Co-Hydroprocessing of Fossil Middle Distillate and Bio-Derived Durene-Rich Heavy Ends under Hydrotreating Conditions

Reactions Pub Date : 2023-09-21 DOI:10.3390/reactions4030032
David Graf, Johannes Waßmuth, Reinhard Rauch
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Abstract

Methanol-to-gasoline (MTG) and dimethyl ether-to-gasoline (DTG), as industrially approved processes for producing greenhouse gas-neutral gasoline, yield byproducts rich in heavy mono-ring aromatics such as 1,2,4,5-tetramethylbenzene (durene). Due to its tendency to crystallize and the overall poor fuel performance, the heavy fuel fraction is usually further processed using after-treatment units designed for this purpose. This research article discusses the co-hydroprocessing (HP) of bio-derived heavy gasoline (HG) with fossil middle distillate (MD), drawing on available refinery hydrotreaters. Co-HP experiments were conducted in a laboratory-scale fixed bed reactor using an industrial CoMo/γ-Al2O3 catalyst, varying the space-time between 0.7 and 4.0 cmCat3 h cmFeed−3 and the reaction temperature between 340 and 390 °C. In addition to the durene conversion, special attention was paid to the octane and cetane numbers (CN) of gasoline and MD, respectively. A six-lump model with ten parameters was developed to predict relevant fuel yields dependent on the process conditions. Under stable catalyst conditions, C10 aromatic conversions of more than 60% were obtained, while the CN remained close to that of pure MD. Harsh process conditions increased the gasoline yield up to 20% at the cost of MD, while the kerosene yield remained almost constant. With an optimized lumping model, fuel yields could be predicted with an R2 of 0.998. In this study, co-HP heavy aromatic-rich MTG/DTG fuels with fossil MD were proven to be a promising process strategy compared to a stand-alone after-treatment.
在加氢处理条件下化石中间馏分与生物衍生的富均烯重端共加氢处理
甲醇制汽油(MTG)和二甲醚制汽油(DTG)是工业上认可的生产温室气体中性汽油的工艺,其副产品富含重单环芳烃,如1,2,4,5-四甲基苯(durene)。由于重质燃料馏分容易结晶,整体燃料性能较差,因此通常使用为此目的而设计的后处理装置对其进行进一步处理。利用现有的炼油厂加氢装置,探讨了生物源重质汽油(HG)与化石燃料中间馏分(MD)的共加氢处理(HP)。采用CoMo/γ-Al2O3工业催化剂,在实验室规模的固定床反应器中进行了共高压实验,反应时间为0.7 ~ 4.0 cmCat3 h cmFeed−3,反应温度为340 ~ 390℃。除杜伦转化率外,还特别关注汽油和MD的辛烷值和十六烷值(CN)。建立了一个包含10个参数的6块模型来预测依赖于工艺条件的相关燃料产量。在稳定的催化剂条件下,C10的芳烃转化率达到60%以上,而CN的转化率与纯MD接近。苛刻的工艺条件下,以MD为代价,汽油收率提高到20%,而煤油收率基本保持不变。优化后的集总模型预测燃料产量的R2为0.998。在本研究中,与独立后处理相比,具有化石MD的共hp重芳烃富MTG/DTG燃料被证明是一种有前途的工艺策略。
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CiteScore
2.70
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