Jaafar Yehya, Ramirez Gian Carlos Arias, Abdelouahed Lokmane, El Samrani Antoine, El Hage Roland, Taouk Bechara
INSA Rouen Normandie, University Rouen Normandie, Normandie Université, LSPC, UR 4704, F-76000 Rouen, France.
Laboratory of Geoscience, Georesources and Environment (L2GE) Campus Fanar EDST, Faculty of Science, Lebanese University, Fanar, Jdeidet P.O. Box 90656, Lebanon.
Molecules. 2023 Jul 30;28(15):5758. doi: 10.3390/molecules28155758.
This study aims to investigate the catalytic co-pyrolysis of beech wood with polystyrene as a synergic and catalytic effect on liquid oil production. For this purpose, a tubular semi-continuous reactor under an inert nitrogen atmosphere was used. Several zeolite catalysts were modified via incipient wetness impregnation using iron and/or nickel. The liquid oil recovered was analyzed using GC-MS for the identification of the liquid products, and GC-FID was used for their quantification. The effects of catalyst type, beechwood-to-polystyrene ratio, and operating temperature were investigated. The results showed that the Fe/Ni-ZSM-5 catalyst had the best deoxygenation capability. The derived oil was mainly constituted of aromatics of about 92 wt.% for the 1:1 mixture of beechwood and polystyrene, with a remarkably high heating value of around 39 MJ/kg compared to 18 MJ/kg for beechwood-based bio-oil. The liquid oil experienced a great reduction in oxygen content of about 92% for the polystyrene-beechwood 50-50 mixture in comparison to beechwood alone. The catalytic and synergetic effects were more realized for high beechwood percentages as a 75-25 beechwood-polystyrene mix. Regarding the temperature variation between 450 and 600 °C, the catalyst seemed to deactivate faster at higher temperatures, thus constituting a quality reduction in the pyrolytic oil in high-temperature ranges.
本研究旨在考察山毛榉木与聚苯乙烯的催化共热解对液体油生产的协同和催化作用。为此,使用了一个在惰性氮气气氛下的管式半连续反应器。通过初湿浸渍法用铁和/或镍对几种沸石催化剂进行了改性。对回收的液体油进行气相色谱-质谱联用(GC-MS)分析以鉴定液体产物,并使用气相色谱-氢火焰离子化检测器(GC-FID)对其进行定量。研究了催化剂类型、山毛榉木与聚苯乙烯的比例以及操作温度的影响。结果表明,Fe/Ni-ZSM-5催化剂具有最佳的脱氧能力。对于山毛榉木和聚苯乙烯1:1的混合物,衍生油主要由约92 wt.%的芳烃组成,与基于山毛榉木的生物油18 MJ/kg相比,其热值显著较高,约为39 MJ/kg。与单独的山毛榉木相比,聚苯乙烯-山毛榉木50-50混合物的液体油氧含量大幅降低约92%。对于75-25的山毛榉木-聚苯乙烯混合物这种高比例山毛榉木的情况,催化和协同作用更为明显。关于450至600 °C之间的温度变化,催化剂在较高温度下似乎失活更快,从而导致高温范围内热解油质量下降。
