共沸物系分离的研究
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摘要
在化工、石油化工、医药工业、生物化工等以生产各种物料和材料的化工类工业生产部门中以及环境保护工程中,混合物的分离占有极重要的地位。对于具有恒沸现象的液体混合物,应用普通精馏方法难以对其进行有效的分离,萃取精馏或者萃取与精馏的耦合方法能达到分离的效果。
本文综述了萃取精馏和萃取中萃取剂的作用原理、选择依据、选择方法,以及分批萃取精馏和萃取近年来的研究进展和应用。针对苯和环己烷二元物系,分别以N、N-二甲基甲酰胺、二甲基亚砜和二者的混合物为萃取剂,进行了分批萃取精馏实验研究,考察了两个操作参数回流比和溶剂流率对分离效果的影响,结果表明:随着回流比和溶剂流率的增加,分离效果增强;三种萃取剂均能对苯和环己烷进行一定的分离,但分离效果不同,N、N-二甲基甲酰胺的最好、其次是二者的混合物,最后是二甲基亚砜;在本实验中最好的分离条件是以N、N-二甲基甲酰胺为萃取剂,溶剂流率为12.33ml/min,回流比为6。针对甲醇、甲基正丁醚和正氯丁烷三元混合物,研究了该物系的性质,得到该物系不是三元共沸物的结论,并用水作萃取剂,通过实验验证了利用萃取和精馏耦合的方法分离该物系的可行性。
The separation of the mixture is important in chemical, petrochemical, medical, biochemical industries. Liquid mixture having azeotropic phenomenon cannot be separated by conventional distillation. But extractive distillation and combination of extractive and distillation can be valid for them.
This paper summarizes the impact principle, choice basis, choice method of extractive solvent, and the research progress, application of batch extractive distillation and extractive in recent years. The batch extractive distillation experiment to separate benzene and cyclohexane was carried out with N,N-dimethylformide, dimethyl sulfoxide and their mixture as extractive solvent in this paper. The effect of operation parameter of solvent flow rate and reflux ratio on the separation result was studied. The experiment showed that the separation effect was improved with the increase of solvent flow rate and the reflux ratio. All the three extractive solvent can separate benzene and cyclohexane to some extent. The best was N,N-dimethylformide, the next was the mixture, and the last was dimethyl sulfoxide. In the experiment the best operation condition was with N,N-dimethylformide as extractive solvent, the solvent flow rate being 12.33ml/min, the reflux ratio being 6. Meanwhile, experiment with the ternary mixture of methanol, butyl methyl ether and 1-chlorobytane showed that the system was not ternary azeotrope and can be separated by combination of extractive and rectification using water as extractive solvent.
本文综述了萃取精馏和萃取中萃取剂的作用原理、选择依据、选择方法,以及分批萃取精馏和萃取近年来的研究进展和应用。针对苯和环己烷二元物系,分别以N、N-二甲基甲酰胺、二甲基亚砜和二者的混合物为萃取剂,进行了分批萃取精馏实验研究,考察了两个操作参数回流比和溶剂流率对分离效果的影响,结果表明:随着回流比和溶剂流率的增加,分离效果增强;三种萃取剂均能对苯和环己烷进行一定的分离,但分离效果不同,N、N-二甲基甲酰胺的最好、其次是二者的混合物,最后是二甲基亚砜;在本实验中最好的分离条件是以N、N-二甲基甲酰胺为萃取剂,溶剂流率为12.33ml/min,回流比为6。针对甲醇、甲基正丁醚和正氯丁烷三元混合物,研究了该物系的性质,得到该物系不是三元共沸物的结论,并用水作萃取剂,通过实验验证了利用萃取和精馏耦合的方法分离该物系的可行性。
The separation of the mixture is important in chemical, petrochemical, medical, biochemical industries. Liquid mixture having azeotropic phenomenon cannot be separated by conventional distillation. But extractive distillation and combination of extractive and distillation can be valid for them.
This paper summarizes the impact principle, choice basis, choice method of extractive solvent, and the research progress, application of batch extractive distillation and extractive in recent years. The batch extractive distillation experiment to separate benzene and cyclohexane was carried out with N,N-dimethylformide, dimethyl sulfoxide and their mixture as extractive solvent in this paper. The effect of operation parameter of solvent flow rate and reflux ratio on the separation result was studied. The experiment showed that the separation effect was improved with the increase of solvent flow rate and the reflux ratio. All the three extractive solvent can separate benzene and cyclohexane to some extent. The best was N,N-dimethylformide, the next was the mixture, and the last was dimethyl sulfoxide. In the experiment the best operation condition was with N,N-dimethylformide as extractive solvent, the solvent flow rate being 12.33ml/min, the reflux ratio being 6. Meanwhile, experiment with the ternary mixture of methanol, butyl methyl ether and 1-chlorobytane showed that the system was not ternary azeotrope and can be separated by combination of extractive and rectification using water as extractive solvent.
引文
[1] 新型传质分离技术 蒋维钧主编 1992年 化学工业出版社。
[2] 谢林,王玉胜,共沸精馏生产无水酒精技术介绍,安徽化工,1998(1):33-36。
[3] 高远明,共沸精馏法精制叔戊醇,四川化工,1995(4):29-31。
[4] 王训道,赵文莲,孙晓波,恒沸精馏分离硝基氯苯的研究,河南化工,2002(12):12-13。
[5] 王树清、罗传义、包力,用共沸精馏法提取巴豆醛,科学实验与技术革新:25-27。
[6] 顾正桂、章高健,用萃取精馏法从水溶液中回收乙醇,化学工业与工程,1993,10(4):46-50。
[7] 王红科,高玉华等,萃取精馏法分离丁烷与丁烯,化工生产与技术,1998(4):28-29。
[8] 徐志珍,万晨等,萃取精馏法精制萘,华东理工大学学报,1999,25(1):29-31。
[9] 潘鹤林、田恒水、于水,萃取精馏分离甲醇-碳酸二甲酯二元恒沸物,华东理工大学学报,1998,24(4):389-392。
[10]林军、顾正桂,萃取精馏制取均三甲苯的实验研究,2000(5):18-20。
[11] 张光旭、时钧等,四氢呋喃-水恒沸物萃取精馏的模拟计算,武汉化工学院学报,2003,25(1):36-39。
[12] 李秀芹,加盐萃取精馏制备无水乙醇的研究,北京服装学院学报,1990,10(2):66-74。
[13] 黎家坚,加盐萃取精制叔丁醇的研究、中试实验设计与生产技术,燕山油化,1993:12-19。
[14] 漆志文、孙海军等,伴有多反应的精馏过程数学模拟,化工学报,1999,50(4),563-567。
[15] 刘庆林,张锋等,反应精馏制四氢呋喃,化学工程,2002,30(2),75-78。
[16] 何志成,杨靖岫,从四氢呋喃、甲醇、水三元混合物系中分离四氢呋喃的研究,沈阳化工,1995(3):44-46。
[17] 何志成,姜涛等,从四氢呋喃、乙醇、甲醇、水四元混合物系中分离四氢呋喃的研究,沈阳化工学院学报,1998,12(2):113-116。
[18] 何志成,张炳辉,从四氢呋喃、乙醇、水三元混合物系中分离四氢呋喃的研究,沈阳化工,1995(4):30-32。
[19] 何志成,林善良等,从四氢呋喃、乙酸乙酯、水三元混合物系中分离四氢
呋喃的研究,沈阳化工学院学报,1996,10(2):143-147。
[20] 姚玉瑞,从碳四组分中分离甲醇甲醇的工艺模拟及节能分析,石油化工设计,2001,18(1):34-36。
[21] 孙学文,刘彦辉,从催化裂化柴油中分离高纯度2.6-二甲基萘,精细石油化工,2002(5),26-28。
[22] 赵雪飞、胡鑫,从工业二甲酚中分离3.5-二甲酚的研究,燃料与化工,2002,33(2),89-92。
[23] 叶永恒,硝基氯苯分离提纯工艺的进展和单塔精馏-结晶工艺的推广,现代化工,2001,21(1),40-43。
[24]陈新,从重质洗油中提取工业芴的工艺研究,鞍钢技术,2000(10),6-8。
[25]《化学工程手册》第14篇,萃取与浸取,化学工业出版社,1979年。
[26] 中国化工学会教育工作委员会组织编写,《多级分离过程-蒸馏、吸收、萃取、吸附》,化学工业出版社,1991年。
[27] 液-液萃取新见解,南化科技信息,1994(1),53-67。
[28] 易筠、古国榜,溶剂萃取新技术评述,广东化工,2000年第4期:10-13,19。
[29] Bork.Micheel; Important aspects on supercritical spice extraction, Chemical Engineering World, 1997,32(10):57-60.。
[30] J.Rincon,A.Delucas, Preliminary study on the supercritical carbon dioxide extraction of nicotine from tobacco wastes,Sep.Sci.Tech,1998,33(3):411-423。
[31] J.Schon, N.Dahmen,H.Schmider; Separation of oil-contaminated glass grinds by supercritical extraction(SFE),Sep.Sci.Tech,1997,32(1-4):883-897。
[32] James.m.bechel.Kerry .M.Dooley.lnd,supercritical fluid extraction of polycyclic aromatic hydrocarbon mixtures from contaminated soils,Industrical Engineering Chemistry Research.,1998,37:584-594。
[33] 吴金川,何志敏,反胶团萃取蛋白质技术,化学工业与工程,1997,14(3):50-54。
[34] Jihong Tong, Shintato,Farusaki,Extraction behavior of proteins using ADT reversed micellar systems formed by kerosene and silicone oil Sep.Sci.Tech, 1998, 33(6): 899-907。
[35] Hamid R.Rable , Tamin Suyyagn, Juan H.Rera, Reverse micellar extraction of proteins using dioctyldimethyl ammonium chloride Sci. Tech, 1998, 33(2): 241-257。
[36] Qinglong Chang, Tioyong Chen , Protein extraction by new reversed micelles with diltridedecyl phosphoric acid ,Sep.Sci.Tech,1995,30(1):89-99。
[37] A.I.Bularchenko,E.K.Batisheheva, Metal concentration by reversed micelles,
Sep.Sci.Tech,1995,30(2):239-246。
[38] 卜玉兰,郭振库,微波萃取技术,色谱,1997,15(6):499-501。
[39] Carcia-Ayuso L.E.,Sanchez M.De Alba A, Focused microwave-assisted soxhlet :an advantageous tool for sample extraction, Analytical Chemistry, 1998, 70(11): 2426 –2431。
[40] 秦炜,原永辉,戴道元,超声场对化工分离过程的强化,化工进展,1995(1):1-5。
[41] 骆广生,周双杰,汪家鼎,溶剂萃取与电泳技术的耦合,化工进展,1996(2):9-12。
[42] 孙雷,王雅丽,磁化学在稀土萃取领域中应用初探,稀土,1992,13(5):51-53。
[43] 吴全锋,顾忠茂,金兰瑞,内耦合萃反交替分离法从稀溶液中提取与富集稀土的研究,稀土,1991,12(4):1-6。
[44] 吴全锋,顾忠茂,汪德熙,液膜分离过程的新进展-内耦合萃反交替分离过程,化工进展,1997,(2):30-35。
[45] 谭平华,林金谱等,双水相萃取技术研究进展及应用,2003,10(1):19-24。
[46] 汪家鼎、费维扬,溶剂萃取的最新进展 化学进展 1995 7(3):219-224。
[47] 许庆仁,溶液萃取在有机化合物提取和分离方面的应用,上海化工,23(20):32-33,34-36。
[48] 天津大学化工原理教研室编,《化工原理》(下册),天津大学技术出版社, 1983。
[49] [美] C.Judson King编,大连工学院化工原理教研室、化学工程教研室译《分离工程》(第二版),化学工业出版社,1987。
[50] 白鹏,邬慧雄,朱思强,分批萃取精馏技术的研究进展,石油化工,2001,30(7):563。
[51] Philipa.Schweitzer.,Handbook of Separation Techniques For Chemical Engineer ,New York: MCGRAW-HILL,1979。
[52] Hampe.M.J.,Slection of solvents in liquid/liquid Extraction According to Physico-chemical Aspects.,Ger.Chem.Eng.,1986,9:251-263。
[53] 陈洪钫,刘家祺编,化工分离过程,化学工业出版社,1995年。
[54] Tassions,D.P.,In Azeotropic and Extractive Distillation , American Chemical Society,1972,Washington D.C.。
[55] Tomas. E.R.,C.A.Echert., Prediction of Limiting Activity Coefficients by a Modified Separation of Cohesive Energy Density Model and UNITAC Ind.Eng.Chem.Process.Des.,1984,23:194。
[56] Weidlich.U.,J.Gmehling., A Modified UNITAC Model.1.Prediction of VLE,hE,and γ∞.,Ind. Eng. Chem.Process.Des.,1987,26:1372-1381。
[57] Larsen.B.L., Rasmassen P.,Fredenslund A.,A Modified UNIFAC Group -Contribution Model For Prediction of Phase Equilibria and Heats of Maxing,Ind. Eng.Chem.Process.Des.,1987,26:2274-2285。
[58] 兰化公司化机组C组,应用汽液色谱法筛选萃取剂-快速测定C5烃在各种溶剂中无限稀释后的相对挥发度,化学工程,1974,4:48-55。
[59] 浙江大学等,用气液色谱法研究C4烃类萃取精馏溶剂的分离能力,化学工程1973(3-4):83。
[60] 宋海华,孙伟,王秀丽等 萃取精馏溶剂选择的研究进展 化学工业与工程,2002,19(1):83。
[61] Pretel E.J.,Lopea P. A.,Bottini S.B,etal.,Computer –Aided Molecular Design of Solvents for Separation Process, [J].AICH E,1994,40(8):1349-1360。
[62] Marcoulaki E.C.,Kokossis A.C., On the Development of Novel Chemical Using a Systematic Synthesis.Approach.part Ⅰ,Optimization Framework,[J]. Chem. Eng. Sci.,2000,55(14):2529-2546。
[63] Marcoulaki E.C.,Kokossis A.C., On the Development of Novel Chemical Using a Systematic Synthesis Approach .part Ⅱ,Solvent Design,[J]. Chem. Eng. Sci., 2000, 55(14):2529-2561。
[64] Petersen R,Predenslund A.Rasumssen P., Artifical neural networksas a predoctive rool for vapor–liquid equilibrium, [J]. Comput.Chem. Eng., 1994, 18 (supple): S63-S67。
[65] Bonz A.P.Braun B.Jamnowsky R.,Application of Quantitative Structure- PerformanceRelationship and Neural Network Models for the Prediction of Physical Properties from Molecular Structure , [J]. Ind. Eng. Chem.Res., 1998, 37(8):3043-3051。
[66] Bonz A.P.Braun B.Jamnowsky R., Quantitative Structure-Property Relationships and Neural Networks;Corrlation and Prediction of Physical Properties of Pure Components and Mixtures from Molecular Structure , [J]. Fluid phase Equilibria, 1999,158-160:367-374。
[67] Espinosa.G Yaffe.D Cohen.Y. etal.,Neural Network Based Quantitative Structural Property Relation(QSPR) for Prediction Boiling Points of Aliphatic Hydrocarbons, [J]. Chem. Inf. Comput. Sci,2000,40(3):859-879。
[68] Sharma.R Singhal.O Ghosh.R etal., Potential Application of Artificial Neural Networks to Thermodynamics:Vapor-Liquid Equilibrium Prediction, [J]. Chem. Eng.,1999,2(3):385-390.
[69] Lelkes Z. Lang P. Moszkowicz.P.Benadda B. and Otterbein M., Batch Extractive Distillation :the process and the operational policies, Chemical Engineering
Science,1998,53(7):1331-1348。
[70] Berg L.Yeh An-I, The Unusual Behavior of Extractive Distillation –Reversing the Volatility of the Acetone –Isopropyle.,AICHE.,1985,31(3):504-506。
[71] Yatim H., Etude theorique etal., Experimental du Procedede Distillation Extractive Discontinue,Ph.D.Thesis,INSA de Lyon(1993)。
[72] Lang.P,H.Yatim, etal., Batch Extractive Distillation Under constant Reflux Ration,Comput. Chem. Eng., 1994,18(11/12):1057-1069。
[73] Milani S.M., Optimization of Solvent Feed Rate for Maximum Recovery of High Parity Top Product in Batch Extractive Distillation,Trans Icheme, 1999, 77(A6): 469-470。
[74] Meadows, E.L.Multicomponent, Batch Distillation Calculations on a Digital Computers,Chem. Eng. Prog.,Symp.Ser.,1963,59:48-57。
[75] Distefano C.P., Mathematical Modeling and Numerical Integration of Multicomponent Batch Distillation Equations,AICHE J.,1968,14:190-198。
[76] Albert, J.LeLann J. M.X.Koehret B.(1991),Process technology proceedings, vol. 10。
[77] Lang P. Modla G.Benadda B.Benadda B.Lelkes Z., Homoazeotropic distillation of maximum azeotropes in a batch rectifier with continuous entrainer feedingⅠ. Feasibility studies, Computers and Chemical Engineering ,2000,24:1665。
[78] Lelkes Z. Lang P. Benadda B. and Moszkowicz.P., Feasibility of Extractive in a Batch Rectifer .,AICHE,1998,44(4):810-822。
[79] Lang P. Modla G. Kotai B. Lelkes Z.Moszkowicz P., Homoazeotropic distillation of maximum azeotropes in a batch rectifier with continuous entrainer feedingⅡ. Rigorous Simulation Results,Computers and Chemical Engineering , 2000, 24: 1429。
[80] Lang. P.,Lelkes Z. Moszkowicz P. etal, Different operational Policies in the Batch Extractive Distillation ,Comput. Chem. Eng. ,1995,19:S645。
[81] Perry R.P. (1984),Chemical Engineers Handbook, 6th Edition , pp1382-1390, McGraw-Hill, New York,U.S.A。
[82] 白鹏,张卫江,余国琮,动态累积分批精馏过程研究(1)操作方法及实验,化学工程,1994,22(5):15-18,23。
[83] 白鹏,张卫江,余国琮,动态累积分批精馏过程研究(2)过程模拟计算,化学工程,1994,22(5):19-23。
[84] 尹波 动态累积分批精馏的操作方法[学位论文],天津大学,1999。
[85] 张健 分批精馏动态累积循环操作流体力学和传质特性研究[博士学位论文],天津大学,2002。
[86] 崔现宝,杨志才,冯天扬,萃取精馏及进展 化学工业与工程,2001,18(4):215。
[87] 崔现宝,带有中间储罐塔的间歇萃取精馏的研究[博士学位论文],天津大学,2002。
[88] 田玉峰,分批萃取精馏操作方法的研究[硕士学位论文],2002。
[2] 谢林,王玉胜,共沸精馏生产无水酒精技术介绍,安徽化工,1998(1):33-36。
[3] 高远明,共沸精馏法精制叔戊醇,四川化工,1995(4):29-31。
[4] 王训道,赵文莲,孙晓波,恒沸精馏分离硝基氯苯的研究,河南化工,2002(12):12-13。
[5] 王树清、罗传义、包力,用共沸精馏法提取巴豆醛,科学实验与技术革新:25-27。
[6] 顾正桂、章高健,用萃取精馏法从水溶液中回收乙醇,化学工业与工程,1993,10(4):46-50。
[7] 王红科,高玉华等,萃取精馏法分离丁烷与丁烯,化工生产与技术,1998(4):28-29。
[8] 徐志珍,万晨等,萃取精馏法精制萘,华东理工大学学报,1999,25(1):29-31。
[9] 潘鹤林、田恒水、于水,萃取精馏分离甲醇-碳酸二甲酯二元恒沸物,华东理工大学学报,1998,24(4):389-392。
[10]林军、顾正桂,萃取精馏制取均三甲苯的实验研究,2000(5):18-20。
[11] 张光旭、时钧等,四氢呋喃-水恒沸物萃取精馏的模拟计算,武汉化工学院学报,2003,25(1):36-39。
[12] 李秀芹,加盐萃取精馏制备无水乙醇的研究,北京服装学院学报,1990,10(2):66-74。
[13] 黎家坚,加盐萃取精制叔丁醇的研究、中试实验设计与生产技术,燕山油化,1993:12-19。
[14] 漆志文、孙海军等,伴有多反应的精馏过程数学模拟,化工学报,1999,50(4),563-567。
[15] 刘庆林,张锋等,反应精馏制四氢呋喃,化学工程,2002,30(2),75-78。
[16] 何志成,杨靖岫,从四氢呋喃、甲醇、水三元混合物系中分离四氢呋喃的研究,沈阳化工,1995(3):44-46。
[17] 何志成,姜涛等,从四氢呋喃、乙醇、甲醇、水四元混合物系中分离四氢呋喃的研究,沈阳化工学院学报,1998,12(2):113-116。
[18] 何志成,张炳辉,从四氢呋喃、乙醇、水三元混合物系中分离四氢呋喃的研究,沈阳化工,1995(4):30-32。
[19] 何志成,林善良等,从四氢呋喃、乙酸乙酯、水三元混合物系中分离四氢
呋喃的研究,沈阳化工学院学报,1996,10(2):143-147。
[20] 姚玉瑞,从碳四组分中分离甲醇甲醇的工艺模拟及节能分析,石油化工设计,2001,18(1):34-36。
[21] 孙学文,刘彦辉,从催化裂化柴油中分离高纯度2.6-二甲基萘,精细石油化工,2002(5),26-28。
[22] 赵雪飞、胡鑫,从工业二甲酚中分离3.5-二甲酚的研究,燃料与化工,2002,33(2),89-92。
[23] 叶永恒,硝基氯苯分离提纯工艺的进展和单塔精馏-结晶工艺的推广,现代化工,2001,21(1),40-43。
[24]陈新,从重质洗油中提取工业芴的工艺研究,鞍钢技术,2000(10),6-8。
[25]《化学工程手册》第14篇,萃取与浸取,化学工业出版社,1979年。
[26] 中国化工学会教育工作委员会组织编写,《多级分离过程-蒸馏、吸收、萃取、吸附》,化学工业出版社,1991年。
[27] 液-液萃取新见解,南化科技信息,1994(1),53-67。
[28] 易筠、古国榜,溶剂萃取新技术评述,广东化工,2000年第4期:10-13,19。
[29] Bork.Micheel; Important aspects on supercritical spice extraction, Chemical Engineering World, 1997,32(10):57-60.。
[30] J.Rincon,A.Delucas, Preliminary study on the supercritical carbon dioxide extraction of nicotine from tobacco wastes,Sep.Sci.Tech,1998,33(3):411-423。
[31] J.Schon, N.Dahmen,H.Schmider; Separation of oil-contaminated glass grinds by supercritical extraction(SFE),Sep.Sci.Tech,1997,32(1-4):883-897。
[32] James.m.bechel.Kerry .M.Dooley.lnd,supercritical fluid extraction of polycyclic aromatic hydrocarbon mixtures from contaminated soils,Industrical Engineering Chemistry Research.,1998,37:584-594。
[33] 吴金川,何志敏,反胶团萃取蛋白质技术,化学工业与工程,1997,14(3):50-54。
[34] Jihong Tong, Shintato,Farusaki,Extraction behavior of proteins using ADT reversed micellar systems formed by kerosene and silicone oil Sep.Sci.Tech, 1998, 33(6): 899-907。
[35] Hamid R.Rable , Tamin Suyyagn, Juan H.Rera, Reverse micellar extraction of proteins using dioctyldimethyl ammonium chloride Sci. Tech, 1998, 33(2): 241-257。
[36] Qinglong Chang, Tioyong Chen , Protein extraction by new reversed micelles with diltridedecyl phosphoric acid ,Sep.Sci.Tech,1995,30(1):89-99。
[37] A.I.Bularchenko,E.K.Batisheheva, Metal concentration by reversed micelles,
Sep.Sci.Tech,1995,30(2):239-246。
[38] 卜玉兰,郭振库,微波萃取技术,色谱,1997,15(6):499-501。
[39] Carcia-Ayuso L.E.,Sanchez M.De Alba A, Focused microwave-assisted soxhlet :an advantageous tool for sample extraction, Analytical Chemistry, 1998, 70(11): 2426 –2431。
[40] 秦炜,原永辉,戴道元,超声场对化工分离过程的强化,化工进展,1995(1):1-5。
[41] 骆广生,周双杰,汪家鼎,溶剂萃取与电泳技术的耦合,化工进展,1996(2):9-12。
[42] 孙雷,王雅丽,磁化学在稀土萃取领域中应用初探,稀土,1992,13(5):51-53。
[43] 吴全锋,顾忠茂,金兰瑞,内耦合萃反交替分离法从稀溶液中提取与富集稀土的研究,稀土,1991,12(4):1-6。
[44] 吴全锋,顾忠茂,汪德熙,液膜分离过程的新进展-内耦合萃反交替分离过程,化工进展,1997,(2):30-35。
[45] 谭平华,林金谱等,双水相萃取技术研究进展及应用,2003,10(1):19-24。
[46] 汪家鼎、费维扬,溶剂萃取的最新进展 化学进展 1995 7(3):219-224。
[47] 许庆仁,溶液萃取在有机化合物提取和分离方面的应用,上海化工,23(20):32-33,34-36。
[48] 天津大学化工原理教研室编,《化工原理》(下册),天津大学技术出版社, 1983。
[49] [美] C.Judson King编,大连工学院化工原理教研室、化学工程教研室译《分离工程》(第二版),化学工业出版社,1987。
[50] 白鹏,邬慧雄,朱思强,分批萃取精馏技术的研究进展,石油化工,2001,30(7):563。
[51] Philipa.Schweitzer.,Handbook of Separation Techniques For Chemical Engineer ,New York: MCGRAW-HILL,1979。
[52] Hampe.M.J.,Slection of solvents in liquid/liquid Extraction According to Physico-chemical Aspects.,Ger.Chem.Eng.,1986,9:251-263。
[53] 陈洪钫,刘家祺编,化工分离过程,化学工业出版社,1995年。
[54] Tassions,D.P.,In Azeotropic and Extractive Distillation , American Chemical Society,1972,Washington D.C.。
[55] Tomas. E.R.,C.A.Echert., Prediction of Limiting Activity Coefficients by a Modified Separation of Cohesive Energy Density Model and UNITAC Ind.Eng.Chem.Process.Des.,1984,23:194。
[56] Weidlich.U.,J.Gmehling., A Modified UNITAC Model.1.Prediction of VLE,hE,and γ∞.,Ind. Eng. Chem.Process.Des.,1987,26:1372-1381。
[57] Larsen.B.L., Rasmassen P.,Fredenslund A.,A Modified UNIFAC Group -Contribution Model For Prediction of Phase Equilibria and Heats of Maxing,Ind. Eng.Chem.Process.Des.,1987,26:2274-2285。
[58] 兰化公司化机组C组,应用汽液色谱法筛选萃取剂-快速测定C5烃在各种溶剂中无限稀释后的相对挥发度,化学工程,1974,4:48-55。
[59] 浙江大学等,用气液色谱法研究C4烃类萃取精馏溶剂的分离能力,化学工程1973(3-4):83。
[60] 宋海华,孙伟,王秀丽等 萃取精馏溶剂选择的研究进展 化学工业与工程,2002,19(1):83。
[61] Pretel E.J.,Lopea P. A.,Bottini S.B,etal.,Computer –Aided Molecular Design of Solvents for Separation Process, [J].AICH E,1994,40(8):1349-1360。
[62] Marcoulaki E.C.,Kokossis A.C., On the Development of Novel Chemical Using a Systematic Synthesis.Approach.part Ⅰ,Optimization Framework,[J]. Chem. Eng. Sci.,2000,55(14):2529-2546。
[63] Marcoulaki E.C.,Kokossis A.C., On the Development of Novel Chemical Using a Systematic Synthesis Approach .part Ⅱ,Solvent Design,[J]. Chem. Eng. Sci., 2000, 55(14):2529-2561。
[64] Petersen R,Predenslund A.Rasumssen P., Artifical neural networksas a predoctive rool for vapor–liquid equilibrium, [J]. Comput.Chem. Eng., 1994, 18 (supple): S63-S67。
[65] Bonz A.P.Braun B.Jamnowsky R.,Application of Quantitative Structure- PerformanceRelationship and Neural Network Models for the Prediction of Physical Properties from Molecular Structure , [J]. Ind. Eng. Chem.Res., 1998, 37(8):3043-3051。
[66] Bonz A.P.Braun B.Jamnowsky R., Quantitative Structure-Property Relationships and Neural Networks;Corrlation and Prediction of Physical Properties of Pure Components and Mixtures from Molecular Structure , [J]. Fluid phase Equilibria, 1999,158-160:367-374。
[67] Espinosa.G Yaffe.D Cohen.Y. etal.,Neural Network Based Quantitative Structural Property Relation(QSPR) for Prediction Boiling Points of Aliphatic Hydrocarbons, [J]. Chem. Inf. Comput. Sci,2000,40(3):859-879。
[68] Sharma.R Singhal.O Ghosh.R etal., Potential Application of Artificial Neural Networks to Thermodynamics:Vapor-Liquid Equilibrium Prediction, [J]. Chem. Eng.,1999,2(3):385-390.
[69] Lelkes Z. Lang P. Moszkowicz.P.Benadda B. and Otterbein M., Batch Extractive Distillation :the process and the operational policies, Chemical Engineering
Science,1998,53(7):1331-1348。
[70] Berg L.Yeh An-I, The Unusual Behavior of Extractive Distillation –Reversing the Volatility of the Acetone –Isopropyle.,AICHE.,1985,31(3):504-506。
[71] Yatim H., Etude theorique etal., Experimental du Procedede Distillation Extractive Discontinue,Ph.D.Thesis,INSA de Lyon(1993)。
[72] Lang.P,H.Yatim, etal., Batch Extractive Distillation Under constant Reflux Ration,Comput. Chem. Eng., 1994,18(11/12):1057-1069。
[73] Milani S.M., Optimization of Solvent Feed Rate for Maximum Recovery of High Parity Top Product in Batch Extractive Distillation,Trans Icheme, 1999, 77(A6): 469-470。
[74] Meadows, E.L.Multicomponent, Batch Distillation Calculations on a Digital Computers,Chem. Eng. Prog.,Symp.Ser.,1963,59:48-57。
[75] Distefano C.P., Mathematical Modeling and Numerical Integration of Multicomponent Batch Distillation Equations,AICHE J.,1968,14:190-198。
[76] Albert, J.LeLann J. M.X.Koehret B.(1991),Process technology proceedings, vol. 10。
[77] Lang P. Modla G.Benadda B.Benadda B.Lelkes Z., Homoazeotropic distillation of maximum azeotropes in a batch rectifier with continuous entrainer feedingⅠ. Feasibility studies, Computers and Chemical Engineering ,2000,24:1665。
[78] Lelkes Z. Lang P. Benadda B. and Moszkowicz.P., Feasibility of Extractive in a Batch Rectifer .,AICHE,1998,44(4):810-822。
[79] Lang P. Modla G. Kotai B. Lelkes Z.Moszkowicz P., Homoazeotropic distillation of maximum azeotropes in a batch rectifier with continuous entrainer feedingⅡ. Rigorous Simulation Results,Computers and Chemical Engineering , 2000, 24: 1429。
[80] Lang. P.,Lelkes Z. Moszkowicz P. etal, Different operational Policies in the Batch Extractive Distillation ,Comput. Chem. Eng. ,1995,19:S645。
[81] Perry R.P. (1984),Chemical Engineers Handbook, 6th Edition , pp1382-1390, McGraw-Hill, New York,U.S.A。
[82] 白鹏,张卫江,余国琮,动态累积分批精馏过程研究(1)操作方法及实验,化学工程,1994,22(5):15-18,23。
[83] 白鹏,张卫江,余国琮,动态累积分批精馏过程研究(2)过程模拟计算,化学工程,1994,22(5):19-23。
[84] 尹波 动态累积分批精馏的操作方法[学位论文],天津大学,1999。
[85] 张健 分批精馏动态累积循环操作流体力学和传质特性研究[博士学位论文],天津大学,2002。
[86] 崔现宝,杨志才,冯天扬,萃取精馏及进展 化学工业与工程,2001,18(4):215。
[87] 崔现宝,带有中间储罐塔的间歇萃取精馏的研究[博士学位论文],天津大学,2002。
[88] 田玉峰,分批萃取精馏操作方法的研究[硕士学位论文],2002。