石油炼制与化工 ›› 2026, Vol. 58 ›› Issue (7): 169-177.
曹婷,常甜,尚倩,畅选辰,肖明艳,张甜
收稿日期:2026-01-04
修回日期:2026-03-13
出版日期:2026-07-12
发布日期:2026-06-29
通讯作者:
曹婷
E-mail:3214487984@qq.com
基金资助:#br#
Received:2026-01-04
Revised:2026-03-13
Online:2026-07-12
Published:2026-06-29
摘要: 全球塑料产量增长带来严重的环境污染与资源浪费,推动废塑料向高值化学品或燃料的定向转化成为重要研究方向。等离子体-催化耦合技术凭借其低温高效、选择性高的优势,在该领域展现出巨大潜力。综述了介质阻挡放电、微波放电和滑动弧放电3类等离子体反应器在废塑料制氢气、芳烃及碳材料领域的研究进展;总结了关键操作参数与催化剂结构对产物分布的调控规律;梳理了等离子体-催化界面的能量传递与反应路径协同机制,为废塑料的高值化资源转化提供理论支撑和技术参考。
曹婷 常甜 尚倩 畅选辰 肖明艳 张甜. 等离子体-催化耦合技术处理废塑料研究进展[J]. 石油炼制与化工, 2026, 58(7): 169-177.
婷 曹. The Current Situation of Plasma Coupling Catalytic Technology for Plastics Treatment and Resource Utilization[J]. PETROLEUM PROCESSING AND PETROCHEMICALS, 2026, 58(7): 169-177.
| [1] Oladele I, Omotosho T, Adediran A. Polymer-Based Composites: An Indispensable Material for Present and Future Applications [J]. Int J Polym Sci, 2020, 2020.[2] Statistics N B o. Annual output of primary form plastics from 2015 to 2024 [R], 2024.[3] Statista. Global plastics industry - statistics & facts [R], 2024.[4] Cai Y, Xu Y, Liu G, et al. Polyethylene microplastic modulates lettuce root exudates and induces oxidative damage under prolonged hydroponic exposure [J]. Sci Total Environ, 2024, 916.[5] 胡锦超, 常甜, 肖明艳, et al. 低温等离子体协同Ni基催化剂重整焦油研究进展 [J]. 燃料化学学报, 2024, 52(11): 1563-79.[6] 畅选辰, 常甜, 胡锦超, et al. 等离子体催化CH4-CO2重整积碳生消机制研究进展 [J]. 陕西科技大学学报?, 2025, 43(05): 23-42.[7] Ghosh T. Microplastics bioaccumulation in fish: Its potential toxic effects on hematology, immune response, neurotoxicity, oxidative stress, growth, and reproductive dysfunction [J]. Toxicology reports, 2025, 14: 101854.[8] Liston E M M L, Wertheimer M R. Plasma surface modification of polymers for improved adhesion: a critical review [M]. 1993.[9] Tendero C T C, Tristant P, et al. Atmospheric pressure plasmas: A review [J]. Spectrochimica Acta Part B: Atomic Spectroscopy, 2006: 61(1).[10] Aminu I, Nahil M A, Williams P T. Hydrogen from Waste Plastics by Two-Stage Pyrolysis/Low-Temperature Plasma Catalytic Processing [J]. Energy & Fuels, 2020.[11] Uekert T, Kuehnel M, Wakerley D, Reisner E. Plastic waste as a feedstock for solar-driven H2 generation [J]. Energy Environ Sci, 2018, 11(10): 2853-7.[12] Lu W, Abbas Y, Mustafa M, et al. A review on application of dielectric barrier discharge plasma technology on the abatement of volatile organic compounds [J]. Front Env Sci Eng, 2019, 13(2).[13] Liu J, Li S, Mahmood A, et al. Improving hydrogen production via ex-situ catalytic fast pyrolysis of non-thermal plasma pretreated HDPE with 1Fe1Ni/γ-Al2O3 catalyst [J]. ACB, 2025, 368.[14] Ren J, Li J, Zhen Y, et al. Removal of polyvinyl chloride microplastic by dielectric barrier discharge plasma [J]. Sep Purif Technol, 2022, 290.[15] Sima J, Song J, Du X, et al. Complete degradation of polystyrene microplastics through non-thermal plasma-assisted catalytic oxidation [J]. J Hazard Mater, 2024, 480.[16] Song J, Wang J, Sima J, et al. Dechlorination of waste polyvinyl chloride (PVC) through non-thermal plasma [J]. Chemosphere?, 2023, 338.[17] Jie X, Gonzalez-Cortes S, Xiao T, et al. The decarbonisation of petroleum and other fossil hydrocarbon fuels for the facile production and safe storage of hydrogen [J]. Energy Environ Sci, 2019, 12(1): 238-49.[18] Liu Y, Guo N, Yin P, Zhang C. Facile growth of carbon nanotubes using microwave ovens: the emerging application of highly efficient domestic plasma reactors [J]. Nanoscale Adv, 2019, 1(12): 4546-59.[19] Luo J, Cui C, Sun S, et al. Leveraging CO2 to directionally control the H2/CO ratio in continuous microwave pyrolysis/gasification of waste plastics: Quantitative analysis of CO2 and density functional theory calculations of regulation mechanism [J]. Chem Eng J, 2022, 435.[20] Li W, Qian K, Yang Z, et al. Promotion effect of cobalt doping on microwave-initiated plastic deconstruction for hydrogen production over iron catalysts [J]. ACB, 2023, 327.[21] Zhang P, Wu M, Liang C, et al. In-situ exsolution of Fe-Ni alloy catalysts for H2 and carbon nanotube production from microwave plasma-initiated decomposition of plastic wastes [J]. J Hazard Mater, 2023, 445.[22] Dong Y, Liu B, He M, et al. Microwave-coupled recycling of plastic waste into hydrogen and carbon nanotubes over economical iron-based catalyst [J]. Int J Hydrogen Energy, 2025, 115: 24-36.[23] Rueangjitt N, Sreethawong T, Chavadej S. Reforming of CO2-Containing Natural Gas Using an AC Gliding Arc System: Effects of Operational Parameters and Oxygen Addition in Feed [J]. Plasma Chem Plasma Process, 2008, 28(1): 49-67.[24] Moussa D, Brisset J L. Disposal of spent tributylphosphate by gliding arc plasma. [J]. J Hazard Mater, 2003, 102(2-3): 189-200.[25] Bellakhal N D K, Brisset J L. Plasma and wet oxidation of (63Cu37Zn) brass[J] [J]. Mater Chem Phys, 2002.[26] Bo Z, Yan J, Li X, et al. Scale-up analysis and development of gliding arc discharge facility for volatile organic compounds decomposition [J]. J Hazard Mater, 2008, 155(3): 494-501.[27] Tiya-Djowe A, Acayanka E, Mbouopda A, et al. Producing oxide catalysts by exploiting the chemistry of gliding arc atmospheric plasma in humid air [J]. Catal Today, 2019, 334: 104-12.[28] Tabu B, Akers K, Yu P, et al. Nonthermal atmospheric plasma reactors for hydrogen production from low-density polyethylene [J]. Int J Hydrogen Energy, 2022, 47(94): 39743-57.[29] Shi C, Long Y, Zhou Y, et al. Rapid degradation of microplastics by catalyst-free gliding arc plasmatron [J]. Chem Commun, 2025, 61(39): 7089-92.[30] 张国治, 王文祥, 张磊. 介质阻挡放电等离子体处理变压器废弃绝缘油的实验探究 [J]. 电工技术学报, 2025, 40(1).[31] Song J, Lv J, Pan Y, et al. Low-temperature hydrogen production from waste polyethylene by nonthermal plasma (NTP)-assisted catalytic pyrolysis using NiCeOx/ β catalyst [J]. Chem Eng J, 2024, 490.[32] Sima J, Wang J, Song J, et al. Efficient degradation of polystyrene microplastic pollutants in soil by dielectric barrier discharge plasma [J]. J Hazard Mater, 2024, 468.[33] Jasinski M, Dors M, Nowakowska H, et al. Production of hydrogen via conversion of hydrocarbons using a microwave plasma [J]. J Phys D Appl Phys, 2011, 44(19).[34] Suenaga Y, Takamatsu T, Aizawa T, et al. Influence of Controlling Plasma Gas Species and Temperature on Reactive Species and Bactericidal Effect of the Plasma [J]. Appl Sci-Basel, 2021, 11(24).[35] Rathore V, Nema S. The role of different plasma forming gases on chemical species formed in plasma activated water (PAW) and their effect on its properties [J]. Phys Scr, 2022, 97(6).[36] Song J, Sima J, Pan Y, et al. Dielectric Barrier Discharge Plasma Synergistic Catalytic Pyrolysis of Waste Polyethylene into Aromatics-Enriched Oil [J]. ACS Sustainable Chem Eng, 2021, 9(34): 11448-57.[37] Kim S, Yun U, Kim J. Low-Density Polyethylene Degradation and Energy Yield Using Dielectric Barrier Discharge under Various Electrical Conditions [J]. Energies, 2023, 16(5).[38] Sima J, Wang J, Song J, et al. Dielectric barrier discharge plasma for the remediation of microplastic-contaminated soil from landfill [J]. Chemosphere?, 2023, 317.[39] Al-Fatesh A, AL-Garadi N, Osman A, et al. From plastic waste pyrolysis to Fuel: Impact of process parameters and material selection on hydrogen production [J]. FUEL, 2023, 344.[40] Acomb J, Wu C, Williams P. The use of different metal catalysts for the simultaneous production of carbon nanotubes and hydrogen from pyrolysis of plastic feedstocks [J]. Appl Catal B-environ, 2016, 180: 497-510.[41] Nishu, Li C, Yellezuome D, et al. Catalytic pyrolysis of rice straw for high yield of aromatics over modified ZSM-5 catalysts and its kinetics [J]. Renewable Energy, 2023, 209: 569-80.[42] Inayat A, Inayat A, Klemencova K, et al. Three-stage pyrolysis-catalytic dry reforming of waste polyolefins over MFI and Ni-MFI catalysts for BTEX and syngas production [J]. FUEL, 2024, 371.[43] Chen Z, Chen L, Zhang J, et al. Upgrading of bio-oil from catalytic co-pyrolysis of PVC and biomass over Ni-modified ZSM-5 [J]. Biomass Convers Bior, 2024, 14(5): 6697-708.[44] Gou X, Zhao D, Wu C. Catalytic conversion of hard plastics to valuable carbon nanotubes [J]. J Anal Appl Pyrolysis, 2020, 145.[45] Li Q, Shan R, Li W, et al. Co-production of hydrogen and carbon nanotubes via catalytic pyrolysis of polyethylene over Fe/ZSM-5 catalysts: Effect of Fe loading on the catalytic activity [J]. Int J Hydrogen Energy, 2024, 55: 1476-85.[46] Zhang L, Zhu N, Liu Y, et al. Two-stage co-pyroysis behaviors and product distribution of Enteromorpha and marine waste polypropylene catalyzed by Cu/HZSM-5 [J]. Renewable Energy, 2026, 256.[47] Zhang J, Ma M, Chen Z, et al. Production of monocyclic aromatics and light olefins through ex-situ catalytic pyrolysis of low-density polyethylene over Ga/P/ZSM-5 catalyst [J]. J Energy Inst, 2023, 108.[48] Lin X, Zhang Z, Zhang Z, et al. Catalytic fast pyrolysis of a wood-plastic composite with metal oxides as catalysts [J]. Waste Manag, 2018, 79: 38-47.[49] Qin T H, Ji G, Qu B, et al. Pyrolysis-catalytic gasification of plastic waste for hydrogen-rich syngas production with hybrid-functional Ni-CaO Ca2SiO4 catalyst [J]. Carbon Capture Science & Technology, 2025, 14.[50] Li S, Xue Y, Lin Y, et al. Synergistic Activity of the Fe2O3/Al2O3 Catalyst for Hydrogen Production through Pyrolysis-Catalytic Decomposition of Plastics [J]. ACS Sustainable Chem Eng, 2023, 11(27): 10108-18.[51] Wang J, Jiang J, Zhong Z, et al. Catalytic fast co-pyrolysis of bamboo sawdust and waste plastics for enhanced aromatic hydrocarbons production using synthesized CeO2/γ-Al2O3 and HZSM-5 [J]. Energy Convers Manage, 2019, 196: 759-67.[52] Wu S, Ren Z, Hu Q, et al. Upcycling plastic waste into syngas by staged chemical looping gasification with modified Fe-based oxygen carriers [J]. Appl Energy, 2024, 353.[53] Gong J, Liu J, Jiang Z, et al. Converting mixed plastics into mesoporous hollow carbon spheres with controllable diameter [J]. Appl Catal B-environ, 2014, 152: 289-99.[54] Elordi G, Olazar M, Artetxe M, et al. Effect of the acidity of the HZSM-5 zeolite catalyst on the cracking of high density polyethylene in a conical spouted bed reactor [J]. Appl Catal, A, 2012, 415: 89-95.[55] Zhang J, Wang X, Sun K, et al. Boosting the Application of Spent Catalysts in Waste Plastic Catalytic Pyrolysis: Maximizing Gasoline Product Selectivity and Quality [J]. Chemistryselect, 2025, 10(8).[56] Fu W, Cheng Y, Wang Y, et al. Counteractive catalytic effects of FeNi- versus Fe- and Ni- in plastic pyrolysis for advanced-quality jet fuel production [J]. Chem Eng J, 2024, 494.[57] Ratnasari D, Nahil M, Williams P. Catalytic pyrolysis of waste plastics using staged catalysis for production of gasoline range hydrocarbon oils [J]. J Anal Appl Pyrolysis, 2017, 124: 631-7.[58] Shi Y, Liu C, Zhuo J, Yao Q. Investigation of a Ni-Modified MCM-41 Catalyst for the Reduction of Oxygenates and Carbon Deposits during the Co-Pyrolysis of Cellulose and Polypropylene [J]. ACS OMEGA, 2020, 5(32): 20299-310.[59] Dai L, Zhou N, Lv Y, et al. Chemical upcycling of waste polyolefinic plastics to low-carbon synthetic naphtha for closing the plastic use loop [J]. Sci Total Environ, 2021, 782.[60] Saad J, Williams P. Catalytic dry reforming of waste plastics from different waste treatment plants for production of synthesis gases [J]. Waste Manag, 2016, 58: 214-20.[61] Shoukat B, Hussain H, Naz M, et al. Microwaves assisted deconstruction of HDPE waste into structured carbon and hydrogen fuel using Al2O3-(Ni, Zn, Mg)Fe2O4 composite catalysts [J]. TSAEP, 2024, 47.[62] Raghav H, Joshi B, Kumar K, et al. Catalytic pyrolysis of low-density waste polyethylene into light olefins and hydrogen over manganese-supported alumina [J]. JECE, 2025, 13(1).[63] Choi D, Jung S, Tsang Y, et al. Sustainable valorization of styrofoam and CO2 into syngas [J]. Sci Total Environ, 2022, 834.[64] Nguyen L, Poinern G, Le H, et al. A LaFeO3 supported natural-clay-mineral catalyst for efficient pyrolysis of polypropylene plastic material [J]. Asia-Pac J Chem Eng, 2021, 16(5).[65] Abnisa F. Enhanced Liquid Fuel Production from Pyrolysis of Plastic Waste Mixtures Using a Natural Mineral Catalyst [J]. Energies, 2023, 16(3).[66] Sun D, Sun L, Han D, et al. Enhanced aromatics production via co-pyrolysis of biomass and plastic by Zn modified ZSM-5 catalysts [J]. J Anal Appl Pyrolysis, 2025, 189.[67] Li Q, Shan R, Zhang J, et al. Enhancement of hydrogen and carbon nanotubes production from hierarchical Ni/ZSM-5 catalyzed polyethylene pyrolysis [J]. J Anal Appl Pyrolysis, 2023, 169.[68] Li Y, Liu T, Deng S, et al. Surface Modification of Fe-ZSM-5 Using Mg for a Reduced Catalytic Pyrolysis Temperature of Low-Density Polyethylene to Produce Light Olefin [J]. CATALYSTS, 2024, 14(1).[69] Hajian M, Rostamizadeh M. Nickel promoted Si-rich ZSM-5 nanocatalyst remarkably converts LDPE plastic waste to gasoline range hydrocarbons in a dual-bed semi-batch reactor at atmospheric pressure [J]. J Anal Appl Pyrolysis, 2023, 173.[70] Chen Z, Erwin B, Che L. Recycling waste polyethylene into fuels over Fe/USY catalyst: Evaluation on the catalytic activities of varied iron states [J]. FUEL, 2024, 363.[71] Lin H, Zhu L, Liu Y, et al. Plastic upgrading via catalytic pyrolysis with combined metal-modified gallium-based HZSM-5 and MCM-41 [J]. Front Chem Sci Eng?, 2024, 18(11).[72] Ma C, Yu J, Yan Q, et al. Pyrolysis-catalytic upgrading of brominated high Impact polystyrene over Fe and Ni modified catalysts: Influence of HZSM-5 and MCM-41 catalysts [J]. Polym Degrad Stab, 2017, 146: 1-12.[73] Lin H, Zhan Y, Vladimirovich V, et al. Enhancement of aromatics selectivity in waste LLDPE with HZSM-5@MCM-41 Core-Shell catalysts synthesized by One-Step hydrothermal method [J]. FUEL, 2025, 397.[74] Azam M, Fernandes A, Ferreira M, et al. Pore-Structure Engineering of Hierarchical β Zeolites for the Enhanced Hydrocracking of Waste Plastics to Liquid Fuels [J]. ACS CATALYSIS, 2024, 14(21): 16148-65.[75] Alvarez J, Kumagai S, Wu C, et al. Hydrogen production from biomass and plastic mixtures by pyrolysis-gasification [J]. Int J Hydrogen Energy, 2014, 39(21): 10883-91.[76] Liu X, Zhang Y, Nahil M, et al. ` Development of Ni- and Fe- based catalysts with different metal particle sizes for the production of carbon nanotubes and hydrogen from thermo-chemical conversion of waste plastics [J]. J Anal Appl Pyrolysis, 2017, 125: 32-9.[77] Budsaereechai S, Hunt A, Ngernyen Y. Catalytic pyrolysis of plastic waste for the production of liquid fuels for engines [J]. RSC Adv, 2019, 9(10): 5844-57.[78] Dong Z, Chen W, Xu K, et al. Understanding the Structure-Activity Relationships in Catalytic Conversion of Polyolefin Plastics by Zeolite-Based Catalysts: A Critical Review [J]. ACS CATALYSIS, 2022, 12(24): 14882-901.[79] Dai L, Lata S, Cobb K, et al. Recent advances in polyolefinic plastic pyrolysis to produce fuels and chemicals [J]. J Anal Appl Pyrolysis, 2024, 180.[80] Rex P, Masilamani I, Miranda L. Microwave pyrolysis of polystyrene and polypropylene mixtures using different activated carbon from biomass [J]. J Energy Inst, 2020, 93(5): 1819-32.[81] Mazar M, Al-Hashimi S, Cococcioni M, Bhan A. β-Scission of Olefins on Acidic Zeolites: A Periodic PBE-D Study in H-ZSM-5 [J]. J Phys Chem C, 2013, 117(45): 23609-20.[82] Fan L, Liu L, Xiao Z, et al. Comparative study of continuous-stirred and batch microwave pyrolysis of linear low-density polyethylene in the presence/absence of HZSM-5 [J]. ENERGY, 2021, 228.[83] Wang W, Ma Y, Chen G, et al. Enhanced hydrogen production using a tandem biomass pyrolysis and plasma reforming process [J]. Fuel Process Technol, 2022, 234.[84] Yao L, King J, Wu D, et al. Non-thermal plasma-assisted hydrogenolysis of polyethylene to light hydrocarbons [J]. Catal Commun, 2021, 150.[85] Song J, Wang J, Pan Y, et al. Catalytic pyrolysis of waste polyethylene into benzene, toluene, ethylbenzene and xylene (BTEX)-enriched oil with dielectric barrier discharge reactor [J]. JEMA, 2022, 322.[86] Pan Y, Du X, Zhu C, et al. Degradation of rubber waste into hydrogen enriched syngas via microwave-induced catalytic pyrolysis [J]. Int J Hydrogen Energy, 2022, 47(80): 33966-78.[87] Zhang Y, Williams P. Carbon nanotubes and hydrogen production from the pyrolysis catalysis or catalytic-steam reforming of waste tyres [J]. J Anal Appl Pyrolysis, 2016, 122: 490-501.[88] Han D, Shin S, Jung H, et al. Hydrogen Production by Steam Reforming of Pyrolysis Oil from Waste Plastic over 3 wt.% Ni/Ce-Zr-Mg/Al2O3 Catalyst [J]. Energies, 2023, 16(6).[89] Nahil M, Wu C, Williams P. Influence of metal addition to Ni-based catalysts for the co-production of carbon nanotubes and hydrogen from the thermal processing of waste polypropylene [J]. Fuel Process Technol, 2015, 130: 46-53.[90] Xiao H, Harding J, Lei S, et al. Hydrogen and aromatics recovery through plasma-catalytic pyrolysis of waste polypropylene [J]. J Clean Prod, 2022, 350.[91] Armenise S, Luing W S, Romero Vázquez M A, et al. Tailoring catalyst acidity and hierarchical pore structure for enhanced BTX yields in plastic waste pyrolysis [J]. JECE, 2025, 13(6).[92] Yun T, Diao Y, Han J, et al. Cold plasma-assisted co-conversion of polyolefin wastes and CO2 into aromatics over hierarchical Ga/ZSM-5 catalyst [J]. J Energy Chem, 2025, 106: 587-99.[93] Song J, Wang J, Du X, et al. Ga-modified zeolites to convert mixed waste plastics to benzene, toluene, ethylbenzene, and xylene (BTEX)-enriched oil through a dielectric barrier discharge plasma-modified reactor [J]. Chem Eng J, 2023, 476: 146501.[94] Han J, Yun T, Hou C, et al. Plasma-catalytic cracking of polyethylene over Ni/Hβ zeolites to light hydrocarbon fuels and hydrogen without external heating [J]. Front Chem Sci Eng?, 2025, 19(8).[95] Yu X, Rashid A, Chen G, et al. Plasma-driven catalytic process for plastic waste upcycling over perovskite-type pre-catalysts [J]. Chem Eng J, 2025, 512.[96] Wang J, Pan Y, Song J, Huang Q. A high-quality hydrogen production strategy from waste plastics through microwave-assisted reactions with heterogeneous bimetallic iron/nickel/cerium catalysts [J]. J Anal Appl Pyrolysis, 2022, 166.[97] Chen L, Zhou W, Huo C, et al. Improved metal-support interaction in Ru/CeO2 catalyst via plasma-treated strategy for dichloroethane oxidation [J]. Appl Catal, A, 2023, 660.[98] Wang W, Wang H, Zhu T, Fan X. Removal of gas phase low-concentration toluene over Mn, Ag and Ce modified HZSM-5 catalysts by periodical operation of adsorption and non-thermal plasma regeneration [J]. J Hazard Mater, 2015, 292: 70-8.[99] Wang Y, Craven M, Yu X, et al. Plasma-Enhanced Catalytic Synthesis of Ammonia over a Ni/Al2O3 Catalyst at Near-Room Temperature: Insights into the Importance of the Catalyst Surface on the Reaction Mechanism [J]. ACS CATALYSIS, 2019, 9(12): 10780-93.[100] Fu M, Shang K, Peng B, et al. Generation of air discharge plasma in the cavities of porous catalysts: a modeling study [J]. PLASMA SCIENCE & TECHNOLOGY, 2023, 25(2).[101] Stere C, Adress W, Burch R, et al. Probing a Non-Thermal Plasma Activated Heterogeneously Catalyzed Reaction Using in Situ DRIFTS-MS [J]. ACS CATALYSIS, 2015, 5(2): 956-64.[102] Giammaria G, Van Rooij G, Lefferts L. Plasma Catalysis: Distinguishing between Thermal and Chemical Effects [J]. CATALYSTS, 2019, 9(2).[103] Boules A, Tabu B, Brack E, et al. Hydrogen production synergy in non-thermal plasma copyrolysis of low-density polyethylene and cellulose [J]. Int J Hydrogen Energy, 2024, 65: 375-80. |
| [1] | 饶勇建 黎小龙 蒋敏 杨正炳 周济群 龚传波. 生产60号工业己烷溶剂油项目改造及效果[J]. 石油炼制与化工, 2026, 57(6): 65-71. |
| [2] | 程仲芊 胡亭屹. 基于全二维气相色谱-飞行时间质谱联用技术的聚乙烯热解油分子结构表征[J]. 石油炼制与化工, 2026, 57(6): 153-159. |
| [3] | 彭佩琦 习远兵 张锐 罗勇. 超重力微气泡强化柴油加氢精制过程化学氢耗研究[J]. 石油炼制与化工, 2026, 57(5): 70-77. |
| [4] | 徐茜 刘雅琼 吴梅. 废塑料热裂解油中氯含量的测定[J]. 石油炼制与化工, 2026, 57(5): 114-119. |
| [5] | 张登前 翟维明 李桂军 习远兵 刘锋 徐凯 甘凌峰. 催化裂解汽油选择性加氢生产芳烃抽提原料(RGTA)技术开发及应用[J]. 石油炼制与化工, 2026, 57(5): 18-23. |
| [6] | 李雪妍 胡俊颖 王思雯 石薇薇 夏树斌 李晓光 佟天宇. 催化裂化油浆中压加氢改质-馏分切割组合工艺制备橡胶增塑剂[J]. 石油炼制与化工, 2026, 57(5): 36-43. |
| [7] | 周志恒 王子军 罗洋 杨长钰 倪清 董明. 含五元环的芳烃热缩聚扩环反应行为研究[J]. 石油炼制与化工, 2026, 57(4): 85-90. |
| [8] | 林强 文富利 李红伟 栾学斌 徐润. CO2加氢直接制芳烃双功能催化剂的研究进展[J]. 石油炼制与化工, 2026, 57(3): 152-165. |
| [9] | 王彦涛. 连续重整生成油液相脱烯烃催化剂TORH-1首次再生及再生后工业应用情况[J]. 石油炼制与化工, 2026, 57(3): 64-67. |
| [10] | 王天宇 娄永峰 孙龙祥 高春杰. 芳烃联合装置低温热发汽提质综合利用与节能优化[J]. 石油炼制与化工, 2026, 57(3): 140-144. |
| [11] | 窦志俊 孙显锋 高福祥 向辉 陈步宁. 煤焦油加氢精制重石脑油用于催化重整制芳烃的研究[J]. 石油炼制与化工, 2026, 57(3): 38-42. |
| [12] | 潘琼 张晓华 邢定峰 吕清龙. 废塑料回收与催化剂循环利用的耦合路径展望[J]. 石油炼制与化工, 2026, 57(1): 159-163. |
| [13] | 王迪 魏晓丽 龚剑洪 刘宪龙. 非临氢重芳烃轻质化过程中BTX分布规律研究[J]. 石油炼制与化工, 2025, 56(9): 20-25. |
| [14] | 康承琳 张文 岳欣 盖月庭 周震寰 刘中勋. C8芳烃异构化气、液相组合工艺概算[J]. 石油炼制与化工, 2025, 56(9): 34-41. |
| [15] | 顾士庆 石张平 李经球 孔德金. 乙苯侧链选择性加氢脱端甲基催化剂制备与性能研究[J]. 石油炼制与化工, 2025, 56(8): 42-47. |
| 阅读次数 | ||||||
|
全文 |
|
|||||
|
摘要 |
|
|||||
京公网安备 11010802027553号