The correlation between nitrogen species in coke and NOx formation during regeneration

doi:10.1016/j.cjche.2015.12.019

Abstract

Abstract: Nitrogen oxides (NO_x) emission during the regeneration of coked fluid catalytic cracking (FCC) catalysts is an environmental issue. In order to identify the correlations between nitrogen species in coke and different nitrogencontaining products in tail gas, three coked catalystswithmultilayer structural cokemolecules were prepared in a fixed bed with model compounds (o-xylene and quinoline) at first. A series of characterization methods were used to analyze coke, including elemental analysis, FT-IR, XPS, and TG-MS. XPS characterization indicates all coked catalysts present two types of nitrogen species and the type with a higher binding energy is related with the inner part nitrogen atoms interacting with acid sites. Due to the stronger adsorption ability on acid sites for basic nitrogen compounds, the multilayer structural coke has unbalanced distribution of carbon and nitrogen atoms between the inner part and the outer edge, which strongly affects gas product formation. At the early stage of regeneration, oxidation starts from the outer edge and the product NO can be reduced to N₂ in high CO concentration. At the later stage, the inner part rich in nitrogen begins to be exposed to O₂. At this period, the formation of CO decreases due to lack of carbon atoms, which is not beneficial to the reduction of NO. Therefore, nitrogen species in the inner part of multilayer structural coke contributesmore to NO_X formation. Based on the multilayer structure model of coke molecule and its oxidation behavior, a possible strategy to control NO_X emission was discussed merely from concept.

Key words: NO_x, Basic nitrogen compounds, FCC catalyst, Coking, Reaction, Multilayer

摘要： Nitrogen oxides (NO_x) emission during the regeneration of coked fluid catalytic cracking (FCC) catalysts is an environmental issue. In order to identify the correlations between nitrogen species in coke and different nitrogencontaining products in tail gas, three coked catalystswithmultilayer structural cokemolecules were prepared in a fixed bed with model compounds (o-xylene and quinoline) at first. A series of characterization methods were used to analyze coke, including elemental analysis, FT-IR, XPS, and TG-MS. XPS characterization indicates all coked catalysts present two types of nitrogen species and the type with a higher binding energy is related with the inner part nitrogen atoms interacting with acid sites. Due to the stronger adsorption ability on acid sites for basic nitrogen compounds, the multilayer structural coke has unbalanced distribution of carbon and nitrogen atoms between the inner part and the outer edge, which strongly affects gas product formation. At the early stage of regeneration, oxidation starts from the outer edge and the product NO can be reduced to N₂ in high CO concentration. At the later stage, the inner part rich in nitrogen begins to be exposed to O₂. At this period, the formation of CO decreases due to lack of carbon atoms, which is not beneficial to the reduction of NO. Therefore, nitrogen species in the inner part of multilayer structural coke contributesmore to NO_X formation. Based on the multilayer structure model of coke molecule and its oxidation behavior, a possible strategy to control NO_X emission was discussed merely from concept.

关键词: NO_x, Basic nitrogen compounds, FCC catalyst, Coking, Reaction, Multilayer

Teng Li, Chaohe Yang, Xiaobo Chen, Libo Yao, Wei Liang, Xuemei Ding. The correlation between nitrogen species in coke and NO_x formation during regeneration[J]. Chin.J.Chem.Eng., 2016, 24(5): 606-611.

Teng Li, Chaohe Yang, Xiaobo Chen, Libo Yao, Wei Liang, Xuemei Ding. The correlation between nitrogen species in coke and NO_x formation during regeneration[J]. Chinese Journal of Chemical Engineering, 2016, 24(5): 606-611.

References

[1] G. Caeiro, A.F. Costa, H.S. Cerqueira, Nitrogen poisoning effect on the catalytic cracking of gas oil, Appl. Catal. A Gen. 320(2007) 8-15.

[2] G.Wang, Y. Liu, X.Wang, C. Xu, J. Gao, Studies on the catalytic cracking performance of coker gas oil, Energy Fuel 23(2009) 1942-1949.

[3] Q. Shi, C. Xu, S. Zhao, K.H. Chung, Y. Zhang, W. Gao, Characterization of basic nitrogen species in coker gas oils by positive-ion electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry, Energy Fuel 24(2009) 563-569.

[4] G.Wang, Z.K. Li, H. Huang, X. Lan, C.M. Xu, J.S. Gao, Synergistic process for coker gas oil and heavy cycle oil conversion for maximum light production, Ind. Eng. Chem. Res. 49(2010) 11260-11268.

[5] C.M. Fu, A.M. Schaffer, Effect of nitrogen compounds on cracking catalysts, Ind. Eng. Chem. Prod. Res. Dev. 24(1985) 68-75.

[6] J. Scherzer, D.P. McArthur, Catalytic cracking of high-nitrogen petroleum feedstocks:effect of catalyst composition and properties, Ind. Eng. Chem. Res. 27(1988) 1571-1576.

[7] A. Corma, V. Fornes, J.B. Monton, A.V. Orchilles, Catalytic cracking of alkanes on large pore, high SiO₂/Al₂O₃ zeolites in the presence of basic nitrogen compounds. Influence of catalyst structure and composition in the activity and selectivity, Ind. Eng. Chem. Res. 26(1987) 882-886.

[8] T.C. Ho, A.R. Katritzky, S.J. Cato, Effect of nitrogen compounds on cracking catalysts, Ind. Eng. Chem. Res. 31(1992) 1589-1597.

[9] R. Hughes, G. Hutchings, C. Koon, B. McGhee, C. Snape, A fundamental study of the deactivation of FCC catalysts:a comparison of quinoline and phenanthrene as catalysts poisons, Stud. Surf. Sci. Catal. 88(1994) 377-384.

[10] Z.k. Li, G. Wang, Q. Shi, C.m. Xu, J.s. Gao, Retardation effect of basic nitrogen compounds on hydrocarbons catalytic cracking in coker gas oil and their structural identification, Ind. Eng. Chem. Res. 50(2011) 4123-4132.

[11] J.O. Barth, A. Jentys, J. Lercher, On the nature of nitrogen-containing carbonaceous deposits on coked fluid catalytic cracking catalysts, Ind. Eng. Chem. Res. 43(2004) 2368-2375.

[12] Z.K. Li, J.S. Gao, G.Wang, Q. Shi, C.M. Xu, Influence of nonbasic nitrogen compounds and condensed aromatics on coker gas oil catalytic cracking and their characterization, Ind. Eng. Chem. Res. 50(2011) 9415-9424.

[13] X. Zhao, A. Peters, G.Weatherbee, Nitrogen chemistry and NO_X control in a fluid catalytic cracking regenerator, Ind. Eng. Chem. Res. 36(1997) 4535-4542.

[14] J.O. Barth, A. Jentys, J. Lercher, Elementary reactions and intermediate species formed during the oxidative regeneration of spent fluid catalytic cracking catalysts, Ind. Eng. Chem. Res. 43(12) (2004) 3097-3104.

[15] R. Bassilakis, Y. Zhao, P.R. Soloman, M.A. Serio, Sulfur and nitrogen evolution in the argonne coals:experiments and modeling, Energy Fuel 7(1993) 710-720.

[16] M.A. Wojtowicz, J.R. Pels, J.A. Moulijn, Combustion of coal as a source of N₂O emission, Fuel Process. Technol. 34(1993) 1-71.

[17] E. Furimsky, A. Siukola, A. Turenne, Effect of temperature and O₂ concentration on N-containing emissions during oxidative regeneration of hydroprocessing catalysts, Ind. Eng. Chem. Res. 35(1996) 4406-4411.

[18] J.P. Hamalainen, M.J. Aho, Effect of fuel composition on the conversion of volatile solid fuel-N to N₂O and NO, Fuel 74(12) (1994) 1922-1924.

[19] T.P. Kobylinski, B.W. Taylor, The catalytic chemistry of nitric oxide. I. The effect of water on the reduction of nitric oxide over supported chromium and iron oxides, J. Catal. 31(450-458) (1973).

[20] T.P. Kobylinski, B.W. Taylor, The catalytic chemistry of nitric oxide. II. Reduction of nitric oxide over noble metal catalysts, J. Catal. 33(1974) 376-384.

[21] X. Chu, L.D. Schmidt, Intrinsic rates of NO_x-carbon reactions, Ind. Eng. Chem. Res. 32(1993) 1359-1366.

[22] A.W. Peters, G.D. Weatherbee, X. Zhao, Origin of NO_x in the FCCU regenerator, Fuel Reformulation 5(3) (1995) 45-50.

[23] A.W. Peters, M. Koranne, C. Pereira, G.D. Weatherbee, X. Zhao, J. Haley, S. Davey, B. Lakhanpal, Control and origin of NO_x in the FCCU regenerator, ACS AnnualMeeting, Orlando, FL, 1996.

[24] R. Mann, Fluid catalytic cracking:some recent developments in catalyst particle design and unit hardware, Catal. Today 18(1993) 509-528.

[25] R.B. Miller, T.E. Johnson, C.R. Santner, A.A. Avidan, J.H. Beech, Comparison between single and two-stage FCC regenerators, Proceedings of the 1996 Annual NPRAMeeting, San Antonio, Texas, 1996.

[26] S. Lin, K. Wang, G. Jia, J. Shi, J. Zhang, G. Yang, The kinetics of coke deposition and regeneration of catalysts, Acta Pet. Sin. S1(1982) 93-102.

[27] G. Caeiro, J.M. Lopesa, P.Magnoux, A FT-IR study of deactivation phenomena during methylcyclohexane transformation on H-USY zeolites:nitrogen poisoning, coke formation, and acidity-activity correlations, J. Catal. 249(2007) 234-243.

[28] H.S. Cerqueira, P. Ayrault, J. Datka, m-Xylene transformation over a USHY zeolite at 523 and 723 K:influence of coke deposits on activity, acidity, and porosity, J. Catal. 196(1) (2000) 149-157.

[29] J. Abbot, Role of Brønsted and Lewis acid sites during cracking reactions of alkane, Appl. Catal. 47(1) (1989) 33-44.

[30] J. Abbot, F. Guerzoni, Roles of Brønsted and Lewis sites during cracking of n-octane on H-mordenite, Appl. Catal. A Gen. 85(2) (1992) 173-188.

[31] S.M. Babitz,M.A. Kuehne, H.H. Kung, J.T.Miller, Role of Lewis acidity in the deactivation of USY zeolites during 2-methylpentane cracking, Ind. Eng. Chem. Res. 36(8) (1997) 3027-3031.

[32] A. Vimont, F. Thibault-Starzyk, J. Lavalley, Structural Lewis sites in zeolite beta-role on coking of the catalyst, Stud. Surf. Sci. Catal. 130(2000) 2963-2968.

[33] K. Qian, D.C. Tomczak, E.F. Rakiewicz, Coke formation in the fluid catalytic cracking process by combined analytical techniques, Energy Fuel 11(1997) 596-601.

[34] J. Huang, Application of FCC 2-stage regeneration in China, Pet. Process. Petrochem. 35(4) (2004) 34-40.

[35] S. Yan, Staked two-stage regeneration technology in heavy oil FCCU, Pet. Process. Petrochem. 33(8) (2002) 7-9.

The correlation between nitrogen species in coke and NO_x formation during regeneration

The correlation between nitrogen species in coke and NO_x formation during regeneration

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	Ming Liu, Ying Li, Rui Wang, Guoqiang Shao, Pengpeng Lv, Jun Li, Qingshan Zhu. Uniform deposition of ultra-thin TiO₂ film on mica substrate by atmospheric pressure chemical vapor deposition: Effect of precursor concentration [J]. Chinese Journal of Chemical Engineering, 2023, 60(8): 99-107.
[2]	Yifan Jiang, Bingqi Xie, Jisong Zhang. Highly reactive and reusable heterogeneous activated carbons-based palladium catalysts for Suzuki-Miyaura reaction [J]. Chinese Journal of Chemical Engineering, 2023, 60(8): 165-172.
[3]	Haixiang Liu, Jun Zhang, Chunlei Dong, Gang Zhu, Guanben Du, Shuduan Deng. Synthesis, performance and structure characterization of glyoxal-monomethylolurea-melamine (G-MMU-M) co-condensed resin [J]. Chinese Journal of Chemical Engineering, 2023, 59(7): 92-104.
[4]	Xun Tao, Fan Zhou, Xinlei Yu, Songling Guo, Yunfei Gao, Lu Ding, Guangsuo Yu, Zhenghua Dai, Fuchen Wang. Effect of carbon dioxide on oxy-fuel combustion of hydrogen sulfide: An experimental and kinetic modeling [J]. Chinese Journal of Chemical Engineering, 2023, 59(7): 105-117.
[5]	Zhonghao Li, Yuanyuan Yang, Huanong Cheng, Yun Teng, Chao Li, Kangkang Li, Zhou Feng, Hongwei Jin, Xinshun Tan, Shiqing Zheng. Measurement and model of density, viscosity, and hydrogen sulfide solubility in ferric chloride/trioctylmethylammonium chloride ionic liquid [J]. Chinese Journal of Chemical Engineering, 2023, 59(7): 210-221.
[6]	Pengcheng Zou, Kai Wang. Methanolysis of amides under high-temperature and high-pressure conditions with a continuous tubular reactor [J]. Chinese Journal of Chemical Engineering, 2023, 58(6): 170-178.
[7]	Xinyu Liu, Hongliang Sheng, Song He, Chunhua Du, Yuansheng Ma, Chichi Ruan, Chunxiang He, Huaming Dai, Yajun Huang, Yuelei Pan. Insight into pyrolysis of hydrophobic silica aerogels: Kinetics, reaction mechanism and effect on the aerogels [J]. Chinese Journal of Chemical Engineering, 2023, 58(6): 266-281.
[8]	Bin Lin, Wenyao Chen, Nan Song, Zhihua Zhang, Qianhong Wang, Wei Du, Xinggui Zhou, Xuezhi Duan. Mechanistic insights into propylene oxidation to acrolein over gold catalysts [J]. Chinese Journal of Chemical Engineering, 2023, 57(5): 39-49.
[9]	Hu Chen, Ying Wang, Puyu Wang, Yongkang Lv. Assessing quinoline removal performances of an aerobic continuous moving bed biofilm reactor (MBBR) bioaugmented with Pseudomonas citronellolis LV1 [J]. Chinese Journal of Chemical Engineering, 2023, 57(5): 132-140.
[10]	Qi Yang, Weikang Dai, Maoshuai Li, Jie Wei, Yi Feng, Cheng Yang, Wanxin Yang, Ying Zheng, Jie Ding, Mei-Yan Wang, Xinbin Ma. Enhanced selective hydrogenation of glycolaldehyde to ethylene glycol over Cu⁰-Cu⁺ sites [J]. Chinese Journal of Chemical Engineering, 2023, 57(5): 141-150.
[11]	Yu Wang, Qunfeng Zhang, Xinlei Liu, Junqi Weng, Guanghua Ye, Xinggui Zhou. Probing deactivation by coking in catalyst pellets for dry reforming of methane using a pore network model [J]. Chinese Journal of Chemical Engineering, 2023, 55(3): 293-303.
[12]	Libing Yu, Qiuyan Huang, Jing Wu, Erhong Song, Beibei Xiao. Spatial-five coordination promotes the high efficiency of CoN₄ moiety in graphene-based bilayer for oxygen reduction electrocatalysis: A density functional theory study [J]. Chinese Journal of Chemical Engineering, 2023, 54(2): 106-113.
[13]	Yilin Song, Yize Zhang, Hao Zhou. Experimental study on the desulfurization and evaporation characteristics of Ca(OH)₂ droplets [J]. Chinese Journal of Chemical Engineering, 2023, 54(2): 127-135.
[14]	Xianglin Liu, Minjie Xu, Chenxi Cao, Zixu Yang, Jing Xu. Effects of zinc on χ-Fe₅C₂ for carbon dioxide hydrogenation to olefins: Insights from experimental and density function theory calculations [J]. Chinese Journal of Chemical Engineering, 2023, 54(2): 206-214.
[15]	Zhiwei Wang, Yu Zhang, Zhi Zhang, Daowei Zhou, Zhikai Cao, Yong Sha. Investigation on catalytic distillation for ethyl acetate production with different catalytic packing structures [J]. Chinese Journal of Chemical Engineering, 2023, 53(1): 63-72.