石油化工高等学校学报 ›› 2023, Vol. 36 ›› Issue (2): 51-62.DOI: 10.12422/j.issn.1006-396X.2023.02.007
收稿日期:
2022-08-08
修回日期:
2022-09-29
出版日期:
2023-04-25
发布日期:
2023-05-06
通讯作者:
吴志杰
作者简介:
高诗奡(1998⁃),男,硕士研究生,从事沸石分子筛合成、改性及反应性能研究;E⁃mail:837735689@qq.com。
基金资助:
Received:
2022-08-08
Revised:
2022-09-29
Published:
2023-04-25
Online:
2023-05-06
Contact:
Zhijie Wu
摘要:
加氢异构反应在提升汽油辛烷值、柴油降凝和润滑油基础油脱蜡降黏等方面应用广泛。一维孔沸石对直链烷烃具有独特的孔口择形效应,是加氢异构反应中最适宜的酸性载体和异构化活性组分,其异构化性能主要取决于沸石拓扑结构、酸性质、晶粒尺寸等自身因素。主要概括了近年来不同拓扑结构一维孔沸石的合成、改性及应用的研究进展,讨论了常用于加氢异构的一维孔沸石分子筛的发展趋势,并对其应用前景进行了展望。
中图分类号:
高诗奡, 吴志杰. 用于加氢异构的一维孔沸石分子筛研究进展[J]. 石油化工高等学校学报, 2023, 36(2): 51-62.
Shiao Gao, Zhijie Wu. Advances in the One⁃Dimensional Pore Zeolite for Hydroisomerization[J]. Journal of Petrochemical Universities, 2023, 36(2): 51-62.
沸石 | 孔道尺寸/nm | 拓扑结构(环数) | 应用领域 | 文献 |
---|---|---|---|---|
ZSM⁃22 | 0.46×0.57 | TON(十元环) | 柴油降凝及润滑油异构脱蜡 | [ |
ZSM⁃23 | 0.45×0.52 | MTT(十元环) | 柴油降凝及润滑油异构脱蜡 | [ |
ZSM⁃48 | 0.53×0.56 | *MRE(十元环) | 柴油降凝及润滑油异构脱蜡 | [ |
EU⁃1 | 0.54×0.41 | EUO(十元环) | 二甲苯异构,柴油降凝 | [ |
SAPO⁃11 | 0.40×0.65 | AEL(十元环) | 柴油降凝及润滑油异构脱蜡 | [ |
SAPO⁃31 | 0.54×0.54 | ATO(十二元环) | 柴油降凝及润滑油异构脱蜡 | [ |
Omega沸石 | 0.74×0.75 | MAZ(十二元环) | 柴油降凝,提升低温流动性 | [ |
丝光沸石 | 0.67×0.70 | MOR(十二元环) | 汽油馏分异构提高辛烷值 | [ |
L沸石 | 0.71×0.71 | LTL(十二元环) | 汽油馏分异构提高辛烷值,柴油异构降凝 | [ |
表1 用于加氢异构反应的一维孔沸石分子筛
Table 1 The list of one?dimensional pore zeolites for hydroisomerization reaction
沸石 | 孔道尺寸/nm | 拓扑结构(环数) | 应用领域 | 文献 |
---|---|---|---|---|
ZSM⁃22 | 0.46×0.57 | TON(十元环) | 柴油降凝及润滑油异构脱蜡 | [ |
ZSM⁃23 | 0.45×0.52 | MTT(十元环) | 柴油降凝及润滑油异构脱蜡 | [ |
ZSM⁃48 | 0.53×0.56 | *MRE(十元环) | 柴油降凝及润滑油异构脱蜡 | [ |
EU⁃1 | 0.54×0.41 | EUO(十元环) | 二甲苯异构,柴油降凝 | [ |
SAPO⁃11 | 0.40×0.65 | AEL(十元环) | 柴油降凝及润滑油异构脱蜡 | [ |
SAPO⁃31 | 0.54×0.54 | ATO(十二元环) | 柴油降凝及润滑油异构脱蜡 | [ |
Omega沸石 | 0.74×0.75 | MAZ(十二元环) | 柴油降凝,提升低温流动性 | [ |
丝光沸石 | 0.67×0.70 | MOR(十二元环) | 汽油馏分异构提高辛烷值 | [ |
L沸石 | 0.71×0.71 | LTL(十二元环) | 汽油馏分异构提高辛烷值,柴油异构降凝 | [ |
1 | 于瑞,华子乐,黄健.金属位⁃酸中心协同性对烷烃异构化双功能催化剂的性能影响及研究进展[J].化工矿物与加工,2022,51(5):1⁃6. |
Yu R,Hua Z L,Huang J. The synergic effect of metal‐acid proximity on the performance of bifunctional catalyst with alkanes isomerization and the research development[J].Industrial Minerals & Processing,2022,51(5):1⁃6. | |
2 | 毕云飞,夏国富,黄卫国,等.加氢异构化催化剂的研究——加氢功能的影响[J].石油学报(石油加工),2018,34(1):64⁃70. |
Bi Y F,Xia G F,Huang W G,et al.Investigation on the hydroisomerization catalyst——The effect of the hydrogenation function[J]. Acta Petrolei Sinica (Petroleum Processing Section),2018,34(1):64⁃70. | |
3 | 贾秀沭,马守涛,所艳华,等.C5-C8烷烃异构化催化剂的研究进展[J].化学与黏合,2017,39(2):126⁃131. |
Jia X S,Ma S T,Suo Y H,et al.Research progress of C5-C8 alkanes isomerization catalysts[J].Chemistry and Adhesion,2017,39(2):126⁃131. | |
4 | Li T,Wang W,Feng Z L,et al.The hydroisomerization of n⁃hexane over highly selective Pd/ZSM⁃22 bifunctional catalysts:The improvements of metal⁃acid balance by room temperature electron reduction method[J].Fuel,2020,272(15):117717. |
5 | 王琰,刘伟,李赛,等.Pt负载位置对双功能催化剂正十二烷加氢异构化性能影响[J].石油学报(石油加工),2021,37(6):1338⁃1345. |
Wang Y,Liu W,Li S,et al.Influence of Pt position on the performance of bifunctional catalysts for n⁃dodecane hydroisomerization[J].Acta Petrolei Sinica (Petroleum Processing Section),2021,37(6):1338⁃1345. | |
6 | Wang Y,Liu W,Zhang W,et al.Comparison of n⁃dodecane hydroisomerization performance over Pt supported ZSM⁃48 and ZSM⁃22[J].Catalysis Letters,2021,151(12):3492⁃3500. |
7 | Wang M H,Han Y Y,Liu S H,et al.Pore‐mouth catalysis boosting the formation of iso‐paraffins from syngas over bifunctional catalysts[J].Chinese Journal of Catalysis,2021,42(12):2197⁃2205. |
8 | Wang X,Zhang X,Wang Q.N⁃dodecane hydroisomerization over Pt/ZSM⁃22:Controllable microporous Bronsted acidity distribution and shape⁃selectivity[J].Applied Catalysis A:General,2020,590:117335. |
9 | Tan Y C,Hu W J,Du Y Y,et al.Species and impacts of metal sites over bifunctional catalyst on long chain n⁃alkane hydroisomerization:A review[J].Applied Catalysis A:General,2021,611:117916. |
10 | Gao S B,Zhao Z,Lu X F,et al.Hydrocracking diversity in n⁃dodecane isomerization on Pt/ZSM⁃22 and Pt/ZSM⁃23 catalysts and their catalytic performance for hydrodewaxing of lube base oil[J].Petroleum Science,2020,17(6):1752⁃1763. |
11 | Li H Y,Liu C L,Wang Y,et al.Synthesis,characterization and n⁃hexane hydroisomerization performances of Pt supported on alkali treated ZSM⁃22 and ZSM⁃48[J].RSC Advances,2018,8(51):28909⁃28917. |
12 | Zhang M,Long H,Fan D,et al.Synthesis of ZSM⁃48 zeolites and their catalytic performance:A review[J].Catalysis Science & Technology,2022,12(16):5097⁃5109. |
13 | 卜佳玉,王东军,颜子金,等.模板剂和助剂对Pt/MOR催化剂临氢异构性能的影响[J].石油炼制与化工,2018,49(9):69⁃74. |
Bu J Y,Wang D J,Yan Z J,et al.Effects of template and additives on hydroisomerization performance of Pt/MOR catalyst[J].Petroleum Processing and Petrochemicals,2018,49(9):69⁃74. | |
14 | Yao J,Feng X B,Fan J Q,et al.Effects of mordenite zeolite catalyst synthesis conditions on dimethyl ether carbonylation[J].Microporous and Mesoporous Materials,2020,306:110431. |
15 | Yu G,Qiu M H,Wang T,et al.Optimization of the pore structure and acidity of SAPO⁃11 for highly efficient hydroisomerization on the long⁃chain alkane[J].Microporous and Mesoporous Materials,2021,320:111076. |
16 | 王新苗,杨晓东,孙发民,等.Pt/SAPO⁃11和Pt/SAPO⁃31催化剂对长链烷烃的加氢异构性能[J].石油学报(石油加工),2017,33(4):717⁃723. |
Wang X M,Yang X D,Sun F M,et al.Hydroisomerization of long⁃chain alkanes over Pt/SAPO⁃11 and Pt/SAPO⁃31 catalysts[J].Acta Petrolei Sinica (Petroleum Processing Section),2017,33(4):717⁃723. | |
17 | Bouchiba N,Toumi N,Bengueddach A,et al.Preparation of a new micro⁃mesoporous omega zeolite by hydrothermal route:Effect of crystallization time[J].Silicon,2022,14(9):5085⁃5090. |
18 | 章芬,章凌,杨志超,等.高温快速合成纳米MAZ分子筛[J].催化学报,2019,40(7):1105⁃1116. |
Zhang F,Zhang L,Yang Z C,et al.Design of fast crystallization of nanosized zeolite omega crystals at higher temperatures[J].Chinese Journal of Catalysis,2019,40(7):1105⁃1116. | |
19 | Zhang F,Luo Y H,Chen L,et al.Designer synthesis of ultra⁃fine Fe⁃LTL zeolite nanocrystals[J].Crystals,2020,10(9):813. |
20 | Teketel S,Skistad W,Benard S,et al.Shape selectivity in the conversion of methanol to hydrocarbons:The catalytic performance of one⁃dimensional 10⁃ring zeolites:ZSM⁃22,ZSM⁃23,ZSM⁃48,and EU⁃1[J].ACS Catalysis,2012,2(1):26⁃37. |
21 | Zhang M,Chen Y J,Wang L,et al.Shape selectivity in hydroisomerization of hexadecane over Pt supported on 10⁃ring zeolites:ZSM⁃22,ZSM⁃23,ZSM⁃35,and ZSM⁃48[J].Industrial & Engineering Chemistry Research,2016,55(21):6069⁃6078. |
22 | Romero D,Rohling R,Meng L Q,et al.Shape selectivity in linear paraffins hydroconversion in 10⁃membered⁃ring pore zeolites[J].Journal of Catalysis,2021,394:284⁃298. |
23 | Zschiesche C,Himsl D,Rakoczy R,et al.Hydroisomerization of long⁃chain n⁃alkanes over bifunctional zeolites with 10⁃membered and 12⁃membered⁃ring pores[J].Chemical Engineering &Technology,2018,41(1):199⁃204. |
24 | Lv G,Wang C X,Wang P,et al.Pt/ZSM⁃22 with partially filled micropore channels as excellent shape⁃selective hydroisomerization catalyst[J].ChemCatChem,2019,11(5):1375. |
25 | Zhai M,Wu W,Xing E,et al.Generating TON zeolites with reduced [001] length through combined mechanochemical bead⁃milling and porogen⁃directed recrystallization with enhanced catalytic property in hydroisomerization[J].Chemical Engineering Journal,2022,440,135874. |
26 | Chen Y J,Li C,Wang L,et al.Seed⁃assisted synthesis of ZSM⁃23 zeolites in the absence of alkali metal ions[J].Microporous and Mesoporous Materials,2017,252(1):146⁃153. |
27 | Du Y Y,Feng B,Jiang Y,et al.Solvent⁃free synthesis and n⁃hexadecane hydroisomerization performance of SAPO⁃11 catalyst[J].European Journal of Inorganic Chemistry,2018,2018(22):2599⁃2606. |
28 | Lyu Y C,Liu Y X,He X,et al.The regulation of Si distribution and surface acidity of SAPO⁃11 molecular sieve[J].Applied Surface Science,2018,453:350⁃357. |
29 | 郭亮,张磊,张伟,等.酸处理的纳米ZSM⁃22沸石负载Pt催化剂对正十二烷的加氢异构化性能[J].石油学报(石油加工),2021,37(6):1321⁃1328. |
Guo L,Zhang L,Zhang W,et al.Hydroisomerization performance of acid⁃treated nanosized ZSM⁃22 zeolite supported Pt catalyst on n⁃dodecane[J].Acta Petrolei Sinica (Petroleum Processing Section),2021,37(6):1321⁃1328. | |
30 | Haghighi M,Fereidooni M.Silica coating of metal⁃loaded H⁃ZSM⁃22 to form the core⁃shell nanostructures:Characterization,textural properties,and catalytic potency in the esterification of oleic acid[J].International Journal of Chemical Engineering,2021,2021(1):1⁃16. |
31 | Bogomolova T S,Lisitsyn A S,Ayupov A B,et al.Characterization and hydroisomerization performance of Mg⁃promoted,Pt/ZSM⁃23⁃based catalysts[J].European Journal of Inorganic Chemistry,2022,2022(14):85⁃93. |
32 | Chen X Y,Xi H J,Lin M G,et al.Synthesis of Fe⁃ZSM⁃23 zeolite and its catalytic performance for the isomerization of n⁃dodecane[J].International Journal of Hydrogen Energy,2019,44(36):19762⁃19770. |
33 | Saenluang K,Srisuwanno W,Salakhum S,et al.Nanoporous Sn⁃substituted ZSM⁃48 nanostructures for glucose isomerization[J].ACS Applied Nano Materials,2021,4(11):11661⁃11673. |
34 | Zhang J W,Wu H M,Zhao A J,et al.Synthesis of MgAPO⁃31 nanocrystals via different heating methods and their catalytic performance in the hydroisomerization of n⁃decane[J].Journal of Porous Materials,2017,24(2):437⁃442. |
35 | Shang S J,Li W H,Zhou A J,et al.Fe⁃substituted Pt/HZSM⁃48 for superior selectivity of i⁃C12 in n⁃dodecane hydroisomerization[J].Industrial & Engineering Chemistry Research,2022,61(2):1056⁃1065. |
36 | Chen Y J,Li C,Chen X,et al.Synthesis and characterization of iron⁃substituted ZSM⁃23 zeolite catalysts with highly selective hydroisomerization of n⁃hexadecane[J].Industrial & Engineering Chemistry Research,2018,57(41):13721⁃13730. |
37 | Liu S Y,He Y R,Zhang H K,et al.Design and synthesis of Ga⁃doped ZSM⁃22 zeolites as highly selective and stable catalysts for n⁃dodecane isomerization[J].Catalysis Science & Technology,2019,9(11):2812⁃2827. |
38 | Agliullin M,KolyaginY,Serebrennikov D,et al.Acid properties and morphology of SAPO⁃11 molecular sieve controled by silica source[J].Microporous and Mesoporous Materials,2022,338:111962. |
39 | 张芳,吕宏安,卞雯,等.费托轻组分蜡加氢异构催化剂的制备与性能评价[J].工业催化,2022,30(2):58⁃62. |
Zhang F,Lü H A,Bian W,et al.Preparation and performance evaluation of Fischer⁃Tropsch light wax hydroisomerization catalysts[J].Industrial Catalysis,2022,30(2):58⁃62. | |
40 | 韩京京,谭涓,刘靖,等.小晶粒ZSM⁃22的可控合成及其催化长链正构生物烷烃制航空煤油性能[J].化工进展,2022,41(4):1916⁃1924. |
Han J J,Tan J,Liu J,et al.Controllable synthesis of small size ZSM⁃22 zeolites and their performance in the production of bio⁃jet fuel by hydrocracking and hydroisomerization of long⁃chain normal bio⁃paraffins[J].Chemical Industry and Engineering Progress,2022,41(4):1916⁃1924. | |
41 | 黄克旺,方昕,雍晓静,等.微孔分子筛ZSM⁃22的合成及其应用研究进展[J].石油炼制与化工,2020,51(7):104⁃112. |
Huang K W,Fang X,Yong X J,et al.Development in the synthesis and application of microporous molecular sieve ZSM⁃22[J].Petroleum Processing and Petrochemicals,2020,51(7):104⁃112. | |
42 | Sousa L V,Silva A O S,Silva B J B,et al.Fast synthesis of ZSM⁃22 zeolite by the seed⁃assisted method of crystallization with methanol[J].Microporous and Mesoporous Materials,2017,254(1):192⁃200. |
43 | Wang L,Niu P Y,Xi H J,et al.Facile synthesis of size⁃controlled ZSM⁃22 zeolite along the [001] direction via two⁃step crystallization[J].Industrial & Engineering Chemistry Research,2021,60(47):17006⁃17015. |
44 | Zhang L,Fu W Q,He L W,et al.Design and synthesis of Pt catalyst supported on ZSM⁃22 nanocrystals with increased accessible 10⁃MR pore mouths and acidic sites for long⁃chain n⁃alkane hydroisomerization[J].Microporous and Mesoporous Materials,2021,313:110834. |
45 | 黄卫国,方文秀,郭庆洲,等.润滑油异构脱蜡催化剂RIW⁃2的研究与开发[J].石油炼制与化工,2019,50(5):6⁃11. |
Huang W G,Fang W X,Guo Q Z,et al.Research and development of lube hydroisomerization dewaxing catalyst RIW⁃2[J].Petroleum Processing and Petrochemicals,2019,50(5):6⁃11. | |
46 | Molino A,Holzinger J,Lukaszuk K A,et al.Synthesis of ZSM⁃23 (MTT) zeolites with different crystal morphology and intergrowths:Effects on the catalytic performance in the conversion of methanol to hydrocarbons[J].Catalysis Science & Technology,2019,9(23):6782⁃6792. |
47 | Ma D Z,Fu W H,Liu C,et al.Syntheses of MTT⁃type zeolites with the presence of both octyltrimethylammonium chloride and SFE⁃type zeolite seeds[J].ACS Omega,2021,6(36):23598⁃23606. |
48 | Piryutko L V,Parfenov M V,Lysikov A L,et al.Influence of type of organic template on the properties of zeolites ZSM⁃23[J].Russian Journal of Applied Chemistry,2019,92(12):1664⁃1673. |
49 | Smirnova M Y,Piryutko L V,Brester Y S,et al.Effect of the ZSM⁃23 synthesis method on the properties of Pt/ZSM⁃23/Al2O3 catalysts inn⁃decane conversion[J].Petroleum Chemistry,2020,60(2):212⁃218. |
50 | Chen Y J,Li C,Chen X,et al.Synthesis of ZSM⁃23 zeolite with dual structure directing agents for hydroisomerization of n⁃hexadecane[J].Microporous and Mesoporous Materials,2018,268:216⁃224. |
51 | 张瑀健,翟绪丽,付凯妹,等.短轴纳米ZSM⁃23的合成及异构化性能[J].高等学校化学学报,2017,38(2):231⁃237. |
Zhang Y J,Zhai X L,Fu K M,et al.Synthesis of nano ZSM⁃23 zeolites with low L/D value morphology and their hydroisomerization performance[J].Chemical Journal of Chinese Universities,2017,38(2):231⁃237. | |
52 | Chen X J,Xi H,Chen C,et al.Synthesis of ZSM⁃23 zeolite by two⁃stage temperature⁃varied crystallization and its isomerization performance[J].Applied Sciences,2020,10(21):7546. |
53 | 郭守敬,白天忠,梁雪美,等.润滑油基础油脱蜡技术研究进展[J].当代化工,2022,51(6):1496⁃1499. |
Guo S J,Bai T Z,Liang X M,et al.Research progress of lubricant base oil dewaxing technology[J].Contemporary Chemical Industry,2022,51(6):1496⁃1499. | |
54 | 付凯妹,李雪静,郑丽君,等.润滑油基础油加氢异构技术研究进展[J].石化技术与应用,2021,39(2):138⁃142. |
Fu K M,Li X J,Zheng L J,et al.Research progress on hydroisomerization technology of lube base oil[J].Petrochemical Technology & Application,2021,39(2):138⁃142. | |
55 | Wang R,Peng Z,Wu P,et al.Direct synthesis of nanorod stacked "nest⁃like" hierarchical ZSM⁃48 hollow spheres using a triazine⁃based bolaform organic structure⁃directing agent[J].Inorganic Chemistry Frontiers,2022,9(9):2016⁃2022. |
56 | Sadrara M,Khorrami M K,Darian J T,et al.Fabrication of highly mesoporous ZSM⁃48 zeolite by anionic surfactant⁃organosilane system for catalytic conversion of methanol to gasoline[J].Solid State Sciences,2022,128:106888. |
57 | Zhao G L,Teng J W,Zhang Y H,et al.Synthesis of ZSM⁃48 zeolites and their catalytic performance in C⁃4⁃olefin cracking reactions[J].Applied Catalysis A⁃General,2006,299:167⁃174. |
58 | Meng J P,Li C,Chen X,et al.Seed⁃assisted synthesis of ZSM⁃48 zeolite with low SiO2/Al2O3 ratio for n⁃hexadecane hydroisomerization[J].Microporous and Mesoporous Materials,2020,309:110565. |
59 | 向江南,刘伟,刘成连,等.低硅铝比ZSM⁃48分子筛合成及其正构十二烷临氢异构催化性能研究[J].燃料化学学报,2020,48(1):83⁃90. |
Xiang J N,Liu W,Liu C L,et al.Synthesis and hydroisomerization performance ofn⁃C12 over ZSM⁃48 molecular sieve with low silicon⁃aluminum ratio[J].Journal of Fuel Chemistry and Technology,2020,48(1):83⁃90. | |
60 | Zhai M,Ding H X,Zeng S,et al.Aluminous ZSM⁃48 zeolite synthesis using a hydroisomerization intermediate mimicking allyltrimethylammonium chloride as a structure⁃directing agent[J].Industrial & Engineering Chemistry Research,2020,59(24):11139⁃11148. |
61 | 唐静思,高禾鑫,孔庆岚,等.利用β沸石废液为部分营养物质合成低硅铝比多级孔ZSM⁃48分子筛[J].石油学报(石油加工),2017,33(2):227⁃233. |
Tang J S,Gao H X,Kong Q L,et al.Synthesis of alumina⁃rich hierarchical ZSM⁃48 by using waste liquor of as⁃synthesized beta zeolite as a partial nutrient[J].Acta Petrolei Sinica (Petroleum Processing Section),2017,33(2):227⁃233. | |
62 | Meng J P,Bai D,Zeyaodong P,et al.Hydroisomerization of n⁃hexadecane over Pt/ZSM⁃48 catalysts:Effects of metal⁃acid balance and crystal morphology[J].Microporous and Mesoporous Materials,2022,330:111637. |
63 | 黄小珠,王泽爱,宫卫国,等.费托合成基础油加工技术研究进展[J].化工进展,2016,35(s1):135⁃140. |
Huang X Z,Wang Z A,Gong W G,et al.Research progress of the processing technology for lube base oils prepared from Fischer⁃Tropsch syncrude[J].Chemical Industry and Engineering Progress,2016,35(s1):135⁃140. | |
64 | 李悦,于跃,葛云晓,等.SAPO⁃11分子筛合成方法研究进展[J].现代盐化工,2019,46(4):5⁃6. |
Li Y,Yu Y,Ge Y X,et al.Research progress in synthesis of SAPO⁃11 molecular sieves[J].Modern Salt and Chemical Industry,2019,46(4):5⁃6. | |
65 | 吕玉超,于洙末,战威龙,等.原位干胶合成Ni/SAPO⁃11催化剂中硅含量及配位环境的调控[J].石油学报(石油加工),2021,37(6):1366⁃1377. |
Lü Y C,Yu Z M,Zhan W L,et al.Regulation of silicon content and coordination environments over Ni/SAPO⁃11 catalyst synthesized via in⁃situ dry gel conversion method[J].Acta Petrolei Sinica (Petroleum Processing Section),2021,37(6):1366⁃1377. | |
66 | Liu Y X,Lyu Y C,Zhao X X,et al.Silicoaluminophosphate⁃11 (SAPO⁃11) molecular sieves synthesized via a grinding synthesis method[J].Chemical Communications,2018,54(78):10950⁃10953. |
67 | Yuan Z,Cheng Y,Ma S,et al.Instant exactness synthesis andn⁃heptane hydroisomerization of high performance Ni/SAPO⁃11 catalyst[J].Journal of Porous Materials,2020,27(5):1455⁃1466. |
68 | Dai X J,Cheng Y,Wei Q,et al.Small⁃crystal and hierarchical SAPO⁃11 molecular sieve synthesized via three⁃stage crystallization method and hydroisomerization performance of corresponding NiWS supported catalyst[J].Fuel,2022,324:124610. |
69 | Zhang P,Liu H Y,Yue Y Y,et al.Direct synthesis of hierarchical SAPO⁃11 molecular sieve with enhanced hydroisomerization performance[J].Fuel Processing Technology,2018,179:72⁃85. |
70 | 韩嘉宝,曹勃.润滑油加氢催化剂及工艺技术进展[J].石油炼制与化工,2022,53(4):17⁃23. |
Han J B,Cao B.Advances in catalysts and processes for lubricating oil hydrogenation[J].Petroleum Processing and Petrochemicals,2022,53(4):17⁃23. | |
71 | Ma M,Huang X M,Zhan E S,et al.Synthesis of mordenite nanosheets with shortened channel lengths and enhanced catalytic activity[J].Journal of Materials Chemistry A,2017,5(19):8887⁃8891. |
72 | Nada M H,Larsen S C,Gillan E G.Mechanochemically⁃assisted solvent⁃free and template⁃free synthesis of zeolites ZSM⁃5 and mordenite[J].Nanoscale Advances,2019,1(10):3918⁃3928. |
73 | Xiao T,Yabushita M,Nishitoba T,et al.Organic structure⁃directing agent⁃free synthesis of mordenitetype zeolites driven by Al⁃rich amorphous aluminosilicates[J].ACS Omega,2021,6(8):5176–5182. |
74 | Ibrahim M,Jalil A A,Zakaria W F W,et al.n⁃Hexane hydroisomerization over Zr⁃modified bicontinuous lamellar silica mordenite supported Pt as highly selective catalyst:Molecular hydrogen generated protonic acid sites and optimization[J].International Journal of Hydrogen Energy,2021,46(5):4019⁃4035. |
75 | Cheng K,van der Wal L,Yoshida H,et al.Impact of the spatial organization of bifunctional metal⁃zeolite catalysts on the hydroisomerization of light alkanes[J].Angewandte Chemie⁃International Edition,2020,59(9):3592⁃3600. |
76 | 陈治平,王苗苗,韦晓艺,等.复合分子筛在烃类异构化反应中的应用研究进展[J].化工进展,2022,41(5):2404⁃2415. |
Chen Z P,Wang M M,Wei X Y,et al.Application of composite molecular sieve in hydrocarbon isomerization[J].Chemical Industry and Engineering Progress,2022,41(5):2404⁃2415. | |
77 | 宋成业,孟记朋,李闯,等.ZSM⁃22/ZSM⁃23共晶分子筛的合成及其正十六烷加氢异构催化性能[J].燃料化学学报,2021,49(5):712⁃726. |
Song C Y,Meng J P,Li C,et al.Synthesis of ZSM⁃22/ZSM⁃23 intergrowth zeolite as the catalyst support for hydroisomerization ofn⁃hexadecane[J].Journal of Fuel Chemistry and Technology,2021,49(5):712⁃726. | |
78 | Munusamy K,Das R,Ghosh S,et al.Synthesis,characterization and hydroisomerization activity of ZSM⁃22/23 intergrowth zeolite[J].Microporous and Mesoporous Materials,2018,266(1):141⁃148. |
79 | 孙娜,王海彦,马宇翔,等.MOR@SAPO⁃11复合分子筛的合成及Pt/MOR@SAPO⁃11催化剂的加氢异构化性能[J].石油学报(石油加工),2019,35(6):1175⁃1182. |
Sun N,Wang H Y,Ma Y X,et al.Synthesis of MOR@SAPO⁃11 composite molecular sieve and the hydroisomerization evaluation of Pt/MOR@SAPO⁃11 catalyst[J].Acta Petrolei Sinica (Petroleum Processing Section),2019,35(6):1175⁃1182. | |
80 | Sun N,Wang H Y,Ma Y X,et al.Synthesis of MOR/SAPO⁃11 composite molecular sieve via seed crystallization for n⁃alkane hydroisomerization[J].China Petroleum Processing & Petrochemical Technology,2019,21(2):58⁃66. |
81 | Chang T,Liu S.Role of the mesoporous diameters of hierarchical ZSM⁃22/MCM⁃41 zeolite for n⁃alkane isomerization[J].Molecular Catalysis,2021,503:111420. |
82 | Liu S Y,Zhang L,Zhang L W,et al.Function of well⁃established mesoporous layers of recrystallized ZSM⁃22 zeolites in the catalytic performance of n⁃alkane isomerization[J].New Journal of Chemistry,2020,44(12):4744⁃4754. |
83 | Zhang J T,Song J,Zhen X,et al.Synthesis of MCM⁃41/MOR composite molecular sieves and its catalytic properties for isomerization of alkane[J].Journal of Fuel Chemistry and Technology,2017,45(6):675⁃681. |
84 | Pirutko L V,Parfenov M M V,Lysikov A I,et al.Synthesis of micro⁃mesoporous ZSM⁃23 zeolite[J].Petroleum Chemistry,2021,61(3):276⁃283. |
85 | He L W,Fu W Q,Li L Y,et al.Study of CA⁃treated ZSM⁃22 zeolite with enhanced catalytic performance in the hydroisomerization of long⁃chain n⁃dodecane[J].New Journal of Chemistry,2021,45(5):2820⁃2829. |
86 | Silva B J B,Sousa L V,Sarmento L P A,et al.Effect of coke deposition over microporous and hierarchical ZSM⁃23 zeolite[J].Journal of Thermal Analysis and Calorimetry,2022,147(4):3161⁃3170. |
87 | Lu X Q,Guo Y P,Xu C H,et al.Preparation of mesoporous mordenite for the hydroisomerization of n⁃hexane[J].Catalysis Communications,2019,125:21⁃25. |
88 | Meng J P,Cui T Y,Bai D,et al.Excellent catalytic performance over hierarchical ZSM⁃48 zeolite:Cooperative effects of enhanced mesoporosity and highly⁃accessible acidity[J].Fuel,2022,324:124589. |
89 | Li H R,Liu C L,Wang Y,et al.Synthesis,characterization and n⁃hexane hydroisomerization performances of Pt supported on alkali treated ZSM⁃22 and ZSM⁃48[J].RSC Advances,2018,8(51):28909⁃28917. |
90 | Zhang M,Li C,Chen X,et al.Hierarchical ZSM⁃48⁃supported nickel catalysts with enhanced hydroisomerization performance of hexadecane[J].Industrial & Engineering Chemistry Research,2019,58(43):19855⁃19861. |
91 | Pablo C,Pablo B,Fernando R,et al.Influence of post⁃synthetic modifications on the composition,acidity and textural properties of ZSM⁃22 zeolite[J].Catalysis Today,2018,299:120⁃134. |
92 | Wang X Y,Zhang X W,Wang Q F.n⁃Dodecane hydroisomerization over hierarchical ZSM⁃22 prepared by a dual⁃protected alkali treatment[J].Industrial & Engineering Chemistry Research,2019,58(19):8495⁃8505. |
93 | Bolshakov A,Hidalgo D,van Hoof A,et al.Mordenite nanorods prepared by an inexpensive pyrrolidine⁃based mesoporogen for alkane hydroisomerization[J].ChemCatChem,2019,11(12):1⁃10. |
94 | Astafan A,Benghalem M A,Michelin L,et al.Synthesis of hierarchical ZSM⁃48 nano⁃zeolites[J].New Journal of Chemistry,2018,42(6):4457⁃4464. |
95 | Zhang Y J,Ma Y H,Che S A.Synthesis of lamellar mesostructured ZSM⁃48 nanosheets[J].Chemistry of Materials,2018,30(6):1839⁃1843. |
96 | Wang X Y,Zhang X W,Wang Q F.Fabrication of hierarchical ZSM⁃22 hollow sphere[J].Materials Letters,2019,244(1):96⁃99. |
97 | Supak T,Stefan E,Christian W.Hybrid nanotube assembly and hierarchical ZSM⁃23 zeolite synthesized with cationic polymer and enhanced performance in n⁃heptane hydroisomerization[J].ChemNanoMat,2020,6(9):1398⁃1406. |
98 | Kadja G T M,Azhari N J,Mardiana S,et al.Accelerated,mesoporogen⁃free synthesis of hierarchical nanorod ZSM⁃48 assisted by hydroxyl radicals[J].Industrial & Engineering Chemistry Research,2021,60(48):17786⁃17791. |
[1] | 李声笛, 肖海成, 吴志杰. 费托合成Co基催化剂的研究进展[J]. 石油化工高等学校学报, 2024, 37(1): 34-42. |
[2] | 王钰佳,岳 元,卢 聪,魏 民. 多级孔Hβ分子筛NiWP催化剂#br# 的制备与加氢脱芳性能[J]. 石油化工高等学校学报, 2016, 29(2): 13-17. |
阅读次数 | ||||||
全文 |
|
|||||
摘要 |
|
|||||
网站版权 © 2024《石油化工高等学校学报》编辑部
地址:辽宁省抚顺市望花区丹东路西段1号 电话:024-56860967 E-mail:lnxuebao@126.com 邮编:113001
本系统由北京玛格泰克科技发展有限公司设计开发