Research progress on deactivation of fixed bed residue hydrogenating catalysts at the initial stage of operation

doi:10.16085/j.issn.1000-6613.2017-0811

Abstract

Abstract: Fixed bed residue hydrogenating technology is a vital way of heavy oil upgrading,but the deactivation of catalysts restricts the operation cycle of the plant,which affects the overall economic benefits of the refinery.At the early stage of operation in residue hydrogenating process,a large number of coke formed on the catalysts' surface leads to the rapid deactivation of the catalysts,the properties of the coke,the factors affecting the formation of carbon deposits and the methods of inhibiting the carbon deposition are discussed in this paper.The coke is divided into soft and refractory coke on the catalysts' surface,mainly the soft coke at the initial stage of operation;the coke is mainly deposited on the outside of the catalysts that results in the migration of pore diameter to the micropore and decreasing the utilization of the active site in the pore;The properties of the residue,the catalyst properties and the process conditions together determine the formation of the coke at the initial stage of operation,but the coke may be inhibited by optimizing these factors.It is of great significance for the rational use of the catalysts,the extension of the operation cycle and the reduction of refinery production cost.

Key words: residue hydrogenation, fixed bed, catalyst, deactivation, the initial stage of operation

摘要： 固定床渣油加氢技术是重油改质的重要手段，而催化剂失活制约着装置运行周期，影响炼厂整体经济效益。渣油加氢过程中，运转初期形成的大量积炭是催化剂快速失活的重要原因。本文主要介绍了运转初期催化剂表面形成积炭的性质、影响积炭形成的因素以及控制积炭的方法等。积炭分为软炭和硬炭，运转初期催化剂表面沉积的积炭以软炭为主，积炭更多地沉积在催化剂外侧，造成孔径向小孔范围迁移，降低孔内活性位利用率；原料油性质、催化剂性质及工艺条件共同决定着催化剂运转初期积炭形成，通过改善原料油性质，优化催化剂及工艺条件可以有效地抑制积炭形成。这对合理使用催化剂，延长装置运转周期及降低炼厂生产成本具有重要意义。

关键词: 渣油加氢, 固定床, 催化剂, 失活, 运转初期

CLC Number:

TE624

HAN Kunpeng, DAI Lishun, NIE Hong. Research progress on deactivation of fixed bed residue hydrogenating catalysts at the initial stage of operation[J]. Chemical Industry and Engineering Progress, 2017, 36(S1): 211-220.

韩坤鹏, 戴立顺, 聂红. 固定床渣油加氢催化剂运转初期失活规律研究进展[J]. 化工进展, 2017, 36(S1): 211-220.

References

[1] 史昕,邹劲松,厉荣.炼油发展趋势对加氢能力及加氢技术的影响[J].当代石油化工,2014,237(9):1-5. SHI Xin,ZOU Jinsong,LI Rong.The influence of refining development trends up on hydrogenation capacity and hydrogenation technology[J].Petroleum&Petrochemical Today,2014,237(9):1-5.
[2] 聂红,杨清河,戴立顺,等.重油高效转化关键技术的开发及应用[J].石油炼制与化工,2012,43(1):1-6. NIE Hong,YANG Qinghe,DAI Lishun,et al. Development and commercial application of key technology for efficient conversion of heavy oil[J].Petroleum Processing and Petrochemicals,2012,43(1):1-6.
[3] 李大东.加氢处理工艺与工程[M].北京:中国石化出版社,2004. LI Dadong.Hydrotreating process and engineering[M]. Beijing:Sinopec Press,2004.
[4] VOGELAAR B M,EIJSBOUT S,BERGWERFF J A,et al.Hydroprocessing catalyst deactivation in commercial practice[J].Catalysis Today,2010,154(3/4):256-263.
[5] 曾松.固定床渣油加氢催化剂失活的原因分析及对策[J].炼油技术与工程,2011,41(9):39-43. ZENG Song.Causes of deactivation of fixed-bed residue hydrotreating catalysts and countermeasures[J].Petroleum Refinery Engineering,2011,41(9):39-43.
[6] ABSI-HALABI M,STANISLAUS A,TRIMM D L.Coke formation on catalysts during the hydroprocessing of heavy oils[J].Applied Catalysis,1991,72(2):193-215.
[7] MARAFI A,HAUSER A,STANISLAUS A.Deactivation patterns of Mo/Al₂O₃,Ni-Mo/Al₂O₃and Ni-MoP/Al₂O₃ catalysts in atmospheric residue hydrodesulphurization[J]. Catalysis Today,2007,125(3/4):192-202.
[8] 安晟,王志武,王欣.渣油加氢处理催化剂失活研究[J].当代化工,2010,39(1):49-51. AN Cheng,WANG Zhiwu,WANG Xin.Study on deactivation of residue hydrotreating catalyst[J]. Contemporary Chemical Industry,2010,39(1):49-51.
[9] 常杰.渣油加氢处理反应动力学及失活模型的研究[D].北京:石油化工科学研究院,1997. CHANG Jie.Study on reaction kinetics and deactivation model of residue hydrotreating[D].Beijing:Research Institute of Petroleum Processing,1997.
[10] OELDERIK J M,SIE S T,BODE D.Progress in the catalysis of the upgrading of petroleum residue:a review of 25 years of R&D on shell's residue hydroconversion technology[J].Applied Catalysis,1989,47(1):1-24.
[11] HAUSER A,STANISLAUS A,MARAFI A,et al.Initial coke deposition on hydrotreating catalysts.PartⅡ.Structure elucidation of initial coke on hydrodematallation catalysts[J]. Fuel,2005,84(2/3):259-269.
[12] 常杰,戴立顺,刘建生,等.渣油加氢脱金属催化剂初期失活的研究[J].石油炼制与化工,1997,28(12):25-28. CHANG Jie,DAI Lishun,LIU Jiansheng,et al.Initial deactivation of HDM catalysts with residual feedstocks[J]. Petroleum Processing and Petrochemicals,1997,28(12):25-28.
[13] 陈士锋,杨朝合.渣油加氢转化催化剂初期结焦规律的研究[J].燃料化学学报,2001,29(5):395-400. CHEN Shifeng,YANG Chaohe.Studies of initial coke formation on residual hydroconversion catalyst[J].Journal of Fuel Chemistry and Technology,2001,29(5):395-400.
[14] CALLEJAS M A,MARTINEZ M T,BLASCO T,et al. Coke characterization in aged residue hydrotreating catalysts by solid-state¹³C-NMR spectroscopy and temperature-programmmed oxidation[J].Applied Catalysis A:General,2001,218(1/2):181-188.
[15] MARAFI M,STANISLAUS A.Effect of initial coking on hydrotreating catalyst functionalities and properties[J]. Applied Catalysis A:General,1997,159(1/2):259-267.
[16] FURIMSKY E,MASSOTH F E.Deactivation of hydroprocessing catalysts[J].Catalysis Today,1999,52(4):381-495.
[17] THAKUR D S,THOMAS M G.Catalyst deactivation during direct coal liquefaction:a review[J]. Ind. Eng. Chem.Prod.Res.Dev.,1983,23(4):349-360.
[18] MARFI A,HAUSER A,STANISLAUS A.Deactivation patterns of Mo/Al₂O₃ and Ni-MoP/Al₂O₃ catalysts in atmospheric residue hydrodesulphurization[J].Applied Catalysis A:General,2001,218(1/2):192-202.
[19] 刘勇军,邹瑜.渣油加氢脱金属催化剂的积炭分析[J].华侨大学学报(自然科学版),2014,35(2):180-185. LIU Yongjun,ZOU Yu.Analysis of the coking of residue hydrodemetallization catalyst[J].Journal of Huaqiao University(Natural Science),2014,35(2):180-185.
[20] 陈士锋,陈海,杨朝合.渣油加氢转化过程结焦催化剂的表征[J].石油学报(石油加工),2002,18(3):8-13. CHEN Shifeng,CHEN Hai,YANG Chaohe. Characterization of coked catalyst for residual hydroconversion process[J].Acta Petrolei Sinica(Petroleum Processing Section)2002,18(3):8-13.
[21] 张会成,马波,李景斌,等.渣油加氢处理催化剂积炭分析[J].当代化工,2008,37(3):277-283. ZHANG Huicheng,MA Bo,LI Jingbin,et al.Analysis of coke on spent catalysts used for residue hydrotreating process[J].Contemporary Chemical Industry,2008,37(3):277-283.
[22] MATSUSHITA K,HAUSER A,MARAFI A,et al. Initial coke deposition on hydrotreating catalysts.Part 1.Changes in coke properties as a function of time on strean[J].Fuel,2004,83(7/8):1031-1038.
[23] RICHARDSON S M,NAGAISHI H,GRAY M R.Initial coke deposition on a NiMo/γ-Al₂O₃ bitumen hydroprocessing catalyst[J].Industrial & Engineering Chemistry Research,1996,35(11):3940-3950.
[24] 崔瑞利,赵愉生,于双林,等.渣油加氢脱残炭催化剂的失活研究[J].石油化工,2013,42(4):411-414. CUI Ruili,ZHAO Yusheng,YU Shuanglin,et al. Deactivation of catalyst for removing residue carbon in hydrotreating residual oil[J].Petrochemical Technology,2013,42(4):411-414.
[25] GUICHARD B,ROY-AUBERGER M,DEVERS E,et al. Characterization of aged hydrotreating catalysts.PartⅠ:Coke depositions,study on the chemical nature and environment[J].Applied Catalysis A:General,2009,367(1/2):1-8.
[26] SEKI H,KUMATA F.Structural change of petroleum asphaltenes and resins by hydrodemetallization[J].Energy Fuels,2000,14(5):980-985.
[27] GRAY M R,ZHAO Y,MCKNIGHT C M,et al.Coking of hydrocessing catalyst by residue fractions of bitumen[J]. Energy&Fuels,1999,13(5):1037-1045.
[28] GAWEL I,BOCIARSKA D,BISKUPSKI P.Effect of asphaltenes on hydroprocessing of heavy oils and residua[J]. Applied Catalysis A:General,2005,295(1):89-94.
[29] 林建飞,胡大为,杨清河.固定床渣油加氢催化剂表面积炭及抑制研究进展[J].化工进展,2015,34(12):4229-4237. LIN Jianfei,HU Dawei,YANG Qinghe.Research progress of coke deposition and inhibition on fixed bed residue hydrogenating catalysts[J].Chemical Industry and Engineering Progress,2015,34(12):4229-4237.
[30] 张会成,颜涌捷,齐邦峰,等.渣油加氢处理过程中氮分布与脱除规律的研究[J].石油炼制与化工,2007,38(4):43-47. ZHANGH Huicheng,YAN Yongjie,QI Bangfeng,et al.Study on the nitrogen distribution and removal during residue hydrotreating[J].Petroleum Processing and Petrochemicals,2007,38(4):43-47.
[31] FURIMSKY.Thermochemical and mechanistic aspects of removal of sulphur,nitrogen and oxygen from petroleum[J].Erdol Und Kohle Erdgas Petrochemie,1983,87(7):1028-1034.
[32] 孙昱东,杨朝合,山红红,等.渣油加氢催化剂构型失活因素综述[J].石化技术与应用,2009,27(5):464-469. SUN Yudong,YANG Chaohe,SHAN Honghong,et al. Review on factors of residue hydrogenation catalyst configuration deactivation[J].Petrochemical Technology &Application,2009,27(5):464-469.
[33] 于双林,张龙力,杨朝合,等.氢初压对渣油加氢产物胶体稳定性的影响及原因分析[J].石化技术与应用,2010,28(2):96-100. YU Shuanglin,ZHANG Longli,YANG Chaohe,et al. Effect of hydrogen initial pressure on the colloidal stability of hydrotreating residuum[J].Petrochemical Technology & Application,2010,28(2):96-100.
[34] 朱英娣.渣油胶体稳定性与热反应生焦性能的关系研究[D]. 沈阳:辽宁石油化工大学,2011. ZHU Yingdi.Relation between colloid stability of residuum and coke formation during thermal reation[D].Shenyang:Liaoning University of Petroleum & Chemical Technology,2011.
[35] 于双林.渣油加氢体系胶体性质的研究[D].青岛:中国石油大学(华东),2010. YU Shuanglin.Study on the colloidal properties of residue hydroprocessing system[D].Qingdao:China University of Petroleum(East China),2010.
[36] 程之光.重油加工技术[M].北京:中国石化出版社,1994. CHENG Zhiguang.Heavy oil processing technology[M]. Beijing:Sinopec Press,1994.
[37] 安晟.渣油加氢处理催化剂焦炭和金属沉积规律的研究[D]. 沈阳:辽宁石油化工大学,2009. AN Cheng.Study on coke and metal deposition on residue hydrotreating catalyst[D].Shenyang:Liaoning University of Petroleum & Chemical Technology,2009.
[38] GUALDAL G,KASZTELAN S.Initial deactivation of residue hydrodemetallizaition Catalysts[J].Journal of Catalysis,1995,161(1):319-337.
[39] 聂红,李明丰,高晓冬,等.石油炼制中的加氢催化剂和技术[J].石油学报(石油加工),2010(s1):77-81. NIE Hong,LI Mingfeng,GAO Xiaodong,et al. Hydrogenation catalyst and technology in petroleum processing[J].Acta Petrolei Sinica(Petroleum Processing Section),2010(s1):77-81.
[40] 牛传峰.不同芳香性重馏分油对渣油加氢过程影响的研究[D].北京:石油化工科学研究院,2001. Niu Chuanfeng.Effect of aromatic heavy gas oil on residue hydrotreating reactions[D].Beijing:Research Institute of Petroleum Processing,2001.
[41] 牛传峰,张瑞弛,戴立顺,等.渣油加氢-催化裂化双向组合技术RICP[J].石油炼制与化工,2002,33(1):27-29. NIU Chuanfeng,ZHANG Ruichi,DAI Lishun,et al.A new integration process of residue hydrotreating combined with catalytic cracking[J].Petroleum Processing and Petrochemicals,2002,33(1):27-29.
[42] CLARKE P F,PRUDEN B B.Asphaltene precipition:Detection using heat transfer analysis,and inhibition using chemical additives[J].Fuel,1997,76(7):607-614.
[43] OH K,RING T A,DEO M D.Asphaltene aggregation in organic solvents[J].Journal of Colloid and Interface Science,2004,271(1):212-219.
[44] CHANG C L,FOGLERH S.Stabilization of asphaltenes in aliphatic solvents using alkybenzene-derived amphiphiles Ⅰ. Effect of the chemical structure of amphiphiles on asphaltene stabilizaition[J].Journal of Petroleum Science and Engeering,2001,32(3):201-216.
[45] DA SILVA RAMOS A C,HARAGUCHI L,NOTRISPE F R,et al.Interfacial and colloidal behavior of asphaltenes obtained from Brazilian crude oils[J].Journal of Petroleum Science & Engeering,2001,32(2/4):201-216.
[46] ROCHA JUNIOR L C,FERREIRA M S,DA SILVA RAMOS A C.Inhibition of asphaltene precipition in Brazilian crude oils using new oil soluble amphiphiles[J].Journal of Petroleum Science and Engineering,2006,51(1/2):26-36.
[47] 张涛,臧景龄,胡爱华,等.锂对于γ-Al₂O₃表面酸性中心的调变及其积炭性的影响[J].催化学报,1990,11(5):341-347. ZHANG Tao,ZANG Jingling,HU Aihua,et al.Effect of lithium on the acidic property of γ-Al₂O₃ and its carbon deposition[J].Catalysis,1990,11(5):341-347.
[48] 沈志虹,潘惠芳,徐春生.镁对γ-Al₂O₃表面酸性及积炭性能的影响[J].石油大学学报(自然科学版),1995,19(3):79-82. SHEN Zhihong,PAN Huifang,XU Chunsheng.Effect of magnesium on the acidity and coking of γ-Al₂O₃[J].Journal of the University of Petroleum(Natural Science),1995,19(3):79-82.
[49] RICHARDON S M,GRAY M R.Enhancement of residue hydroprocessing catalysts by doping with alkli metals[J]. Energy&Fuels,1997,11(6):1119-1126.
[50] 胡大为,杨清河,聂红.活性氧化铝载体的扩孔及改性[J].石油炼制与化工,2004,35(8):46-49. HU Dawei,YANG Qinghe,NIE Hong.Pore enlarging and modification of alumina carrier[J].Petroleum Processing and Petrochemicals,2004,35(8):46-49.
[51] GUO Rong,SHEN Benxian,FANG Xiangchen,et al. Study on relationship between microstructure of active phase and HDS performance of sulfide Ni-Mo catalysts:effect of metal loading[J]. China Petroleum Processing and Petrochemical Technology,2014,16(2):12-19.
[52] 韩保平,晋梅.渣油加氢装置反应温度操作初探[J].石油炼制与化工,2003,34(8):16-19. HAN Baoping,JIN Mei.Prelimilary exploration on handling reaction temperature of residue hydrotreating unit[J]. Petroleum Processing and Petrochemicals,2003,34(8):16-19.
[53] 董凯,戴立顺,贾燕子,等.仪长渣油加氢处理反应规律的研究Ⅱ.新型催化剂及工艺条件的影响[J].石油炼制与化工,2015,46(2):7-11. DONG Kai,DAI Lishun,JIA Yanzi,et al.Study on hydrotreating reactivity of yichanag residue Ⅱ.Catalyst and operation conditions[J].Petroleum Processing and Petrochemicals,2015,46(2):7-11.