Study on reaction characteristics of phenolic hydroxyl in coal by using the model compound during direct coal liquefaction 被引量：3

Study on reaction characteristics of phenolic hydroxyl in coal by using the model compound during direct coal liquefaction

下载PDF

导出

摘要 The reaction characteristics of phenolic hydroxyl group were studied under the conditions of direct coal liquefaction. 2-naphthol was used as a coal model compound in this study. Under the conditions of with and without catalysts, a series of experiments were conducted at different temperatures, pressures and reaction time. Gas chromatography-mass spectrometry and gas chromatography were used to identify and quantify the reactants and products respectively. The conversion of 2-naphthol rises with the increase of reaction temperature, initial pressure and catalyst amount. The results indicated that tem- perature had a significant effect on 2-naphthol conversion, which promoted the dehydroxylation reaction. However, initial pressure had an important influence on the hydrogenation of 2-naphthol and naphthalene. The iron catalyst plays a significant role of cracking instead of hydrogenation. It is concluded that the harsh reaction conditions of high temperature, high pressure, and more catalyst are conducive to promoting dehydroxylation of 2-naphthol. The reaction mechanism was put forward based the experimental results, in which 2-tetralone was an intermediate.

作者 Bo-Wen MA Xiao-Su ZHU Wen-Bo LI Xiao-Jing ZHANG Shu-Feng DU

机构地区 State Key Laboratory of Coal Mining and Clean Utilization Beijing Research Institute of Coal Chemistry

出处《Journal of Coal Science & Engineering(China)》 2013年第4期540-545,共6页 煤炭学报（英文版）

关键词 direct coal liquefaction model compound phenolic hydroxyl reaction characteristics direct coal liquefaction model compound phenolic hydroxyl reaction characteristics

分类号 O629.8 [理学—有机化学] TQ529.1 [化学工程—煤化学工程]

引文网络
相关文献

参考文献12

1Hei R D, Sweeny PG, Stenberg V I, 1986. Mechanism of the hydrogen-sulphide-promoted cleavage of the coal model compounds: diphenyl ether, diphenylmethane and biben- zyl. Fuel, 65:577-585.
2Hirota T, Nomura M, Song C, 1989. A method for manufacture of aromatic chemicals from coals. Japanese Patent, 1-279990.
3Kodera Y, Ukegawa K, Matsumura A, Ma X, 1993. Methanol- mediated extraction process for the separation of phenolic compounds from coal liquids. Fuel, 72: 57.
4McMillen D F, Malhotra R, Chang S J, Nigenda S E, John G A, 2004. Coupling pathways for dihydroxy aromatics during coal pyrolysis and liquefaction. Fuel, 83: 1455-1467.
5Nomura M, Moritaka S, Miura M, 1995. Catalytic dehydroge- nation of coal liquefied products: an alternative route produce naphthalene from coal. Energy & Fuels, 9: 936.
6Cypre R, 1987. Aromatic hydrocarbons formation during coal pyrolysis. Fuel Processing Technology, 15: 1-15.
7Schobert H H, Song C, 2002. Chemicals and materials from coal in the 21st century. Fuel, 81:15-32.
8Sharma R K, Raman KP, Miller B, 1986. Catalysis of cleavage of di-[3-naphthyl ether by electron-donating agents: an ex- planation for the effectiveness of phenols as promoters for coal conversion. Fuel, 65:738 739.
9Shukla Y V, 1985. Catalytic hydrodeoxygenation studies of aromatic ethers, phenols and oxygen-rich synfuels. Doc- tor's thesis, University of Utah.
10Siskin M, Aczel T, 1983. Pyrolysis studies on the structure of ethers and phenols in coal. Fuel, 62: 1321.

同被引文献29

1魏贤勇,宗志敏,孙林兵,秦志宏,赵炜.重质碳资源高效利用的科学基础[J].化工进展,2006,25(10):1134-1142. 被引量：27
2李军,冯耀声.超临界二氧化碳萃取茶多酚的研究[J].天然产物研究与开发,1996,8(3):42-47. 被引量：36
3谢崇禹.煤液化用煤种的选择研究[J].当代化工,2007,36(2):189-191. 被引量：5
4朱晓苏.中国煤炭直接液化优选煤种的研究[J].煤化工,1997(3):32-39. 被引量：31
5黄珏,张德祥,蔺华林,高晋生.云南先锋褐煤液化轻质油的分析[J].石油化工,2008,37(11):1206-1210. 被引量：10
6毛学锋,陈颖,胡发亭.煤炭直接液化油中酚类化合物的分离与利用[J].洁净煤技术,2008,14(6):39-42. 被引量：7
7毛学锋,李文博,高振楠,谷小会,杜淑凤,史士东.工艺条件对煤液化油中酚类化合物的影响研究[J].煤炭转化,2010,33(1):26-30. 被引量：13
8高振楠.煤液化油中酚类化合物的提取利用研究[J].煤炭学报,2010,35(7):1188-1192. 被引量：8
9张伟,王再义,王相力,张宁.日本神户制钢UBC工艺的开发[J].洁净煤技术,2010,16(4):63-66. 被引量：4
10叶翠平,冯杰,李文英,张志红.固相萃取法富集煤抽提物中的酚类化合物[J].太原理工大学学报,2010,41(5):661-665. 被引量：9

引证文献3

1马博文,李文博,朱晓苏,毛学锋,赵鹏.煤液化油中低级酚生成的影响因素研究[J].煤化工,2014,42(3):22-25. 被引量：2
2李文英,李旺,冯杰.褐煤直接液化过程中存在的问题与思考[J].煤炭学报,2020,45(1):414-423. 被引量：18
3马博文.溶剂供氢性对艾丁低阶煤直接液化低级酚生成的影响研究[J].煤质技术,2020,35(4):48-51. 被引量：1

二级引证文献21

1陈庭胜,杜朕屹.多级孔ZSM-5分子筛催化异丙基苯酚脱烷基反应研究[J].现代化工,2020,40(S01):92-97. 被引量：1
2梁江朋.SO_4^(2-)/Fe_2O_3固体酸催化艾丁褐煤直接液化反应性研究[J].煤炭学报,2018,43(12):3518-3524. 被引量：3
3佟瑞利,杨卓,鲁波娜,冯留海,杜冰,赵用明,卜亿峰,门卓武.工艺条件对费托铁基催化剂气固流化特性的影响[J].煤炭学报,2020,45(4):1282-1289. 被引量：2
4杜冰,卜亿峰,孟祥堃,赵用明,谢晶,门卓武.CNFT-1费托合成催化剂长周期运行性能研究[J].煤炭学报,2020,45(4):1290-1296. 被引量：4
5黄恪,朱超,师楠,温福山,王韶华,吴雷,刘东.Pt-MOR/MCM-41催化剂制备与加氢异构化评价[J].煤炭学报,2020,45(4):1304-1311.
6梁江朋.艾丁褐煤直接液化产物中酚类形成影响因素研究[J].洁净煤技术,2020,26(4):98-103.
7谢瑞伦,张侠,田誉娇.锡林浩特褐煤萃取-反萃取产物的氧化解聚[J].安徽工业大学学报（自然科学版）,2020,37(4):345-350.
8鄢僖,汪云川,唐博,葛方秋.褐煤在壳牌气化工艺下行水激冷气化装置中的应用[J].盐科学与化工,2020,49(12):38-41.
9赵云鹏,司兴刚,赵薇,曹景沛,魏贤勇.Co/Al2O3催化褐煤衍生模型化合物的加氢脱氧制单体烃类化合物[J].燃料化学学报,2021,49(2):160-167.
10田宏,肖志红,李昌珠,吴红,黎继烈,谢益仙.生物质溶剂液化研究进展[J].湖南林业科技,2021,48(1):76-82. 被引量：1

1Xiao-Man ZHU Pei-Lin LI Shu-Feng DU.Determination of the gas compositions for direct coal liquefaction by gas chromatography[J].Journal of Coal Science & Engineering(China),2013,19(4):535-539. 被引量：1
2姜元博,李群花,施力.煤直接液化油品组分分析研究进展[J].理化检验（化学分册）,2014,50(10):1324-1328. 被引量：4
3乔建超,王建平,盛清涛,申峻,凌开成.由煤制取芳烃化合物的研究进展[J].化工进展,2012,31(8):1717-1720. 被引量：5
4杨建丽,胡天斗,等.EXAFS和SAXS在煤直接液化催化剂表征中的应用[J].北京同步辐射装置年报,1998(1):81-84.
5李伟,申峻,侯丽红,凌开成.煤直接液化过程中酚类的转化规律及检测方法[J].现代化工,2011,31(7):92-95. 被引量：2
6潘业翔.浅谈气相色谱法快速炼厂气分析[J].内蒙古石油化工,2016,42(5):60-64. 被引量：1
7朱继升,杨建丽,等.煤直接液化原位担载铁催化剂的表征[J].北京同步辐射装置年报,2000(1):65-68.
8单贤根,王秀辉,江洪波,翁惠新,章序文,李克健.煤直接液化升温阶段气体产物组成关联模型[J].化学反应工程与工艺,2015,31(2):123-128.
9朱继升,胡天斗,等.煤直接液化担载铁催化剂的XRD和EXAFS表征[J].北京同步辐射装置年报,2000(1):69-74.
10李群花,姜元博,胡慧廉,吴婷,杜一平,李克健.气相色谱-质谱结合活数据库法测定煤直接液化加氢改质油中C7C9馏分的组成[J].理化检验（化学分册）,2014,50(9):1086-1091. 被引量：2

Journal of Coal Science & Engineering(China)

2013年第4期

浏览历史

内容加载中请稍等...

Study on reaction characteristics of phenolic hydroxyl in coal by using the model compound during direct coal liquefaction 被引量：3

参考文献12

同被引文献29

引证文献3

二级引证文献21

相关作者

相关机构

相关主题

浏览历史