液相加氢失活催化剂的物理性质分析及其再生性能

炼油技术与工程 ›› 2022, Vol. 52 ›› Issue (9): 45-48.

液相加氢失活催化剂的物理性质分析及其再生性能

陈禹霏¹,辛靖¹,韩龙年¹,于文奇²,宫祉夷²,黄宇岳²,范文轩¹,张海洪¹

1.中海油炼油化工科学研究院; 2.中海油惠州石化有限公司

收稿日期:2022-02-17 出版日期:2022-09-15 发布日期:2022-09-20
作者简介:陈禹霏，工程师，硕士，2015年毕业于中国石油大学(北京)化学工程与技术专业，主要从事汽柴油加氢催化剂及工艺研究工作。联系电话：010-89913285,E-mail:chenyf44@cnooc.com.cn。

Analysis of physical properties and regeneration performance of liquid-phase hydrogenation deactivated catalyst

Chen Yufei¹,Xin Jing¹,Han Longnian¹,Yu Wenqi²,Gong Zhiyi²,Huang Yuyue²,Fan Wenxuan¹,Zhang Haihong¹

1.CNOOC Research Institute of Refining and Petrochemicals (Beijing) Co., Ltd.; 2.CNOOC Huizhou Petrochemical Co., Ltd.

Received:2022-02-17 Online:2022-09-15 Published:2022-09-20

摘要/Abstract

摘要：

为了探究柴油液相加氢失活催化剂的性质变化以及再生后催化剂的加氢性能，通过N₂吸附-脱附、C-S元素分析、XRF和XRD等表征手段对加氢精制失活剂与再生剂进行物理性质分析，并利用小试评价装置考察催化剂再生后催化裂化性能。结果显示：失活催化剂的C元素质量分数为8.37%,S元素质量分数为9.45%,失活剂的比表面积和孔体积均有所降低，且孔分布向小孔方向偏移。再生后的催化剂C元素含量可降至新鲜催化剂水平，有少量的含硫物质不能通过高温再生消除，对比新鲜催化剂孔结构性质有所变化，再生后孔结构可恢复至80%左右。活性评价结果显示：柴油加氢精制失活催化剂再生后的活性能够基本恢复。

关键词: 液相加氢, 失活催化剂, S元素, C元素, 孔结构, XRF, XRD

Abstract:

To study the property changes of deactivated catalyst for liquid-phase hydrogenation of diesel and the hydrogenation performance of regenerated catalyst, the physical properties of the deactivated catalyst and regenerated catalyst are characterized by N₂ adsorption-desorption, C-S analysis, XRF, XRD techniques, and the catalytic performance of the regenerated catalyst is investigated by a small-scale evaluation device. The results show that the contents of carbon and sulfur of the deactivated catalyst are 8.37% and 9.45% respectively, the specific surface area and pore volume of the deactivated catalyst decrease, and the pore distribution shifts to the small pores. The carbon content of the regenerated catalyst is reduced to the level of fresh agent, and there is a small amount of sulfur-containing substances that cannot be eliminated by high temperature regeneration. Compared with the fresh catalyst, the pore structure of regenerated catalyst can be recovered to about 80%. The results of activity evaluation show that the activity of deactivated catalyst for diesel hydrofining can be basically recovered after regeneration.

Key words: liquid-phase hydrogenation, deactivated catalyst, S element, C element, pore structure, XRF, XRD

陈禹霏, 辛靖, 韩龙年, 于文奇, 宫祉夷, 黄宇岳, 范文轩, 张海洪 . 液相加氢失活催化剂的物理性质分析及其再生性能[J]. 炼油技术与工程, 2022, 52(9): 45-48.

Chen Yufei, Xin Jing, Han Longnian, Yu Wenqi, Gong Zhiyi, Huang Yuyue, Fan Wenxuan, Zhang Haihong . Analysis of physical properties and regeneration performance of liquid-phase hydrogenation deactivated catalyst[J]. Petroleum Refinery Engineering, 2022, 52(9): 45-48.

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