HY分子筛酸性孔结构耦合调控及其催化萘与1-十二烯烷基化反应性能的研究

石油炼制与化工 ›› 2025, Vol. 56 ›› Issue (12): 41-49.

HY分子筛酸性孔结构耦合调控及其催化萘与1-十二烯烷基化反应性能的研究

刘哲,周顺利,李永祥,张成喜,刘宜鹏

中石化石油化工科学研究院有限公司石油化工分子转化与反应工程全国重点实验室

收稿日期:2025-04-15 修回日期:2025-07-30 出版日期:2025-12-12 发布日期:2025-12-02
通讯作者: 李永祥 E-mail:liyx.ripp@sinopec.com
基金资助:
理性设计过渡态择形催化芳烃烷基化反应研究;固体酸催化制备长链烷基萘模试及技术数据包开发

STUDY ON COUPLED REGULATION OFACID PROPERTIES AND PORE STRUCTURE IN HY ZEOLITE AND ITS CATALYTIC PERFORMANCE IN ALKYLATION OF NAPHTHALENE WITH 1-DODECENE

Received:2025-04-15 Revised:2025-07-30 Online:2025-12-12 Published:2025-12-02

摘要/Abstract

摘要： 探究加压水蒸气处理对HY分子筛酸性质和孔结构及其催化萘与1-十二烯烷基化反应性能的影响规律。采用扫描电子显微镜、氨气程序升温脱附与吡啶吸附红外光谱等多种分析方法对催化剂的酸性质和孔道结构等物化性质进行表征。结果表明，经过0.2 MPa加压水蒸气处理的分子筛催化剂的介孔孔体积为0.120 cm³/g，平均介孔孔径达到30 nm以上，反应物和产物分子在分子筛中的扩散性能提升，强酸位点可接近性指数从未经水蒸气处理的0.11提升至0.32，酸孔协同指数从16.53提升至32.28，实现了酸性质与孔道结构的协同优化。催化性能评价结果显示，经过0.2 MPa加压水蒸气处理的分子筛催化剂上的1-十二烯转化率和长链烷基萘选择性分别达到98.57%和95.07%，这主要归因于经过耦合调控的催化剂具有较大的介孔孔体积和较高的强酸位点可接近性。

关键词: HY分子筛, 耦合调控, 加压水蒸气处理, 长链烷基萘, 孔道结构

Abstract: This work systematically investigates the influence of pressurized water-vapor treatment on the acidic properties and pore structure of HY zeolite, as well as its catalytic performance in the alkylation of naphthalene with 1-dodecene. Advanced analytical techniques, including SEM, NH₃-TPD,and Py-IR, are used to characterize the acid properties and pore structure of the catalysts. The results indicate that the mesopore volume of the zeolite catalyst treated with pressurized steam at 0.2 MPa is 0.120 cm³/g, with an average mesopore diameter exceeding 30 nm. The diffusion performance of reactant and product molecules within the zeolite is improved. The accessibility index of strong acid sites rises from 0.11 (for the untreated catalyst)to 0.32, while the acid-pore synergy index increases from 16.53 to 32.28, evidencing a synergistic optimization of acid properties and pore structure. The catalytic performance evaluation reveals that the conversion rate of 1-dodecene and the selectivity for long-chain alkylnaphthalenes on the zeolite catalyst treated with pressurized steam at 0.2 MPa reach 98.57% and 95.07%, respectively. This is primarily attributed to thelarger mesopore volume and higher accessibility of strong acid sites of the catalyst achieved through coupled regulation.

Key words: HY zeolite, coupling regulation, pressurized steam treatment, long-chain alkylnaphthalene synthesis, pore structure

刘哲周顺利李永祥张成喜刘宜鹏. HY分子筛酸性孔结构耦合调控及其催化萘与1-十二烯烷基化反应性能的研究[J]. 石油炼制与化工, 2025, 56(12): 41-49.

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