石油炼制与化工 ›› 2026, Vol. 58 ›› Issue (7): 19-24.

• 加工工艺 • 上一篇    下一篇

催化裂化汽油与乙烯烷基化降低苯含量研究

金雨萌,李福超,袁起民   

  1. 中石化石油化工科学研究院有限公司
  • 收稿日期:2025-11-03 修回日期:2026-03-11 出版日期:2026-07-12 发布日期:2026-06-29
  • 通讯作者: 袁起民 E-mail:yuanqm.ripp@sinopec.com
  • 基金资助:
    中国石油化工股份有限公司项目

STUDY ON REDUCING BENZENE CONTENT IN FCC GASOLINE VIA ETHYLENE ALKYLATION


  • Received:2025-11-03 Revised:2026-03-11 Online:2026-07-12 Published:2026-06-29

摘要: 针对催化裂化汽油苯含量高的问题,采用活性组分为ZSM-5分子筛的TZ催化剂,在固定床装置上考察了反应温度和空速对汽油与乙烯烷基化反应的影响,并分析了反应路径对产物分布和芳烃组成的作用规律。结果表明:乙烯单独进料时,经低聚、裂化以及环化脱氢等反应主要生成丙烷和芳烃,其中苯占芳烃总量的10%;汽油单独进料时,主要发生烯烃氢转移反应,同时还有裂化反应及缩合反应。对于汽油和乙烯的混合体系:在330 ℃时,汽油中苯和乙烯的烷基化反应效果较优,乙烯接近完全转化,汽油产率高,同时苯的脱除率可达36.69%,而360 ℃条件下裂化、环化脱氢等副反应加剧,导致苯含量升高;低质量空速(1.2~2.0 h-1)条件下,乙烯接近完全转化,而质量空速3.0 h-1时,因反应物停留时间缩短,乙烯转化受到抑制。

关键词: 催化裂化汽油, 乙烯, 苯含量, 烷基化, 反应路径

Abstract: In response to the high benzene content in FCC (fluid catalytic cracking) gasoline, this study employed a TZ catalyst with ZSM-5 zeolite as the active component to investigate the effects of reaction temperature and space velocity on the alkylation reaction of gasoline and ethylene in a fixed-bed reactor. The influence of reaction pathways on product distribution and aromatic composition was also analyzed. The results indicated that when ethylene was fed alone, reactions such as oligomerization, cracking, and cyclization-dehydrogenation primarily generated propane and aromatics, with benzene accounting for 10% of the total aromatics. When gasoline was fed alone, olefin hydrogen transfer reactions dominated, accompanied by cracking and condensation reactions. For the mixed system of gasoline and ethylene, the alkylation reaction between benzene in gasoline and ethylene exhibited optimal performance at 330 °C, achieving nearly complete ethylene conversion, high gasoline yield, and a benzene removal rate of 36.69%. However, at 360 °C, side reactions such as cracking and cyclization-dehydrogenation intensified, leading to an increase in benzene content. Under low mass space velocity conditions (1.2-2.0 h-1), ethylene was nearly completely converted, whereas at a mass space velocity of 3.0 h-1, the reduced residence time inhibited ethylene conversion.

Key words: FCC gasoline, ethylene, benzene content, alkylation, reaction pathway