煤液化油中芳烃/环烷烃分离规律及其机理研究
|
摘要
以煤为原料生产液体燃料是缓解我国燃料短缺的有效途径。煤液化油粗油的主要组成为芳烃及其衍生物(60~70%),其次为饱和烃(25%)、烯烃以及杂原子化合物(不到10%)。芳烃及其衍生物具有密度高、低反应性的特点,如将煤液化油直接用作液体燃料,芳烃及其衍生物在高温下容易裂解发生结焦,增加的固体沉积物会使燃料热稳定性变差,为此,各国都对燃料中的芳烃含量限定一定范围(通常<18%)。煤液化油中芳烃同其他组分的分离富集成为煤液化油精制的一个重要内容。将煤直接液化粗油中的芳烃进行有效的分离,可以控制液化油中芳烃含量、优化燃料性能、降低液化油粗油精制过程的氢耗。
为研究煤液化油中芳烃分离的方法、分离过程机理及传质规律,形成液体产物萃取分离理论和绿色工艺,实现对煤液化油加氢精制生产液体燃料油品质的提升,本研究选择神华煤直接液化油粗油中油馏分中富含芳烃和环烷烃的(200~220℃)馏分段,并通过对其GC/MS测定的数据分析,以其中含量较高的甲苯和甲基环己烷作为芳烃和环烷烃的替代模型化合物研究分离过程。
以γ-丁内酯为萃取剂,通过液液相平衡实验,绘制了三元体系溶解度相图,对Y-丁内酯在甲苯/甲基环己烷中的溶解性进行了测定,发现其选择性良好。利用汽液平衡装置进行了三元汽液平衡实验,对不同分离条件下甲苯、甲基环己烷和γ-丁内酯进行三元汽液平衡测定,发现在溶剂比为0.5:1~1:1范围内,甲苯含量为60%以内(甲苯甲基环己烷混合液中甲苯的体积分数)时分离效果较好。应用Aspen计算三元混合体系中二元交互作用系数,得到甲苯和γ-丁内酯之间交互系数最大,即偏离理想程度比较大,归其主要原因在于分子间作用力的不同,并通过量子化学计算,证实分离过程的本质为分子间作用力。甲基环己烷、甲苯由于和γ-丁内酯分子间相互作用力不同,因而γ-丁内酯的加入影响了相对挥发度的改变,进而使目标混合物得到分离。
Producing liquid fuel from raw coal is analternative method to alleviate shortage of liquid fuel. The main composition of coal liquefied oil are aromatic hydrocarbon and its derivatives(60-70%), saturated hydrocarbon(25%), olefin and heteroatomic compound(<10%). For the higher density and lower reactivity, aromatic hydrocarbon and its derivatives largely existing in coal liquefied oil are easily to be cracked and coke under high temperature if the coal liquefied oil used as liquefied fuel directly. As a result, various countries set the value of 18% as maximum content of aromatic hydrocarbon in fuel. Thus, separating or enriching aromatic hydrocarbonof coal liquid effectively is critical work of coal liquefied oil purification, which can improve conversion rates of aromatic hydrocarbon, control content of aromatic hydrocarbon, optimize properties of fuel and decrease hydrogen consumption.
In order to study approach of separation process, methylbenzene and methylcyclohexane, which riched in the 200~220℃fractions of Shenhua coal liquefied oil, was selected as model compounds to study the phase equilibrium rules of the extracting agent.
Usingγ-butyrolactone as an extraction agent, the ternary equilibrium phase of methylenenzene and mehtylcyclohexane was diagramed. Furthermore, the amount ofγ-butyrolactone used in extraction was calculated based on the ternary diagram. The equilibrium parameters were measured by D-B apparatus in the different experiment condition. The results showed the best separation was at the solvent ratio of 0.5:1 and toluene less than 60%. According to the caculation of Aspen, the coefficient of these three mixture phase was the most existed between toluene andγ-butyrolactone. It is proved by the quantum chemistry calculation that the separation mechanism was from the inter-molecular force. Different steric hindrance of methylcyclohexane and toluene leads to different inter-molecular force withγ-butyrolactone and the changes of relative volatility. These results in the separation of toluene and methylcyclohexane easily.
为研究煤液化油中芳烃分离的方法、分离过程机理及传质规律,形成液体产物萃取分离理论和绿色工艺,实现对煤液化油加氢精制生产液体燃料油品质的提升,本研究选择神华煤直接液化油粗油中油馏分中富含芳烃和环烷烃的(200~220℃)馏分段,并通过对其GC/MS测定的数据分析,以其中含量较高的甲苯和甲基环己烷作为芳烃和环烷烃的替代模型化合物研究分离过程。
以γ-丁内酯为萃取剂,通过液液相平衡实验,绘制了三元体系溶解度相图,对Y-丁内酯在甲苯/甲基环己烷中的溶解性进行了测定,发现其选择性良好。利用汽液平衡装置进行了三元汽液平衡实验,对不同分离条件下甲苯、甲基环己烷和γ-丁内酯进行三元汽液平衡测定,发现在溶剂比为0.5:1~1:1范围内,甲苯含量为60%以内(甲苯甲基环己烷混合液中甲苯的体积分数)时分离效果较好。应用Aspen计算三元混合体系中二元交互作用系数,得到甲苯和γ-丁内酯之间交互系数最大,即偏离理想程度比较大,归其主要原因在于分子间作用力的不同,并通过量子化学计算,证实分离过程的本质为分子间作用力。甲基环己烷、甲苯由于和γ-丁内酯分子间相互作用力不同,因而γ-丁内酯的加入影响了相对挥发度的改变,进而使目标混合物得到分离。
Producing liquid fuel from raw coal is analternative method to alleviate shortage of liquid fuel. The main composition of coal liquefied oil are aromatic hydrocarbon and its derivatives(60-70%), saturated hydrocarbon(25%), olefin and heteroatomic compound(<10%). For the higher density and lower reactivity, aromatic hydrocarbon and its derivatives largely existing in coal liquefied oil are easily to be cracked and coke under high temperature if the coal liquefied oil used as liquefied fuel directly. As a result, various countries set the value of 18% as maximum content of aromatic hydrocarbon in fuel. Thus, separating or enriching aromatic hydrocarbonof coal liquid effectively is critical work of coal liquefied oil purification, which can improve conversion rates of aromatic hydrocarbon, control content of aromatic hydrocarbon, optimize properties of fuel and decrease hydrogen consumption.
In order to study approach of separation process, methylbenzene and methylcyclohexane, which riched in the 200~220℃fractions of Shenhua coal liquefied oil, was selected as model compounds to study the phase equilibrium rules of the extracting agent.
Usingγ-butyrolactone as an extraction agent, the ternary equilibrium phase of methylenenzene and mehtylcyclohexane was diagramed. Furthermore, the amount ofγ-butyrolactone used in extraction was calculated based on the ternary diagram. The equilibrium parameters were measured by D-B apparatus in the different experiment condition. The results showed the best separation was at the solvent ratio of 0.5:1 and toluene less than 60%. According to the caculation of Aspen, the coefficient of these three mixture phase was the most existed between toluene andγ-butyrolactone. It is proved by the quantum chemistry calculation that the separation mechanism was from the inter-molecular force. Different steric hindrance of methylcyclohexane and toluene leads to different inter-molecular force withγ-butyrolactone and the changes of relative volatility. These results in the separation of toluene and methylcyclohexane easily.
引文
[1]江冰.2015年煤炭占一次能源比重比2009年降幅约7%[DB/OL]. ,2009.
[2]朱肖曼.煤液化油基本性质的研究[D].北京:煤炭科学研究总院,2006.
[3]张琪,白雪松,张晓东.对我国喷气燃料进出口的特点分析及建议[J].化学工业,2009,(003):7-10.
[4]王梦奎.关于“十二五”时期的发展[J].政策解读,2011,(01):6-10.
[5]李好管.煤直接液化技术进展及前景分析[J].煤化工,2002,30(003):8-12.
[6]杜岩.柴油芳烃加氢饱和及环烷烃开环的研究[D].天津:天津大学,2007.
[7]舒歌平,史士东,李克健.煤炭液化技术[M].北京:煤炭工业出版社,2003.
[8]崔之栋,李嘉珞.煤炭液化[M].大连:大连理工大学出版社,1993.
[9]王永刚,周建明,王彩红,杨正伟.先锋煤和神华煤直接液化油的组成[J].煤炭学报,2006,31(001):81-84.
[10]王永刚,王彩红,杨正伟,董敏.典型中国煤直接液化油组成特征研究[J].JOURNAL OF CHINA UNIVERSITY OF MINING & TECHNOLOGY,2009,38(1):96-100.
[11]宫万福,田松柏,付晓恒.分析技术在煤液化油分析中的应用[J].洁净煤技术,2004,10(002):47-52.
[12]魏贤勇,宗志敏,秦志宏,陈茺.煤液化化学[M].北京:科学出版社,2002.
[13]薛艳,王树雷,刘婕.煤直接液化制取喷气燃料原料油的组成分析[J]. ACTA PETROLEI SINICA (PETROLEUM PROCESSING SECTION),26(zl):264-267.
[14]吴秀章,石玉林,徐春明.煤炭直接液化油品加氢改质中试研究[J].石油学报:石油加工,2009,25(002):156-161.
[15]蔺华林,张德祥,高晋生.煤加氢液化制取芳烃研究进展[J].煤炭转化,2006,29(002):92-98.
[16]冯利利,朱岳麟,倪建成,熊常健.高密度高安定性喷气燃料的制备及性能[J].石油化工高等学校学报,2006,19(3):15-18.
[17]王德岩.高热安定性喷气燃料jp900制备及性能[J].能源研究与信息,2006,22(004):232-236.
[18]李艳红,王升宝,常丽萍.煤液化产品的分析和提质加工技术[J].科技情报开发与经济,2006,16(021):179-180.
[19]李克健,史士东.德国igor煤液化工艺及云南先锋褐煤液化[J].煤炭转化,2001,24(003):13-16.
[20]吴秀章,石玉林,马辉.煤炭直接液化油品加氢稳定和加氢改质的试验研究[J].石油炼制与化工,2009,(005):1-5.
[21]马筱良,薛宗佑.精制煤液化中油加氢裂化制取喷气燃料的研究[J].燃料化学学报,1989,17(004):296-301.
[22]邱泽锋.煤直接液化技术及其液化粗质油和精制油特点[J].浙江化工,2009,40(006):26-29.
[23]李春凤,张雪梅,张志刚,张卫江.间歇萃取精馏分离苯-环己烷[J].化学工业与工程,2005,22(006):422-426.
[24]郑英峨,蔡锐.用n—甲酰吗啉萃取精馏分离苯加氢油中的烷烃[J].燃料与化工,1997,28(002):90-93.
[25]王孝科,田敉.加盐萃取精馏分离苯-环己烷[J].化学工程,2009,37(003):9-12.
[26]Garcia Villaluenga J., Tabe-Mohammadi A. A review on the separation of benzene/cyclohexane mixtures by pervaporation processes [J]. Journal of Membrane Science,2000,169(2):159-174.
[27]周勇,吴礼光,蔡邦肖,高从阶.Pva/pvp/ag^+共混膜渗透汽化分离苯/环己烷混合物[J].膜科学与技术,2003,23(005):52-55.
[28]Quiggle D., Fenske M. Vapor liquid equilibria of methylcyclohexane toluene mixtures [J]. Journal of the American Chemical Society,1937,59(10):1829-1832.
[29]叶宏,李继定,林阳政,陈剑,陈翠仙.渗透汽化芳烃/烷烃分离膜材料[J].化学进展,2008,20(002):288-299.
[30]张志刚,鲁盼,韩银成.三元混合溶剂间歇萃取精馏分离苯-环己烷[J].沈阳化工学院学报,2009,23(003):217-221.
[31]王孝科,田敉.离子液体萃取精馏分离苯-环己烷物系[J]. PETROCHEMICAL TECHNOLOGY,2008,37(9):905-909.
[32]雷志刚,周荣琪.Nmp萃取精馏分离芳烃和非芳烃[J].高校化学工程学报,2001,15(002):183-186.
[33]Berg L. Separation of toluene from non-aromatic hydrocarbons by extractive distillation. 1982, Google Patents.
[34]贾绍义,柴诚敬.化工传质与分离过程[M].北京:化学工业出版社,2001.
[35]邓修,吴俊生.化工分离过程[M].北京::科学出版社,2000.
[36]李雪梅.液液扩散和气液界面传质的研究[D].天津:天津大学,2007.
[37]管国锋,赵汝溥.化工原理[M].北京:化学工业出版社,2003.
[38]Nernst W. Theoretical chemistry [M].1904.
[39]Azbel D., Kemp-Pritchard P. Two-phase flows in chemical engineering [M]. Cambridge Univ Pr,1981.
[40]高习群.气液界面传质机理与强化[D].天津:天津大学,2008.
[41]张东翔,谭世语,黄会清.传质体系界面过程研究进展[J].重庆大学学报:自然科学版,2001,24(002):137-142.
[42]成弘.强化汽液两相传质的研究进展[J].2001:315-322.
[43]余国琼.蒸馏过程和设备的现状与展望[J].化学工程,1992,20(002):20-25.
[44]Emmert R., Pigford R. A study of gas absorption in falling liquid films [J]. Chem. Eng. Prog,1954,50(2): 87-93.
[45]Danckwerts P., Kennedy A. Kinetics of liquid-film process in gas absorption. Part i: Models of the absorption process [J]. Trans. Instn. Chem. Engrs,1954,32:49-53.
[46]苗容生,王树楹.运动气泡近界面湍流场的激光测量及其湍流结构特性[J].化工学报,1992,43(5):570-576.
[47]马友光,余国琮,何明霞.多组分相际传质近界面浓度场的测定[J].化工学报,1994,45(5):636-636.
[48]Sherwood T. Rl pigford, and cr wilke, mass transfer.1975, McGraw-Hill, Inc, New York.
[49]顾正桂,林军.乙酸乙酯和水萃取精馏分离溶剂的研究[J].南京师范大学学报:工程技术版,2005,5(002):68-70.
[50]赵新合,吴卫生.基于unifac基团贡献法的计算机辅助分子设计[J].广东化工2005,32(6);36-39.
[51]张学岗.分离过程质量分离剂的计算机辅助分子设计[D].天津:天津大学,2008.
[52]杨春雪,冯杰.高温高压下煤液化油气液平衡体系的研究[J].燃料化学学报,2009,37(003):271-276.
[53]车延光,张瑜.萃取精馏分离乙酸乙酯-乙醇溶剂的实验研究[J].科协论坛,2007,1:69.
[54]苏复.乙酸乙酯-乙醇-水与溶剂之间的汽液平衡数据测定及关联[D].南京:南京师范大学,2006.
[55]赵承朴.萃取精馏及恒沸精馏[M].北京:高等教育出版社,1988.
[56]迪安J.兰氏化学手册[M].北京:科学出版社,1991.
[57]Helpinstill J. "And van winkle, m [J]. Ind Eng. Chem. Proc. Des. and Develop,1968, 7-213.
[58]程能林.溶剂手册[M].北京:化学工业出版社,1994.
[59]柳玉堂.溶解度参数[J].武汉化工,1994,(003):1-21.
[60]陈洪钫,刘家祺.化丁分离过程[M].北京:化学工业出版社,1995.
[61]胡兴兰,温守东,周荣琪.萃取精馏溶剂筛选方法的评述[J].承德石油高等专科学校学报,2007,9(003):7-10.
[62]张志刚,张卫江,杨志才,崔现宝.萃取精馏分离乙酸乙酯-乙醇的溶剂[J].化工学报,2004,55(002):226-230.
[63]宋华,陈颖.化工分离工程[M].哈尔滨:哈尔滨工业大学出版社,2003.
[64]马沛生.石油化工基础数据手册(续编)[M].北京:化学工业出版社,1993.
[65]范辉.水-醋酸-醋酸正丁酯三元体系液液平衡研究[J].广东化工,2009,36(004):34-36.
[66]陈东初,叶红齐,吴浩.庚烷-苯-n-甲酰吗啉体系液液平衡研究[J].湖南科技大学学报:自然科学版,2007,22(003):113-117.
[67]陈东初.N-甲酰吗啉抽提芳烃体系相平衡及过程模拟研究[D].长沙:中南大学,2007.
[2]朱肖曼.煤液化油基本性质的研究[D].北京:煤炭科学研究总院,2006.
[3]张琪,白雪松,张晓东.对我国喷气燃料进出口的特点分析及建议[J].化学工业,2009,(003):7-10.
[4]王梦奎.关于“十二五”时期的发展[J].政策解读,2011,(01):6-10.
[5]李好管.煤直接液化技术进展及前景分析[J].煤化工,2002,30(003):8-12.
[6]杜岩.柴油芳烃加氢饱和及环烷烃开环的研究[D].天津:天津大学,2007.
[7]舒歌平,史士东,李克健.煤炭液化技术[M].北京:煤炭工业出版社,2003.
[8]崔之栋,李嘉珞.煤炭液化[M].大连:大连理工大学出版社,1993.
[9]王永刚,周建明,王彩红,杨正伟.先锋煤和神华煤直接液化油的组成[J].煤炭学报,2006,31(001):81-84.
[10]王永刚,王彩红,杨正伟,董敏.典型中国煤直接液化油组成特征研究[J].JOURNAL OF CHINA UNIVERSITY OF MINING & TECHNOLOGY,2009,38(1):96-100.
[11]宫万福,田松柏,付晓恒.分析技术在煤液化油分析中的应用[J].洁净煤技术,2004,10(002):47-52.
[12]魏贤勇,宗志敏,秦志宏,陈茺.煤液化化学[M].北京:科学出版社,2002.
[13]薛艳,王树雷,刘婕.煤直接液化制取喷气燃料原料油的组成分析[J]. ACTA PETROLEI SINICA (PETROLEUM PROCESSING SECTION),26(zl):264-267.
[14]吴秀章,石玉林,徐春明.煤炭直接液化油品加氢改质中试研究[J].石油学报:石油加工,2009,25(002):156-161.
[15]蔺华林,张德祥,高晋生.煤加氢液化制取芳烃研究进展[J].煤炭转化,2006,29(002):92-98.
[16]冯利利,朱岳麟,倪建成,熊常健.高密度高安定性喷气燃料的制备及性能[J].石油化工高等学校学报,2006,19(3):15-18.
[17]王德岩.高热安定性喷气燃料jp900制备及性能[J].能源研究与信息,2006,22(004):232-236.
[18]李艳红,王升宝,常丽萍.煤液化产品的分析和提质加工技术[J].科技情报开发与经济,2006,16(021):179-180.
[19]李克健,史士东.德国igor煤液化工艺及云南先锋褐煤液化[J].煤炭转化,2001,24(003):13-16.
[20]吴秀章,石玉林,马辉.煤炭直接液化油品加氢稳定和加氢改质的试验研究[J].石油炼制与化工,2009,(005):1-5.
[21]马筱良,薛宗佑.精制煤液化中油加氢裂化制取喷气燃料的研究[J].燃料化学学报,1989,17(004):296-301.
[22]邱泽锋.煤直接液化技术及其液化粗质油和精制油特点[J].浙江化工,2009,40(006):26-29.
[23]李春凤,张雪梅,张志刚,张卫江.间歇萃取精馏分离苯-环己烷[J].化学工业与工程,2005,22(006):422-426.
[24]郑英峨,蔡锐.用n—甲酰吗啉萃取精馏分离苯加氢油中的烷烃[J].燃料与化工,1997,28(002):90-93.
[25]王孝科,田敉.加盐萃取精馏分离苯-环己烷[J].化学工程,2009,37(003):9-12.
[26]Garcia Villaluenga J., Tabe-Mohammadi A. A review on the separation of benzene/cyclohexane mixtures by pervaporation processes [J]. Journal of Membrane Science,2000,169(2):159-174.
[27]周勇,吴礼光,蔡邦肖,高从阶.Pva/pvp/ag^+共混膜渗透汽化分离苯/环己烷混合物[J].膜科学与技术,2003,23(005):52-55.
[28]Quiggle D., Fenske M. Vapor liquid equilibria of methylcyclohexane toluene mixtures [J]. Journal of the American Chemical Society,1937,59(10):1829-1832.
[29]叶宏,李继定,林阳政,陈剑,陈翠仙.渗透汽化芳烃/烷烃分离膜材料[J].化学进展,2008,20(002):288-299.
[30]张志刚,鲁盼,韩银成.三元混合溶剂间歇萃取精馏分离苯-环己烷[J].沈阳化工学院学报,2009,23(003):217-221.
[31]王孝科,田敉.离子液体萃取精馏分离苯-环己烷物系[J]. PETROCHEMICAL TECHNOLOGY,2008,37(9):905-909.
[32]雷志刚,周荣琪.Nmp萃取精馏分离芳烃和非芳烃[J].高校化学工程学报,2001,15(002):183-186.
[33]Berg L. Separation of toluene from non-aromatic hydrocarbons by extractive distillation. 1982, Google Patents.
[34]贾绍义,柴诚敬.化工传质与分离过程[M].北京:化学工业出版社,2001.
[35]邓修,吴俊生.化工分离过程[M].北京::科学出版社,2000.
[36]李雪梅.液液扩散和气液界面传质的研究[D].天津:天津大学,2007.
[37]管国锋,赵汝溥.化工原理[M].北京:化学工业出版社,2003.
[38]Nernst W. Theoretical chemistry [M].1904.
[39]Azbel D., Kemp-Pritchard P. Two-phase flows in chemical engineering [M]. Cambridge Univ Pr,1981.
[40]高习群.气液界面传质机理与强化[D].天津:天津大学,2008.
[41]张东翔,谭世语,黄会清.传质体系界面过程研究进展[J].重庆大学学报:自然科学版,2001,24(002):137-142.
[42]成弘.强化汽液两相传质的研究进展[J].2001:315-322.
[43]余国琼.蒸馏过程和设备的现状与展望[J].化学工程,1992,20(002):20-25.
[44]Emmert R., Pigford R. A study of gas absorption in falling liquid films [J]. Chem. Eng. Prog,1954,50(2): 87-93.
[45]Danckwerts P., Kennedy A. Kinetics of liquid-film process in gas absorption. Part i: Models of the absorption process [J]. Trans. Instn. Chem. Engrs,1954,32:49-53.
[46]苗容生,王树楹.运动气泡近界面湍流场的激光测量及其湍流结构特性[J].化工学报,1992,43(5):570-576.
[47]马友光,余国琮,何明霞.多组分相际传质近界面浓度场的测定[J].化工学报,1994,45(5):636-636.
[48]Sherwood T. Rl pigford, and cr wilke, mass transfer.1975, McGraw-Hill, Inc, New York.
[49]顾正桂,林军.乙酸乙酯和水萃取精馏分离溶剂的研究[J].南京师范大学学报:工程技术版,2005,5(002):68-70.
[50]赵新合,吴卫生.基于unifac基团贡献法的计算机辅助分子设计[J].广东化工2005,32(6);36-39.
[51]张学岗.分离过程质量分离剂的计算机辅助分子设计[D].天津:天津大学,2008.
[52]杨春雪,冯杰.高温高压下煤液化油气液平衡体系的研究[J].燃料化学学报,2009,37(003):271-276.
[53]车延光,张瑜.萃取精馏分离乙酸乙酯-乙醇溶剂的实验研究[J].科协论坛,2007,1:69.
[54]苏复.乙酸乙酯-乙醇-水与溶剂之间的汽液平衡数据测定及关联[D].南京:南京师范大学,2006.
[55]赵承朴.萃取精馏及恒沸精馏[M].北京:高等教育出版社,1988.
[56]迪安J.兰氏化学手册[M].北京:科学出版社,1991.
[57]Helpinstill J. "And van winkle, m [J]. Ind Eng. Chem. Proc. Des. and Develop,1968, 7-213.
[58]程能林.溶剂手册[M].北京:化学工业出版社,1994.
[59]柳玉堂.溶解度参数[J].武汉化工,1994,(003):1-21.
[60]陈洪钫,刘家祺.化丁分离过程[M].北京:化学工业出版社,1995.
[61]胡兴兰,温守东,周荣琪.萃取精馏溶剂筛选方法的评述[J].承德石油高等专科学校学报,2007,9(003):7-10.
[62]张志刚,张卫江,杨志才,崔现宝.萃取精馏分离乙酸乙酯-乙醇的溶剂[J].化工学报,2004,55(002):226-230.
[63]宋华,陈颖.化工分离工程[M].哈尔滨:哈尔滨工业大学出版社,2003.
[64]马沛生.石油化工基础数据手册(续编)[M].北京:化学工业出版社,1993.
[65]范辉.水-醋酸-醋酸正丁酯三元体系液液平衡研究[J].广东化工,2009,36(004):34-36.
[66]陈东初,叶红齐,吴浩.庚烷-苯-n-甲酰吗啉体系液液平衡研究[J].湖南科技大学学报:自然科学版,2007,22(003):113-117.
[67]陈东初.N-甲酰吗啉抽提芳烃体系相平衡及过程模拟研究[D].长沙:中南大学,2007.