McCormick Robert L, Fioroni Gina M, Naser Nimal, Luecke Jon
National Renewable Energy Laboratory, 15301 Denver West Parkway, Golden, Colorado 80401, United States.
Energy Fuels. 2024 May 7;38(10):8829-8841. doi: 10.1021/acs.energyfuels.4c00912. eCollection 2024 May 16.
While today's biomass-based diesel fuels are used at relatively low blend levels in petroleum diesel, decarbonization of the heavy-duty trucking and off-road sectors is driving increasing use of higher level blends and the combination of hydroprocessing-derived renewable diesel (RD) with biodiesel (fatty acid methyl esters) to create a 100% renewable fuel. However, little data are available on the properties of biodiesel blends over 20 vol % into RD or conventional diesel, despite the potential for properties to fall well outside the normal range for diesel fuels. Here, we evaluate the properties of 20-80% blends of a soy-derived biodiesel into RD and petroleum diesel. Properties measured were flash point, cloud point, cetane number, surface tension, density, kinematic viscosity, distillation curve, lower heating value, water content, water solubility in the fuel, lubricity, and oxidation stability. Density and viscosity were measured over a wide temperature range. A key objective was to reveal properties that might limit blending of biodiesel and any differences between biodiesel blends into RD versus petroleum diesel and to understand research needed to advance the use of high-level blends and 100% renewable fuel. Properties that may limit blending include the cloud point, viscosity, distillation curve, and oxidation stability. Meeting cloud point requirements can be an issue for all distillate fuels. For biodiesel, reducing the blend level and use of lower cloud point hydrocarbon blendstocks, such as No. 1 diesel or kerosene, can be used in winter months. Alternatively, a heated fuel system that allows for starting the vehicle on conventional diesel before switching to pure biodiesel (B100) or a high-level blend has been successfully demonstrated in the literature. Some biodiesels can have kinematic viscosity above the upper limit for diesel fuels (4.1 mm/s), which will limit the amount that can be blended. Biodiesel boils in a narrow range at the very high end of the No. 2 diesel range. Additional research is needed to understand how the high T90 of B100 and high-level blends and the very low distillation range of B100, some RD samples, and high-level biodiesel blends impact lube oil dilution, engine deposits, and diesel oxidation catalyst light-off. Blending with No. 1 diesel or kerosene or biodiesel-specific engine calibrations may mitigate these issues. Oxidation stability of higher level blends is poorly understood but may be addressed through the increased use of antioxidant additives. Finally, high-level biodiesel blends and B100 will have significantly higher density, viscosity, and surface tension compared to conventional diesel. In combination with the high boiling point, these properties may impact fuel spray atomization and evaporation, and additional research is needed in this area.
虽然当今基于生物质的柴油燃料在石油柴油中的混合比例相对较低,但重型运输和越野领域的脱碳正推动着更高混合比例的使用,以及将加氢处理衍生的可再生柴油(RD)与生物柴油(脂肪酸甲酯)混合以制造100%可再生燃料。然而,关于生物柴油在RD或传统柴油中混合比例超过20体积%时的性能数据很少,尽管其性能有可能远远超出柴油燃料的正常范围。在此,我们评估了大豆衍生生物柴油与RD和石油柴油以20%-80%比例混合后的性能。所测量的性能包括闪点、浊点、十六烷值、表面张力、密度、运动粘度、蒸馏曲线、低热值、含水量、水在燃料中的溶解度、润滑性和氧化稳定性。在较宽的温度范围内测量了密度和粘度。一个关键目标是揭示可能限制生物柴油混合的性能,以及生物柴油与RD混合和与石油柴油混合之间的任何差异,并了解推进高比例混合和100%可再生燃料使用所需的研究。可能限制混合的性能包括浊点、粘度、蒸馏曲线和氧化稳定性。满足浊点要求对所有馏分燃料来说都可能是个问题。对于生物柴油,在冬季可通过降低混合比例以及使用浊点较低的烃类调合组分,如1号柴油或煤油来解决。或者,文献中已成功证明了一种加热燃料系统,该系统允许车辆先用传统柴油启动,然后再切换到纯生物柴油(B100)或高比例混合燃料。一些生物柴油的运动粘度可能高于柴油燃料的上限(4.1毫米/秒),这将限制其可混合的量。生物柴油在2号柴油范围的高端非常窄的范围内沸腾。需要更多研究来了解B100和高比例混合燃料的高T90以及B100、一些RD样品和高比例生物柴油混合燃料的极窄蒸馏范围如何影响润滑油稀释、发动机沉积物和柴油氧化催化剂的起燃。与1号柴油或煤油混合或进行生物柴油专用的发动机校准可能会缓解这些问题。对高比例混合燃料的氧化稳定性了解甚少,但可通过增加抗氧化添加剂的使用来解决。最后,与传统柴油相比,高比例生物柴油混合燃料和B100的密度、粘度和表面张力将显著更高。结合其高沸点,这些性能可能会影响燃料喷雾的雾化和蒸发,这一领域还需要更多研究。
