Hydrocracking of hydrotreated light cycle oil for optimizing BTEX production: a simple kinetic model

IF 1.6 4区 工程技术 Q3 Chemical Engineering
G. Laredo, Eli H. Olmos-Cerda, P. Pérez-Romo, Ricardo Águeda-Rangel, A. García-López
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Abstract

Abstract The effect of the experimental conditions on the hydrocracking (HCK) of a hydrotreated light cycle oil (HDT LCO) was studied in this work. The catalyst tested was a 50/50 weight mixture of nickel-molybdenum-phosphorous on alumina (NiMo/Al2O3) and a commercial ZSM5 zeolite (HCK 50/50). The experimental conditions tested were 340, 350, 360, and 370 °C; 7.5 MPa; 0.9, 1.2, 1.5, and 1.8 h−1 LHSV, and H2/HC of 752 m3/m3. Two phases: gas and liquid, were obtained as HDK products. The gas phase consisted mostly of C1–C5 paraffins, iso-paraffins, and olefins. The liquid phase was characterized by GC-PIONA and was distributed in lumps as follows: NAPA by C11 to C13-naphthalenes; TET by C11 to C13-tetralins; IND by C9 to C13-indanes and indenes; AKB by C9 to C13-alkylbenzenes; BTEX by benzene, toluene, ethylbenzene, and xylenes; NAPE by C9 to C13-naphthenes; and PIP by C3 to C14 paraffin, iso-paraffin, and olefin type hydrocarbons. Using this classification, the results showed that increments in temperature and decrements in LHSV produced increments in the formation of gases, PIP, BTEX, and NAPE. At the same conditions, AKB, TET, NAPA, and IND decreased sharply. TET and NAPA derivatives were no longer present at high temperatures (360–370 °C). It seemed to be a limit of the BTEX formation directly related to the TET and IND presence, and it did not seem to depend on the transalkylation process of AKB hydrocarbons. Instead, AKB hydrocarbons were directly correlated to NAPE hydrocarbon formation by hydrogenation. A kinetic model was prepared. The model presented correlation coefficients higher than 98 %. The kinetic model that was made predicted that neither increasing the temperature nor lowering the LHSV would improve the BTEX formation when departing from this feedstock.
加氢处理轻循环油加氢裂化优化BTEX生产的简单动力学模型
本文研究了实验条件对加氢处理轻循环油(HDT-LCO)加氢裂化(HCK)的影响。测试的催化剂是氧化铝上的镍-钼-磷(NiMo/Al2O3)和市售ZSM5沸石(HCK 50/50)的50/50重量的混合物。测试的实验条件为340、350、360和370 °C;7.5 MPa;0.9、1.2、1.5和1.8 h−1 LHSV,H2/HC为752 m3/m3。获得两相:气体和液体,作为HDK产物。气相主要由C1–C5链烷烃、异链烷烃和烯烃组成。液相通过GC-PIONA进行表征,并呈块状分布如下:C11-C13萘的NAPA;C11-C13四氢萘的TET;C9-C13茚和茚的IND;C9-C13烷基苯的AKB;苯、甲苯、乙苯和二甲苯的BTEX;C9-C13环烷的NAPE;以及C3至C14链烷烃、异链烷烃和烯烃型烃的PIP。使用这种分类,结果表明,温度的增加和LHSV的减少会导致气体、PIP、BTEX和NAPE的形成增加。在相同条件下,AKB、TET、NAPA和IND急剧下降。TET和NAPA衍生物在高温下不再存在(360–370 °C)。这似乎是BTEX形成的一个极限,与TET和IND的存在直接相关,并且似乎不取决于AKB烃的烷基转移过程。相反,AKB烃通过氢化与NAPE烃的形成直接相关。制备了动力学模型。该模型的相关系数大于98 %. 所建立的动力学模型预测,当离开该原料时,无论是提高温度还是降低LHSV都不会改善BTEX的形成。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
2.80
自引率
12.50%
发文量
107
审稿时长
3 months
期刊介绍: The International Journal of Chemical Reactor Engineering covers the broad fields of theoretical and applied reactor engineering. The IJCRE covers topics drawn from the substantial areas of overlap between catalysis, reaction and reactor engineering. The journal is presently edited by Hugo de Lasa and Charles Xu, counting with an impressive list of Editorial Board leading specialists in chemical reactor engineering. Authors include notable international professors and R&D industry leaders.
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