Pilot-scale enhancement of vacuum residue conversion via dual-stage catalytic cracking coupled with hydrogen regulation: Toward optimal product selectivity

IF 6.2 2区化学 Q1 CHEMISTRY, ANALYTICAL

Journal of Analytical and Applied Pyrolysis Pub Date : 2025-10-16 DOI:10.1016/j.jaap.2025.107427

Chengbiao Wang , Jingxian Wang , Xiaoxi An , Peijie Zong , Wenshuo Ma , Yanpeng Zhang , Ruotong Cui , Wenlong Xu , Di Zhang , Yingyun Qiao , Yuanyu Tian

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Abstract

Efficient conversion of vacuum residue (VR) into high-value light olefins and aromatics is critical for the sustainable utilization of heavy carbon resources. In this study, we propose a dual-stage gas-phase catalytic cracking process using a modified dual-stage self-mixing downer circulating fluidized bed (DS-DCFB) reactor tailored for intermediate-naphthenic VR. In the primary stage (530 °C, calcium aluminate catalyst (CaAl)), a 69.21 wt% liquid yield and 70.24 % heavy oil conversion were achieved with only 11.05 wt% coke formation. The dual-stage system (Stage I: 530 °C, CaAl catalyst; Stage II: 610 °C, acid-base composite catalyst (Z-CA)) significantly enhanced light olefin selectivity, yielding 30.13 wt% light olefins (C₂–C₄) and 40.64 wt% liquid products, while maintaining coke yield at 14.61 wt%. Notably, introducing 1.00 wt% H₂ co-feeding suppressed methane and coke formation by 22.29 % and 11.02 % and simultaneously increased the yields of benzene, toluene, and xylene (BTX) by 2.87 wt%. The DS-DCFB reactor exhibited robust stability during 12-hour continuous pilot-scale operation, confirming its efficiency for VR-to-chemicals conversion. These findings demonstrate the synergistic role of hierarchical catalysis and hydrogen regulation in suppressing coke formation, enhancing light olefin yield, and achieving stable pilot-scale performance. This work provides key experimental insights for industrial VR valorization and offers a promising pathway for heavy oil upgrading toward chemical feedstock production.

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通过双级催化裂化和氢调控对真空渣油转化的中试强化：走向最佳产品选择性

真空渣油高效转化为高价值轻质烯烃和芳烃是重碳资源可持续利用的关键。在这项研究中，我们提出了一种双级气相催化裂化工艺，该工艺使用的是为中间环烷基VR量身定制的改进的双级自混合下行循环流化床（DS-DCFB）反应器。在初级阶段（530°C，铝酸钙催化剂（CaAl）），得到69.21 wt%的产液率和70.24 %的重油转化率，只有11.05 wt%的焦炭生成。双级体系（阶段I: 530℃，CaAl催化剂；阶段II: 610℃，酸碱复合催化剂（Z-CA））显著提高了轻烯烃的选择性，产率为30.13 wt%轻烯烃（C₂-C₄）和40.64 wt%液体产物，同时保持焦炭产率为14.61 wt%。值得注意的是，引入1.00 wt%的h2共进料，甲烷和焦炭的生成分别降低了22.29 %和11.02 %，同时苯、甲苯和二甲苯（BTX）的产率提高了2.87 wt%。DS-DCFB反应器在连续12小时的中试运行中表现出强大的稳定性，证实了其VR-to-chemicals转化的效率。这些发现证明了分级催化和氢调控在抑制焦炭形成、提高轻烯烃收率和实现稳定中试规模性能方面的协同作用。这项工作为工业VR增值提供了关键的实验见解，并为重油向化学原料生产的升级提供了一条有希望的途径。

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来源期刊

Journal of Analytical and Applied Pyrolysis 化学-分析化学

CiteScore

9.10

自引率

11.70%

发文量

340

审稿时长

44 days

期刊介绍： The Journal of Analytical and Applied Pyrolysis (JAAP) is devoted to the publication of papers dealing with innovative applications of pyrolysis processes, the characterization of products related to pyrolysis reactions, and investigations of reaction mechanism. To be considered by JAAP, a manuscript should present significant progress in these topics. The novelty must be satisfactorily argued in the cover letter. A manuscript with a cover letter to the editor not addressing the novelty is likely to be rejected without review.