工艺条件对裂解汽油加氢脱噻吩反应的影响

乙烯工业 ›› 2020, Vol. 32 ›› Issue (2): 16-18.

工艺条件对裂解汽油加氢脱噻吩反应的影响

董万军，史云伟，赵伟奇

中国石油四川石化有限责任公司，四川成都 611930

收稿日期:2019-05-09 修回日期:2019-10-16 出版日期:2020-06-25 发布日期:2020-07-02
作者简介:董万军，男，2010年毕业于大连理工大学化学工程专业，主要从事技术生产工作，工程师。

Influence of Process Conditions on Thiophene Removal Reaction of Pyrolysis Gasoline by Hydrogenation

Dong Wanjun, Shi Yunwei, Zhao Weiqi,Wang Shengwei

PetroChina Sichuan Petrochemical Company Limited, Chengdu, Sichuan, P.C.611930

Received:2019-05-09 Revised:2019-10-16 Online:2020-06-25 Published:2020-07-02

摘要/Abstract

摘要：

作为重要的基础化学品之一，石油苯的工业生产过程在芳烃抽提装置实现，其大部分原料来自裂解汽油加氢装置，约占石油苯产品的50％以上。随着化学工业水平的快速发展，化工市场对苯产品的硫含量要求越来越高，苯产品中硫形态主要以噻吩的形式存在，可以用总硫含量近似表征产品中噻吩含量。因噻吩与苯的物理性质类似，工业生产中很难以精馏的方式将二者分离，大部分以加氢脱硫方式实现。通过分析裂解汽油加氢脱噻吩化学反应过程，对比不同工艺条件下加氢汽油产品中的总硫含量，得出在现有技术及工艺条件下能够满足产品中硫含量的最佳操作条件。

关键词: 工艺条件 , , 裂解汽油 , , 加氢脱噻吩 , , 影响

Abstract:

Petroleum benzene is one of the important basic chemicals, and its industrial production process is realized in aromatics extraction unit. Most of its raw materials come from pyrolysis gasoline hydrogenation unit, accounting for more than 50% of petroleum benzene products. With the rapid development of the chemical industry, the requirements for sulfur content of benzene products in chemical market become higher and higher. Sulfur exists in benzene products mainly in the form of thiophene, and the thiophene content of products can be approximately characterized by total sulfur content. Because the physical properties of thiophene and benzene are similar, it is difficult to separate them by distillation in industrial production, and hydrodesulfurization is mostly adopted. By analyzing the chemical reaction process of thiophene removal of pyrolysis gasoline by hydrogenation and comparing the total sulfur content of hydrogenated gasoline products under different process conditions, the optimal operating conditions that can meet the sulfur content of products with the existing technologies and process conditions are obtained.

Key words: process condition, pyrolysis gasoline, thiophene removal by hydrogenation, influence

董万军, 史云伟, 赵伟奇. 工艺条件对裂解汽油加氢脱噻吩反应的影响[J]. 乙烯工业, 2020, 32(2): 16-18.

Dong Wanjun, Shi Yunwei, Zhao Weiqi, Wang Shengwei. Influence of Process Conditions on Thiophene Removal Reaction of Pyrolysis Gasoline by Hydrogenation[J]. Ethylene Industry, 2020, 32(2): 16-18.

[1]	赵百仁, 王振维, 盛在行. 乙烷逐步替代石脑油对乙烯装置的影响[J]. 乙烯工业, 2020, 32(3): 1-6.
[2]	范士平. 乙烯装置停开车减排方案优化[J]. 乙烯工业, 2020, 32(3): 7-12.
[3]	黄登胜, 史长洪, 马俊, 蒋晓勇. 脱乙烷塔系统存在的问题及优化[J]. 乙烯工业, 2020, 32(3): 13-15.
[4]	李智源, 马俊, 尚永福, 丁璐, 马利凡. 乙烯装置节能减排优化分析[J]. 乙烯工业, 2020, 32(3): 16-18.
[5]	王晨宇, 董亚龙, 任崇欣, 马俊, 游笑辉. 原料轻质化对裂解气压缩机的影响及优化措施[J]. 乙烯工业, 2020, 32(3): 19-21.
[6]	蒋鹏飞, 宿伟毅, 罗灵力, 谷阳, 洪琨. 裂解炉长周期运行中的问题及优化措施[J]. 乙烯工业, 2020, 32(3): 22-28.
[7]	代兵, 王平, 王小瑞, 杨雪. SCR脱硝技术在裂解炉上的应用分析[J]. 乙烯工业, 2020, 32(3): 29-34.
[8]	芦丹. 裂解炉弯头箱的结构设计[J]. 乙烯工业, 2020, 32(3): 35-38.
[9]	任崇欣、叶明鹭、王喜旺、董志全、康鸿才. 裂解炉机械清焦及化学清洗节能分析[J]. 乙烯工业, 2020, 32(3): 39-41.
[10]	刘曼. 裂解炉辐射段衬里设计与失效原因分析[J]. 乙烯工业, 2020, 32(3): 42-45.
[11]	李德龙. 乙烯装置裂解炉节能降耗措施研究与实施[J]. 乙烯工业, 2020, 32(3): 46-49.
[12]	赵贵才. 提高压缩机油路系统可靠性的措施[J]. 乙烯工业, 2020, 32(3): 50-53.
[13]	张建华. 裂解气压缩机氮气运行模拟核算及应用研究[J]. 乙烯工业, 2020, 32(3): 54-56.
[14]	王生伟, 张迎春, 刘源波, 刘军, 魏哲如. 裂解气压缩机段间换热器堵塞在线处理[J]. 乙烯工业, 2020, 32(3): 57-60.
[15]	刘晓晖, 张迪, 刘东. 裂解气压缩机透平振动异常分析及对策[J]. 乙烯工业, 2020, 32(3): 61-64.