共查询到17条相似文献,搜索用时 78 毫秒
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橄榄油制备生物柴油的工艺研究 总被引:3,自引:0,他引:3
以橄榄油为原料,四氢呋喃作共溶剂,NaOH为催化剂制备生物柴油.用气相色谱分析方法,通过对反应温度、醇油摩尔比、催化剂的量、反应时间的研究,得出在各自的最优化条件下橄榄油的转化率为97.3%. 相似文献
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桐油制备生物柴油的工艺研究 总被引:3,自引:1,他引:3
以四川桐油为原料,研究了生产生物柴油过程中的酯交换反应条件的影响。结果表明,当甲醇和油脂的物质的量之比超过6∶1后,桐油转化率提高范围很小。当油脂中含有少量游离脂肪酸和水分时,通过甘油虽可测定油脂的转化率,但是后处理时乳化严重,甲酯的损失较大从而影响甲酯的收率。反应温度对反应的转化率影响较大。通过测定桐油生物柴油的物性,表明桐油生物柴油的低温流动性良好,可以作为低温流动性改进剂与其它油脂制备的生物柴油混合使用。闪点为194℃,硫含量为70.75μg/g。 相似文献
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面对能源紧缺和环境污染,生物柴油替代传统石化燃料已成为研究热点。本文从原料选取、生产方法和生产工艺的角度对生物柴油发展进行了评价和比选。结合最新研究进展发现,现阶段相比其他工艺,化学催化工艺技术生产生物柴油更为成熟可靠,且更加有利于我国大规模工业化生产的实现。 相似文献
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《分离科学与技术》2012,47(7-9):2021-2033
Abstract The acceptance of methylesters (biodiesel) as an alternative fuel has rapidly increased in recent years. This development has been followed by increasing research activities in the field of methylester processes. After listing reasons that supporte arguments for biodiesel and a survey of production methods, a low-waste process for biodiesel is introduced. 相似文献
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提出了一种清洁、环境友好的餐饮业废油脂制备生物柴油的方法和工艺.以磁性固体超强酸SO2-4/TiO2-Fe3O4为非均相催化剂,以餐饮业废油脂为原料与甲醇进行酯交换反应制备生物柴油;利用三因素一次回归正交设计实验方法,考察了反应温度、甲醇用量、催化剂用量对废油脂酯转化率的影响,确定了制备生物柴油的最佳反应条件;通过对实验结果的处理,求出了回归方程;数理统计分析表明回归方程可靠适用;同时利用IR、XRD、SEM、EDS等对磁性固体超强酸SO2-4/TiO2-Fe3O4催化剂的结构进行了表征.与传统的均相催化剂(H2SO4、NaOH) 相比,磁性固体超强酸具有催化活性高、易于分离、可重复使用的特点,是制备生物柴油的环境友好型固体酸催化剂. 相似文献
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超临界酯交换法制备生物柴油工艺基础及其过程强化技术研究 总被引:3,自引:0,他引:3
生物柴油以其优良的环境友好性和可再生性成为近年来的研究热点.简述了生物柴油的特性,比较了生物柴油制备工艺的优缺点,重点介绍了超临界甲醇法制备生物柴油的研究现状,指出以共溶剂和催化剂强化超临界过程可以有效地改善反应条件;同时对超临界甲醇法制备生物柴油的热力学和动力学进行了探讨,包括状态方程、混合体系临界参数、反应速率常数和反应活化能的估算方法;最后对超临界甲醇法制备生物柴油的经济性进行了分析.结果表明,超临界酯交换法具有与传统酸碱催化过程相当的竞争性,尤其是对以餐饮废油等低成本油为原料的生产过程. 相似文献
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Effects of High Temperatures and Duration of Heating on Olive Oil Properties for Food Use and Biodiesel Production 下载免费PDF全文
Heating deteriorates the physicochemical properties of a vegetable oil for both edible and biofuel uses. The parameters for edible olive oil are established by European Union regulations and by the International Olive Council. The properties of a vegetable oil to be used as a source for biodiesel production are indicated by the German DIN 51605 for rapeseed oil. Biofuel properties are described by the European EN 14214 and the North American ASTM 6751 standards for biodiesel. It is useful to know how temperature and heating duration influence the physicochemical properties of olive oil. Free acidity, refractive index and myristic acid were not significantly influenced by temperature and heating duration. K232, K266, K270, K274, p-anisidine value, totox index, kinematic viscosity (at 30, 40, 50 °C), estimated higher heating value, relative density, and cetane number increased during olive oil heating. The biological properties: iodine value, oxidative stability index, antiradical (2,2-diphenyl-1-picrylhydrazyl radical, DPPH?) activity, and phenol content, decreased when time and temperature increased. Fatty acid methyl esters were highly influenced by the applied variables. Almost all the fatty acid methyl esters, except myristic, stearic, and arachidic acid esters, were influenced by the combined effect of temperature and time in a very highly significant level. These results show how temperature and duration of heating influence extra virgin olive oil degradation for both edible use and biodiesel production. 相似文献