Synthesis and mechanism analysis of a new oil soluble viscosity reducer for flow improvement of Chenping heavy oil

doi:10.1016/j.cjche.2021.04.029

Abstract

Abstract: Oil soluble viscosity reducers have gradually attracted the attention of petrochemical research due to their cleanliness and high efficiency. Considering the high viscosity and non-Newtonian fluid properties of Chenping heavy oil found in China, a series of new oil soluble viscosity reducers with different proportions and molecular weights were prepared by free radical polymerization using octadecyl acrylate, 2-allylphenol and N-methylolacrylamide as monomers. The viscosity reducer was applied to different types of heavy oil and found that it exhibited a better effect on heavy oils with high asphaltene content. The test of rheological behavior of heavy oil with additive was performed at wide range of shear rate (3–90 s^-1) and temperature range (30–100 ℃). The apparent viscosity reduction rate was up to 70.09%, which was better than the industrially relevant ethylene–vinyl acetate copolymer under the same test condition. In addition, the effect of viscosity reducers on the components of heavy oil and the energy change of the system simulated by molecular dynamics simultaneously was investigated. The consistency of the simulated and experimental results show that the effect of viscosity reduction closely related to the crystallization process of wax and the viscosity reducer can reconstruct the surface structure of asphaltene and diminish the connection of benzene ring.

Key words: Heavy oil, Viscosity reduction, Asphaltene, Non-Newtonian fluid

摘要： Oil soluble viscosity reducers have gradually attracted the attention of petrochemical research due to their cleanliness and high efficiency. Considering the high viscosity and non-Newtonian fluid properties of Chenping heavy oil found in China, a series of new oil soluble viscosity reducers with different proportions and molecular weights were prepared by free radical polymerization using octadecyl acrylate, 2-allylphenol and N-methylolacrylamide as monomers. The viscosity reducer was applied to different types of heavy oil and found that it exhibited a better effect on heavy oils with high asphaltene content. The test of rheological behavior of heavy oil with additive was performed at wide range of shear rate (3–90 s^-1) and temperature range (30–100 ℃). The apparent viscosity reduction rate was up to 70.09%, which was better than the industrially relevant ethylene–vinyl acetate copolymer under the same test condition. In addition, the effect of viscosity reducers on the components of heavy oil and the energy change of the system simulated by molecular dynamics simultaneously was investigated. The consistency of the simulated and experimental results show that the effect of viscosity reduction closely related to the crystallization process of wax and the viscosity reducer can reconstruct the surface structure of asphaltene and diminish the connection of benzene ring.

关键词: Heavy oil, Viscosity reduction, Asphaltene, Non-Newtonian fluid

Yaqi Ren, Shuqian Xia. Synthesis and mechanism analysis of a new oil soluble viscosity reducer for flow improvement of Chenping heavy oil[J]. Chinese Journal of Chemical Engineering, 2022, 45(5): 58-67.

Yaqi Ren, Shuqian Xia. Synthesis and mechanism analysis of a new oil soluble viscosity reducer for flow improvement of Chenping heavy oil[J]. 中国化学工程学报, 2022, 45(5): 58-67.

References

[1] S.W. Hasan, M.T. Ghannam, N. Esmail, Heavy crude oil viscosity reduction and rheology for pipeline transportation, Fuel 89 (5) (2010) 1095-1100
[2] R. Martinez-Palou, R. Ceron-Camacho, B. Chavez, A.A. Vallejo, D. Villanueva-Negrete, J. Castellanos, J. Karamath, J. Reyes, J. Aburto, Demulsification of heavy crude oil-in-water emulsions:A comparative study between microwave and thermal heating, Fuel 113 (2013) 407-414
[3] D. Pradilla, J. Ramirez, F. Zanetti, O. Alvarez, Demulsifier Performance and Dehydration Mechanisms in Colombian Heavy Crude Oil Emulsions, Energy Fuel 31 (10) (2017) 10369-10377
[4] J. Liu, H. Wang, X. Li, W. Jia, Y. Zhao, S. Ren, Recyclable magnetic graphene oxide for rapid and efficient demulsification of crude oil-in-water emulsion, Fuel 189 (2017) 79-87
[5] C.E. McGlade, A review of the uncertainties in estimates of global oil resources, Energy 47 (1) (2012) 262-270
[6] R. Guseo, Worldwide cheap and heavy oil productions:A long-term energy model, Energy Policy 39 (9) (2011) 5572-5577
[7] G.A. Mansoori, Modeling of asphaltene and other heavy organic depositions, J. Pet. Sci. Eng. 17 (1997) 101-111
[8] I.A. Wiehe, R.J. Kennedy, The Oil Compatibility Model and Crude Oil Incompatibility, Energy Fuel 14 (1) (2000) 56-59
[9] Y. Li, H. Gao, W. Pu, B. Wei, Y. Chen, D. Li, Q. Luo, Viscosity profile prediction of a heavy crude oil during lifting in two deep artesian wells, Chin. J. Chem. Eng. 25 (7) (2017) 976-982
[10] X. Yang, W. Li, A novel theoretical approach to the temperature-viscosity relation for fluidic fuels, Fuel 153 (2015) 85-89
[11] M.D. Garcia, L. Carbognani, Asphaltene Paraffin Structural Interactions. Effect on Crude Oil Stability, Energy Fuel 15 (5) (2001) 1021-1027
[12] J.A. Dehkordi, A. Jafari, S.A. Sabet, F. Karami, Kinetic studies on extra heavy crude oil upgrading using nanocatalysts by applying CFD techniques, Chin. J. Chem. Eng. 26(2) (2018) 131-143
[13] M.T. Ghannam, S.W. Hasan, B. Abu-Jdayil, N. Esmail, Rheological properties of heavy & light crude oil mixtures for improving flowability, J. Pet. Sci. Eng. 81 (2012) 122-128
[14] R. Martinez-Palou, M.D. Mosqueira, B. Zapata-Rendon, E. Mar-Juarez, C. Bernal-Huicochea, J.D. Clavel-Lopez, J. Aburto, Transportation of heavy and extra-heavy crude oil by pipeline:A review, J. Pet. Sci. Eng. 75 (3-4) (2011) 274-282
[15] A.R. Kovscek, Emerging challenges and potential futures for thermally enhanced oil recovery, J. Pet. Sci. Eng. 98-99 (2012) 130-143
[16] B. Yao, C. Li, F. Yang, J. Sjoblom, Y. Zhang, J. Norrman, K. Paso, Z. Xiao, Organically modified nano-clay facilitates pour point depressing activity of polyoctadecylacrylate, Fuel 166 (2016) 96-105
[17] S. Deshmukh, D.P. Bharambe, Synthesis of polymeric pour point depressants for Nada crude oil (Gujarat, India) and its impact on oil rheology, Fuel Process. Technol. 89 (3) (2008) 227-233
[18] P. Ghosh, S. Yeasmin, Polymer blend:a new approach towards flow improvement of crude oil, Petrol Sci Technol 38 (3) (2020) 177-184
[19] Y. Yang, J. Guo, Z. Cheng, W. Wu, J. Zhang, J. Zhang, Z. Yang, D. Zhang, A New Composite Viscosity Reducer with both Asphaltene Dispersion and Emulsifying Capability for Heavy and Ultra-Heavy Crude Oils, Energy Fuel 31 (2017) 1159-1173
[20] T.E. Chavez-Miyauchi, L.S. Zamudio-Rivera, V. Barba-Lopez, Aromatic Polyisobutylene Succinimides as Viscosity Reducers with Asphaltene Dispersion Capability for Heavy and Extra-Heavy Crude Oils, Energy Fuel 27 (4) (2013) 1994-2001
[21] J. Xu, S. Xing, H. Qian, S. Chen, X. Wei, R. Zhang, L. Li, X. Guo, Effect of polar/nonpolar groups in comb-type copolymers on cold flowability and paraffin crystallization of waxy oils, Fuel 103 (2013) 600-605
[22] Y. Wu, G. Ni, F. Yang, C. Li, G. Dong, Modified Maleic Anhydride Co-polymers as Pour-Point Depressants and Their Effects on Waxy Crude Oil Rheology, Energy Fuel 26 (2) (2012) 995-1001
[23] H. Quan, L. Chen, Z. Huang, J. Wang, C. Zheng, The effect of a kind of hyperbranched polyester with different carbon length on flowability for crude oil, Fuel 214 (2018) 356-362
[24] A.E. Kuzmic, M. Radosevic, G. Bogdanic, V. Srica, R. Vukovic, Studies on the influence of long chain acrylic esters polymers with polar monomers as crude oil flow improver additives, Fuel 87 (13-14) (2008) 2943-2950
[25] L.V. Castro, E.A. Flores, F. Vazquez, Terpolymers as Flow Improvers for Mexican Crude Oils, Energy Fuel 25 (2) (2011) 539-544
[26] A.M. Al-Sabagh, T. Mahmoud, M.H. Helal, A.M. Abdelrahman, A.E.M. Abdallah, M. El-Rayes, Flow Ability Enhancement of Waxy Crude Oil Using New Spirocompound Based on Aromatic Amine System, Egyptian Journal of Chemistry 62 (12) (2019) 2289-2301
[27] T. Liu, L. Fang, X. Liu, X. Zhang, Preparation of a kind of reactive pour point depressant and its action mechanism, Fuel 143 (2015) 448-454
[28] R. Anto, S. Deshmukh, S. Sanyal, U.K. Bhui, Nanoparticles as flow improver of petroleum crudes:Study on temperature-dependent steady-state and dynamic rheological behavior of crude oils, Fuel 275 (2020) 117873
[29] J. Mao, J. Liu, H. Wang, X. Yang, Z. Zhang, B. Yang, J. Zhao, Novel terpolymers as viscosity reducing agent for Tahe super heavy oil, RSC Adv. 7 (31) (2017) 19257-19261
[30] W. Chen, Z. Zhao, Thermodynamic Modeling of Wax Precipitation in Crude Oils, Chin, J. Chem. Eng. 14 (5) (2006) 685-689
[31] R. Venkatesan, J.A. Ostlund, H. Chawla, P. Wattana, M. Nyden, H.S. Fogler, The effect of asphaltenes on the gelation of waxy oils, Energy Fuel 17 (6) (2003) 1630-1640
[32] Y. Aray, R. Hernández-Bravo, J.G. Parra, J. Rodríguez, D.S. Coll, Exploring the Structure-Solubility Relationship of Asphaltene Models in Toluene, Heptane, and Amphiphiles Using a Molecular Dynamic Atomistic Methodology, J. Phys. Chem. A 115 (42) (2011) 11495-11507
[33] F.M. Adebiyi, V. Thoss, Organic and elemental elucidation of asphaltene fraction of Nigerian crude oils, Fuel 118 (2014) 426-431
[34] E. Soto-Castruita, P.V. Ramirez-Gonzalez, U. Martinez-Cortes, S.E. Quinones-Cisneros, Effect of the Temperature on the Non-Newtonian Behavior of Heavy Oils, Energy Fuel 29 (5) (2014) 2883-2889
[35] K. Paso, H. Kallevik, J. Sjoeblom, Measurement of Wax Appearance Temperature Using Near-Infrared (NIR) Scattering, Energy Fuel 23 (10) (2009) 4988-4994
[36] V. Coussirat, F. Amarilla, P. Peruzzo, C.M. Susana, Dioctyl fumarate-co-vinyl benzoate copolymers preparation and their performance as flow improvers in waxy crude oils, J. Pet. Sci. Eng. 182 (2019) 106290-106290
[37] C. Li, C. Zhang, D. Sun, J Sun, Physicochemical Research on Effect of Pour Point Depressant on Wax Precipitation and Dissolution of Waxy Oil, Chemical Research In Chinese Universities 24 (8) (2003) 1451-1455 (in Chinese)
[38] Hirschberg, L.N.J. Dejong, B.A. Schipper, J.G. Meijer, Influence of Temperature and Pressure on Asphaltene Flocculation, SPE J. 24 (1984) 283-293
[39] H.J. Sun, COMPASS:An ab Initio Force-Field Optimized for Condensed-Phase ApplicationsOverview with Details on Alkane and Benzene Compounds, J. Phys. Chem. B 102 (38) (1998) 7338-7364
[40] S. Alimohammadi, S. Zendehboudi, L. James, A comprehensive review of asphaltene deposition in petroleum reservoirs:Theory, challenges, and tips, Fuel 252 (2019) 753-791
[41] J. Mao, Z. Kang, X. Yang, C. Lin, L. Zheng, M. Zuo, J. Mao, S. Dai, J. Xue, D. Ouyang, Synthesis and Performance Evaluation of a Nanocomposite Pour-Point Depressant and Viscosity Reducer for High-Pour-Point Heavy Oil, Energy Fuel 34 (7) (2020) 7965-7973
[42] A.M. Al-Sabagh, M.A. Betiha, D.I. Osman, T. Mahmoud, Synthesis and characterization of nanohybrid of poly (octadecylacrylates derivatives)/montmorillonite as pour point depressants and flow improver for waxy crude oil, Journal of Applied Polymer Science 136 (17) (2019)
[43] Q. Sun, Y. Yi, F. Ding, X. Liang, The research of nature about Liaohe heavy oil and its heavy components after thermal reaction, Petroleum refining and chemical industry 45 (10) (2014) 33-6 (in Chinese)