使生物柴油合成过程更加环保的一种方法是使用多相催化剂,因为它们是可重复使用的。但使用这些催化剂,酯交换反应混合物将是含有甲醇、油和催化剂的三相混合物,导致反应时间长,工艺成本高。本研究以麻疯树油为原料,以CaO为多相催化剂,利用超声波合成了生物柴油。考察了丙酮和己烷两种不同的助溶剂对改善反应混合物均匀性的影响,从而提高油制生物柴油的转化率。实验采用探头式超声仪,输出功率为200w,频率为20khz。结果表明,两种助溶剂均对提高油的转化率有积极的影响,其中丙酮因其极性适中,能提高油与甲醇的混溶性,因而效率更高。在丙酮甲醇比为25% v/v、甲醇油摩尔比为12:1、催化剂油摩尔比为4% w/w、反应温度55℃、反应时间60 min的条件下,合成了转化率为90.33%的生物柴油样品。采用核磁共振和密度测定法测定合成生物柴油样品的百分比。并对合成的生物柴油进行了部分理化性能分析,符合ASTM和EN标准。
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