Improvement of Octane Number in FCC Gasoline Through the Extraction with Urea/Thiourea Complex based on Property Analysis

Industrial Chemistry & Materials Pub Date : 2024-03-16 DOI:10.1039/d4im00005f

Lin Gao, Chunyu Geng, Botao Teng, Hongwei Xiang, Xiaodong Wen, Yong Yang, Yongwang Li

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Abstract

In this paper, the uses urea/thiourea complexation approach was employed to enhance octane number of FCC gasoline by extracting n-alkanes. It was observed that adding thiourea improved the removal of n-alkanes from the gasoline, and matching results were obtained through the experiments using model samples. Molecular dynamics simulation revealed that the stability of urea complexes increased with raising carbon number of n-alkanes, while lighter n-alkane molecules exhibited lower propensity for complex formation with urea. This finding is in line with the results of DSC measurement at decomposition temperature. Furthermore, infrared spectrum analysis, XRD characterization, and reaction heat measurements indicated that although thiourea was introduced into the reaction system, it did not actively participate in the complexation reaction. In summary, the introduction of thiourea resulted in an increased solubility of urea in ethanol solution and enhanced reaction heat, suggesting its beneficial role in promoting urea complex formation and facilitating n-alkane removal from FCC gasoline.

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基于性能分析的尿素/硫脲复合物萃取法改善催化裂化汽油的辛烷值

本文采用尿素/硫脲络合方法，通过萃取正构烷烃来提高催化裂化汽油的辛烷值。研究发现，添加硫脲可提高汽油中正烷烃的去除率，并通过使用模型样品进行实验获得了与之匹配的结果。分子动力学模拟显示，尿素复合物的稳定性随着正构烷烃碳数的增加而增加，而较轻的正构烷烃分子与尿素形成复合物的倾向性较低。这一发现与分解温度下的 DSC 测量结果一致。此外，红外光谱分析、XRD 表征和反应热测量结果表明，虽然反应体系中引入了硫脲，但硫脲并没有积极参与络合反应。总之，硫脲的引入增加了尿素在乙醇溶液中的溶解度并提高了反应热，这表明硫脲在促进尿素络合物的形成和促进催化裂化汽油中正烷烃的脱除方面发挥了有益的作用。

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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