矾土衬里在丙烷脱氢反应器中的沙化行为研究

摘要/Abstract

摘要： 丙烷脱氢反应器衬里在运行过程中出现的“沙化”现象严重制约了装置的长周期运转。通过X射线衍射、H2程序升温还原、扫描透射电子显微镜、X射线光电子能谱等表征手段对出现沙化的衬里进行分析，结果表明，沙化的原因是矾土衬里中形成了丝状炭。矾土中的杂质铁是导致丝状炭形成的主要原因。通过研究矾土在不同气氛中反应的质量增加现象，进一步明确反应气氛中氢气对丝状炭形成有促进作用。同时考察矾土在不同气氛、不同温度下的质量增加情况。结果表明，氢气与烷烃/烯烃共存时，丝状炭的生成温度大幅降低，且丙烯比丙烷更易在氧化铁表面裂解形成丝状炭。基于上述试验结果，初步确立了含铁矾土衬里的安全使用范围，为反应器衬里选材与工艺条件优化提供参考。

关键词: 矾土衬里, 沙化, 丙烷脱氢, 反应器, 铁, 丝状炭, 安全使用范围

Abstract: The ‘pulverization’ phenomenon occurring in the propane dehydrogenation reactor lining during operation severely restricts the long-term operation of the unit. The pulverized lining was analyzed by characterization techniques such as X-ray diffraction (XRD), H2 temperature-programmed reduction (H2-TPR), scanning electron microscopy (SEM) and X-ray photoelectron spectroscopy (XPS). The results indicate that iron (Fe) present in the bauxite lining could catalyze the filamentous carbon formed from alkanes, which generates significant expansive stress within the lining, leading to its failure. By studying the weight gain behavior of bauxite under different atmospheres, the promoting effect of hydrogen in the reaction atmosphere on the formation of filamentous carbon was clarified. The weight gain of bauxite under different atmospheres and temperatures was also investigated. The results show that the temperature of filamentous carbon formed is reduced significantly when hydrogen coexists with propane/ propylene, and propylene is more prone to cracking on the iron oxide surface to form filamentous carbon compared to propane. Based on the experimental results, a preliminary safe operating range for bauxite linings has been established, providing a reference for the selection of reactor lining materials and the optimization of process conditions.

Key words: bauxite lining, pulverization, propane dehydrogenation, reactor, ferrum, filamentous carbon, safe operating range

黄锐纪人杰燕晓宇徐家乐王飞李春义. 矾土衬里在丙烷脱氢反应器中的沙化行为研究[J]. 石油炼制与化工, 2026, 57(5): 168-177.

参考文献

[1]黄志华, 杨颖, 孙朝, et al.丙烷化学链氧化脱氢丙烯-氢气联产系统研究[J].铁道技术标准, 2023, 5(2):1-6
[2]Shan Yiou, Hu Huimin, Fan Xiaoqiang, et al.Recent progress in catalytic dehydrogenation of propane over Pt-based catalysts[J].Physical Chemistry Chemical Physics, 2023, 25(28):14-18
[3]Zhang Huanling, Jiang Yixue, Wang Guowei, et al.In-depth study on propane dehydrogenation over Al2O3-based unconventional catalysts with different crystal phases[J].Molecular catalysis, 2022, 519(0):112143-112146
[4]Rodaum Chadatip, Chaipornchalerm Peeranat, Nunthakitgoson Watinee, et al.Highly efficient propane dehydrogenation promoted by reverse water–gas shift reaction on Pt-Zn alloy surfaces[J].Fuel, 2022, 325(0):124833-124838
[5]钟香崇.新一代矾土基耐火材料[J].硅酸盐通报, 2006, 25(5):92-98
[6]徐平坤.中国耐火原料发展的探讨[J].耐火与石灰, 2024, 49(5):1-6
[7]于志, 李淼, 高金星, et al.TiO2在耐火材料中的研究与应用进展[J].耐火材料, 2021, 55(5):5-6
[8]Lian Jianwei, Boquan Zhu, Xiangcheng Li, et al.Growth mechanism of in situ diamond-shaped mullite platelets and their effect on the properties of Al2O3-SiC-C refractories[J].Ceramics International, 2016, 43(15):12427-12434
[9]赵亚伟, 苟荣恒, 何源, et al.甲醇制烯烃反-再系统衬里损坏原因分析及解决办法[J].现代化工, 2024, 44(S01):345-350
[10]吴云龙.异丁烷脱氢装置中掌形件耐火隔热衬里失效分析及改进措施[J].石油化工设备技术, 2017, 38(6):61-66
[11]周子炫.催化裂化装置再生器衬里损坏情况分析及修复[J].科技创新与应用, 2017, 6(6):126-126
[12]奚伟光.催化裂化装置两器衬里施工的技术改进措施[J].化工管理, 2019, 1(22):189-190
[13]付春辉.催化裂化装置衬里损坏情况分析及对策[J].石油化工设备技术, 2010, 31(5):26-28
[14]李铁斌.催化装置反再系统隔热耐磨衬里损坏原因及解决办法[J].中国设备工程, 2018, 1(19):62-64
[15]张亮.甲烷化反应器衬里的选择与设计优化分析[J].中国石油和化工标准与质量, 2012, 32(16):48-52
[16]Kim Sungyun, Woo JongWon, Kim EunHee, et al.Mechanical degradation of mullite-and andalusite-based refractories in hot hydrogen environment[J].Journal of the Korean Ceramic Society, 2025, 62(1):798-809
[17]Takenaka Sakae, Serizawa Michio, Otsuka Kiyoshi.Formation of filamentous carbons over supported Fe catalysts through methane decomposition[J].Journal of Catalysis, 2004, 222(2):520-531
[18][18]Kang Jiandong, Ran Jingyu, Niu Juntian, et al.Experimental and theoretical study on propane pyrolysis to produce gas and soot[J].International journal of hydrogen energy, 2019, 44(41):22904-22978
[19]Yang Jie, Bao Chunxiong, Yu Tao, et al.Enhanced performance of photoelectrochemical water splitting with ITO@α-Fe2O3 Core-shell Nanowire Array as Photoanode[J].ACS Applied Materials Interfaces, 2015, 7(48):26482-26490
[20]Fan Zhiyong, Wang Zilong, Waleed Aashir, et al.Fabrication of CuFe2O4/alpha-Fe2O3 Composite Thin Films on FTO Coated Glass and 3-D Nanospike Structures for Efficient Photoelectrochemical Water Splitting[J].ACS applied materials interfaces, 2016, 8(51):35315-35322
[21]Ding Jie, Zhong Qin, Zhang Shule.Simultaneous removal of NOX and SO2 with H2O2 over Fe based catalysts at low temperature[J].Chemical Engineering Journal, 2014, 45(26):5394-5398
[22]Su Dang Sheng, Chen Xiaowei, Liu Xi, et al.Mount-Etna-Lava-Supported Nanocarbons for Oxidative Dehydrogenation Reactions[J].Advanced Materials, 2010, 20(19):3597-3600
[23]Feng Yuchuan, Wang Nana, Guo Xin, et al.Characteristics of dopant distribution and surface oxygen vacancy formation for modified Fe2O3 in chemical looping combustion[J].Fuel, 2020, 276(1):117942-117946
[24]Chan Antony PY, Sergeev Alexey G.Metal-mediated cleavage of unsaturated CC bonds[J].Coordination Chemistry Reviews, 2020, 413(1):213213-213217