Chemical Industry and Engineering Progress ›› 2018, Vol. 37 ›› Issue (04): 1212-1228.DOI: 10.16085/j.issn.1000-6613.2017-2303
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LI Hong1,2,3, MENG Ying1,2,3, LI Xingang1,2,3, GAO Xin1,2,3
Received:
2017-11-08
Revised:
2017-12-18
Online:
2018-04-05
Published:
2018-04-05
李洪1,2,3, 孟莹1,2,3, 李鑫钢1,2,3, 高鑫1,2,3
通讯作者:
高鑫,副教授,博士生导师。
作者简介:
李洪(1980-),女,研究员,博士生导师,研究方向为传质与分离工程、化工分离过程强化。E-mail:lihong.tju@163.com。
基金资助:
CLC Number:
LI Hong, MENG Ying, LI Xingang, GAO Xin. State-of-the-arts review of the research process for distillation process intensification technology[J]. Chemical Industry and Engineering Progress, 2018, 37(04): 1212-1228.
李洪, 孟莹, 李鑫钢, 高鑫. 蒸馏过程强化技术研究进展[J]. 化工进展, 2018, 37(04): 1212-1228.
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[1] 李鑫钢. 现代蒸馏技术[M]. 北京:化学工业出版社,2009. LI Xingang. Modern distillation technology[M]. Beijing:Chemical Industry Press,2009. [2] KISS A A. Distillation technology-still young and full of breakthrough opportunities[J]. Journal of Chemical Technology and Biotechnology,2014,89(4):479-498. [3] 王春蓉. 共沸蒸馏技术研究及应用进展[J]. 矿冶,2011,20(1):47-49. WANG Chunrong. Research and application progress of azeotropic distillation[J]. Mining and Metallurgy,2011,20(1):47-49. [4] 汤志刚,王玲珑,李明飞. 酸水体系共沸现象探究——"超分子"假说及其应用[J]. 化学工程,2009,37(12):39-42. TANG Zhigang,WANG Linglong,LI Mingfei. Research on azeotropic phenomenon of acid-water system:hypothesis of "supermolecular"and applications[J]. Chemical Engineering,2009,37(12):39-42. [5] 唐有祺. 相平衡、化学平衡和热平衡[M]. 北京:科学出版社,1984:8-9. TANG Youqi. Phase equilibrium,chemical equilibrium and thermal equilibrium[M]. Beijing:Science Press,1984:8-9. [6] 杨志才. 化工生产中的间歇过程-原理、工艺及设备[M]. 北京:化学工业出版社,2001:398-402. YANG Zhicai. Batch process-principle,process and equipment in chemical production[M]. Beijing:Chemical Industry Press,2001:398-402. [7] 隋振英,邹东雷. 共沸蒸馏中共沸剂的选择[J]. 化学工程师,1996(3):27-29. SUI Zhenying,ZOU Donglei. The choice of azeotropic agent in azeotropic distillation[J]. Chemical Engineer,1996(3):27-29. [8] 陈敏恒,丛德滋,方图南,等. 化工原理[M]. 北京:化学工业出版社,2006:89. CHEN Minhuan,CONG Dezi,FANG Tunan,et al. Principles of chemical engineering[M]. Beijing:Chemical Industry Press,2006:89. [9] MCDOWELL J K,DAVIS J F. A characterization of diffusion distillation for azeotropic separation[J]. Industrial & Engineering Chemistry Research,1988,27(11):2139-2148. [10] LE Q K,HALVORSEN I J,PAJALIC O,et al. Dividing wall columns for heterogeneous azeotropic distillation[J]. Chemical Engineering Research and Design,2015,99:111-119. [11] YU H,YE Q,XU H,et al. Design and control of dividing-wall column for tert-butanol dehydration system via heterogeneous azeotropic distillation[J]. Industrial & Engineering Chemistry Research,2015,54(13):3384-3397. [12] PIROLA C,GALLI F,MANENTI F,et al. Simulation and related experimental validation of acetic acid/water distillation using p-xylene as entrainer[J]. Industrial & Engineering Chemistry Research,2014,53(46):18063-18070. [13] HUANG X,ZHONG W,DU W,et al. Thermodynamic analysis and process simulation of an industrial acetic acid dehydration system via heterogeneous azeotropic distillation[J]. Industrial & Engineering Chemistry Research,2013,52(8):2944-2957. [14] WANG S J,HUANG K. Design and control of acetic acid dehydration system via heterogeneous azeotropic distillation using p-xylene as an entrainer[J]. Chemical Engineering and Processing:Process Intensification,2012,60:65-76. [15] 李春利,张明禄,方静,等. 间歇共沸蒸馏分离乙二醇单甲醚-水物系[J]. 化工进展,2012,31(6):1220-1223. LI Chunli,ZHANG Minglu,FANG Jing,et al. Separation of 2-methoxyethanol-water mixture by batch azeotropic distillation[J]. Chemical Industry and Engineering Progress,2012,31(6):1220-1223. [16] GOMIS V,PEDRAZA R,SAQUETE M D,et al. Ethanol dehydration via azeotropic distillation with gasoline fractions as entrainers:a pilot-scale study of the manufacture of an ethanol-hydrocarbon fuel blend[J]. Fuel,2015,139:568-574. [17] LI W,CHANG S,QI X,et al. The azeotropic behavior of waste water that contains phenol and high concentrated salt in a distillation column[J]. Bio Technology:an Indian Journal,2014,10(18):10220-10223. [18] LEE S I,SON S R,CHOI Y B. Method for producing anhydrous sugar alcohol using azeotropic distillation:US15/518827[P]. 2015-10-07. [19] BENEDICT M,RUBIN L C. Extractive and azeotropic distillation[J]. Theoretical Aspects. Trans. Am. Inst. Chem. Eng.,1945,41:353-370. [20] LEI Z,CHEN B,LI C,et al. Predictive molecular thermodynamic models for liquid solvents,solid salts,polymers,and ionic liquids[J]. Chemical Reviews,2008,108(4):1419-1455. [21] JORK C,KRISTEN C,PIERACCINI D,et al. Tailor-made ionic liquids[J]. The Journal of Chemical Thermodynamics,2005,37(6):537-558. [22] LEI Z,DAI C,ZHU J,et al. Extractive distillation with ionic liquids:a review[J]. AIChE Journal,2014,60(9):3312-3329. [23] SCHEFFCZYK J,REDEPENNING C,JENS C M,et al. Massive,automated solvent screening for minimum energy demand in hybrid extraction-distillation using COSMO-RS[J]. Chemical Engineering Research and Design,2016,115:433-442. [24] LEI Z,ARLT W,WASSERSCHEID P. Selection of entrainers in the 1-hexene/n-hexane system with a limited solubility[J]. Fluid Phase Equilibria,2007,260(1):29-35. [25] GUTIERREZ J P,MEINDERSMA G W,DE HAAN A B. COSMO-RS-based ionic-liquid selection for extractive distillation processes[J]. Industrial & Engineering Chemistry Research,2012,51(35):11518-11529. [26] BANERJEE T,KHANNA A. Infinite dilution activity coefficients for trihexyltetradecyl phosphonium ionic liquids:measurements and COSMO-RS prediction[J]. Journal of Chemical & Engineering Data,2006,51(6):2170-2177. [27] TASSIONS D P. Azeotropic and extractive distillation[M]. Washington D C:American Chemical Society,1972:46-63. [28] NAVARRETE-CONTRERAS S,SANCHEZ-IBARRA M,BARROSO-MUNOZ F O,et al. Use of glycerol as entrainer in the dehydration of bioethanol using extractive batch distillation:simulation and experimental studies[J]. Chemical Engineering and Processing:Process Intensification,2014,77:38-41. [29] WANG H,CUI X,LI C,et al. Separation of ethyl acetate-dichloromethane-ethanol by extractive distillation:simulation and optimization[J]. Chemical Engineering & Technology,2013,36(4):627-634. [30] WANG Y,ZHANG Z,ZHAO Y,et al. Control of extractive distillation and partially heat-integrated pressure-swing distillation for separating azeotropic mixture of ethanol and tetrahydrofuran[J]. Industrial & Engineering Chemistry Research,2015,54(34):8533-8545. [31] 席晓敏. 萃取蒸馏法分离乙醇水体系的实验研究及流程模拟[D]. 北京:北京化工大学,2014. XI Xiaomin. Experimental research and process simulation for separation of ethanol and water with extractive distillation[D]. Beijing:Beijing University of Chemical Technology,2014. [32] BACKHAUS A A. Continuous processes for the manufacture of esters:US1400849[P]. 1921-12-20. [33] MALONE M F,DOHERTY M F. Reactive distillation[J]. Industrial & Engineering Chemistry Research,2000,39(11):3953-3957. [34] 马敬环,刘家祺,李俊台,等. 反应蒸馏技术的进展[J]. 化学反应工程与工艺,2003,19(1):1-8. MA Jinghuan,LIU Jiaqi,LI Juntai,et al. The progress in reactive distillation technology[J]. Chemical Reaction Engineering and Technology,2003,19(1):1-8. [35] TAYLOR R,KRISHNA R. Modelling reactive distillation[J]. Chemical Engineering Science,2000,55(22):5183-5229. [36] 安振国,张晓杰,任万忠. 反应蒸馏技术的研究进展[J]. 化学工业与工程技术,2007,28(1):14-19. AN Zhenguo,ZHANG Xiaojie,REN Wanzhong. Research progress of reactive distillation technology[J]. Journal of Chemical Industry & Engineering,2007,28(1):14-19. [37] 杨照,王志祥. 反应蒸馏技术及其应用[J]. 化工时刊,2004,18(11):10-12. YANG Zhao,WANG Zhixiang. Reactive distillation technique and its application[J]. Chemical Industry Times,2004,18(11):10-12. [38] LI H,XIAO C,LI X,et al. Synthesis of n-amyl acetate in a pilot plant catalytic distillation column with seepage catalytic packing internal[J]. Industrial & Engineering Chemistry Research,2017,56(44):12726-12737. [39] GADEKAR-SHINDE S,REDDY B,KHAN M,et al. Reactive distillation for the production of methoxy propyl acetate:experiments and simulation[J]. Industrial & Engineering Chemistry Research,2017,56(4):832-843. [40] KAYMAK D B,ÜNLÜ H,ÖFKELI T. Control of a reactive distillation column with double reactive sections for two-stage consecutive reactions[J]. Chemical Engineering and Processing:Process Intensification,2017,113:86-93. [41] HSIAO T L,WENG K C,LEE H Y. Design and control of hybrid heat-integrated configuration for an ideal indirect reactive distillation process[J]. Journal of the Taiwan Institute of Chemical Engineers,2017,73:37-49. [42] BABCOCK P D,CLUMP C W. Distillation of chemically reactive solutions[M]//LINN. Recent developments in separation science,1978,Ⅳ:149-166. [43] KRISHNAMURTHY R,TAYLOR R. A nonequilibrium stage model of multicomponent separation processes. Part I:Model description and method of solution[J]. AIChE Journal,1985,31(3):449-456. [44] Chemical Research & Licensing Company. Catalytic distillation reactor:EP0461855[P]. 1991-11-06. [45] YEOMAN N,PINAIRE R,ULOWETZ M A,et al. Internals for distillation columns including those for use in catalytic reactions:US5454913[P]. 1995-10-03. [46] YEOMAN N,PINAIRE R,ULOWETZ M A,et al. Internals for distillation columns including those for use in catalytic reactions:US5496446[P]. 1996-03-05. [47] Chemical Research & Licensing Company. Catalytic distillation system:US5262912[P]. 1993-11-16. [48] Chemical Research & Licensing Company. Catalytic distillation structured:US4443559[P]. 1984-04-17. [49] LI H,XIAO C,LI X,et al. Synthesis of n-amyl acetate in a pilot-plant catalytic distillation column with seepage catalytic packing internal[J]. Industrial & Engineering Chemistry Research,2017,56(44):12726-12737. [50] TANG Y T,CHEN Y W,HUANG H P,et al. Design of reactive distillations for acetic acid esterification[J]. AIChE Journal,2005,51(6):1683-1699. [51] 刘有智,等. 化工过程强化方法与技术[M]. 北京:化学工业出版社,2017:479-497. LIU Youzhi,et al. Chemical process strengthening method and technology[M]. Beijing:Chemical Industry Press,2017:479-497. [52] THOSTENSON E T,CHOU T W. Microwave processing:fundamentals and applications[J]. Composites Part A:Applied Science and Manufacturing,1999,30(9):1055-1071. [53] 李洪,崔俊杰,李鑫钢,等. 微波场强化化工分离过程研究进展[J]. 化工进展,2016,35(12):3735-3745. LI Hong,CUI Junjie,LI Xingang,et al. Recent developments in microwave-assisted chemical separation processes[J]. Chemical Industry and Engineering Progress,2016,35(12):3735-3745. [54] GAO X,LI X,ZHANG J,et al. Influence of a microwave irradiation field on vapor-liquid equilibrium[J]. Chemical Engineering Science,2013,90:213-220. [55] WERTH K,LUTZE P,KISS A A,et al. A systematic investigation of microwave-assisted reactive distillation:influence of microwaves on separation and reaction[J]. Chemical Engineering and Processing:Process Intensification,2015,93:87-97. [56] YOUSEFI S,EMAM-DJOMEH Z,MOUSAVI S M A,et al. Comparing the effects of microwave and conventional heating methods on the evaporation rate and quality attributes of pomegranate(Punica granatum L.)juice concentrate[J]. Food and Bioprocess Technology,2012,5(4):1328-1339. [57] 侯钧,徐世民,丁辉,等. 微波对乙醇-苯体系汽液平衡和间歇精馏的影响[J]. 中国科技论文在线精品论文,2013,6(7):684-689. HOU Jun,XU Shimin,DING Hui,et al. Effect of microwave on vapor-liquid equilibrium and batch distillation for ethand-benzene system[J]. High Lights of Science Paper Online,2013,6(7):684-689. [58] CHEN F,DU X,ZU Y,et al. Microwave-assisted method for distillation and dual extraction in obtaining essential oil,proanthocyanidins and polysaccharides by one-pot process from cinnamomi cortex[J]. Separation and Purification Technology,2016,164:1-11. [59] JIAO W Z,LIU Y Z,QI G S. Gas pressure drop and mass transfer characteristics in a cross-flow rotating packed bed with porous plate packing[J]. Industrial & Engineering Chemistry Research,2010,49(8):3732-3740. [60] 孙宏伟,陈建峰. 我国化工过程强化技术理论与应用研究进展[J]. 化工进展,2011,30(1):1-15. SUN Hongwei,CHEN Jianfeng. Advances in fundamental study and application of chemical process intensification technology in China[J]. Chemical Industry and Engineering Progress,2011,30(1):1-15. [61] AGARWAL L,PAVANI V,RAO D P,et al. Process intensification in HIGEE absorption and distillation:design procedure and applications[J]. Industrial & Engineering Chemistry Research,2010,49(20):10046-10058. [62] 李俊妮. 特殊精馏用填料研究进展[J]. 化工中间体,2012(1):1-5. LI Junni. Research development of packing for special distillation[J]. Chemical Intermediate,2012(1):1-5. [63] 栗秀萍,王新成,李俊妮,等. 超重机内多孔板填料上气液流场的计算流体动力学模拟[J]. 石油化工,2013,42(12):1361-1366. LI Xiuping,WANG Xincheng,LI Junni,et al. Computational fluid dynamics simulation of gas-liquid flow field on perforated plate packing in higee[J]. Petrochemical Technology,2013,42(12):1361-1366. [64] 王新成. 基于Aspen Plus的超重力蒸馏过程模拟与优化[D]. 太原:中北大学,2014. WANG Xincheng. Higee distillation process simulation and optimization based on Aspen Plus[D]. Taiyuan:North University of China,2014. [65] LI Y,JI J,XU Z,et al. Pressure drop model on rotating zigzag bed as a new high-gravity technology[J]. Industrial & Engineering Chemistry Research,2013,52(12):4638-4649. [66] LI Y,LU Y,WANG G,et al. Liquid entrainment and flooding in a rotating zigzag bed[J]. Industrial & Engineering Chemistry Research,2015,54(9):2554-2563. [67] 姚文,李育敏,郭成峰,等. 网板填料复合旋转床的传质性能[J].高校化学工程学报,2013,27(3):386-392. YAO W,LI Y M,GUO C F,et al. Mass transfer performance of rotating compound bed with perforated sheet and packing[J]. Journal of Chemical Engineering of Chinese Universities,2013,27(3):386-392. [68] LI Y,LI X,WANG Y,et al. Distillation in a counterflow concentric-ring rotating bed[J]. Industrial & Engineering Chemistry Research,2014,53(12):4821-4837. [69] 计建炳,俞云良,徐之超. 折流式旋转床——超重力场中的湿壁群[J]. 现代化工,2005,25(5):52-58. JI Jianbing,YU Yunliang,XU Zhichao. Wetted wall cluster in high gravity field:zigzag rotating bed[J]. Modern Chemical Industry,2005,25(5):52-58. [70] 栗秀萍,刘有智. 超重力场蒸馏过程探讨[J]. 现代化工,2006,26(s2):315-319. LI Xiuping,LIU Youzhi. Study on distillation in high gravity field[J]. Modern Chemical Industry,2006,26(s2):315-319. [71] 栗秀萍,李俊妮,刘有智,等. 多级超重力蒸馏过程的传质性能[J]. 化学工程,2013,41(5):14-18. LI Xiuping,LI Junni,LIU Youzhi,et al. Mass transfer property of multistage high gravity distillation process[J]. Chemical Engineering,2013,41(5):14-18. [72] 吴松海,孙永利,贾绍义. 磁场对蒸馏水蒸发过程的影响[J]. 石油化工高等学校学报,2006,19(1):10-12. WU songhai,SUN Yongli,JIA Shaoyi. Effects of magnetic field on evaporation of distilled water[J]. Journal of Petrochemical Universities,2006,19(1):10-12. [73] 马伟,马文骥. 磁场强化溶液蒸发的效果及机理[J]. 中国有色金属学报,1998,8(3):502-506. MA Wei,MA Wenji. The effect and mechanism of magnetic field enhanced solution evaporation[J]. The Chinese Journal of Nonferrous Metals,1998,8(3):502-506. [74] 张敏卿,周维义. 磁场对汽液平衡的影响[J]. 化学工程,1999,27(5):42-44. ZHANG Minqing,ZHOU Weiyi. The effect of magnetic field on vapor-liquid equilibrium[J]. Chemical Engineering,1999,27(5):42-44. [75] GUO Y Z,YIN D C,CAO H L,et al. Evaporation rate of water as a function of a magnetic field and field gradient[J]. International Journal of Molecular Sciences,2012,13(12):16916-16928. [76] 马空军,贾殿赠,孙文磊,等. 物理场强化化工过程的研究进展[J]. 现代化工,2009,29(3):27-31. MA Kongjun,JIA Dianzeng,SUN Wenlei,et al. Advances in physical fields used to enhance processes of chemical engineering[J]. Modern Chemical Industry,2009,29(3):27-31. [77] 肖祖峰,陈明东,韩光泽. 电磁场作用下的强化传质研究进展[J]. 化工进展,2008,27(12):1911-1916. XIAO Zufeng,CHEN Mingdong,HAN Guangze. Research progress of mass transfer enhancement by electromagnetic field[J]. Chemical Industry and Engineering Progress,2008,27(12):1911-1916. [78] 马空军,贾殿赠,包文忠,等. 超声场作用下的强化传质研究进展[J]. 化工进展,2010,29(1):11-16. MA Kongjun,JIA Dianzeng,BAO Wenzhong,et al. Research progress in mass transfer enhancement by ultrasonic field[J]. Chemical Industry and Engineering Progress,2010,29(1):11-16. [79] 金付强,张晓东,许海朋,等. 物理场强化气液传质的研究进展[J]. 化工进展,2014,33(4):803-810. JIN Fuqiang,ZHANG Xiaodong,XU Haipeng,et al. Research progress of enhancement of gas-liquid mass transfer by physical fields[J]. Chemical Industry and Engineering Progress,2014,33(4):803-810. [80] 李群生,杨金苗. 新型高效填料的原理及其在脱硫工序中的应用[C]//全国化工合成氨设计技术中心站技术交流会,2005. LI Qunsheng,YANG Jinmiao. Principle of a new type of high efficiency packing and its application in desulfurization process[C]//The National Exchang Meeting for Chemical Synthetic Technology of Ammonia,2005. [81] 金祖源. 乱堆填料层压降半经验通用关联图[J]. 化学工程,1982(3):26-37. JIN Zuyuan. The general correlation diagram for the pressure drop of the packing laminate[J]. Chemical Engineering,1982(3):26-37. [82] 王广全,袁希钢,刘春江,等. 规整填料压降研究新进展[J]. 化学工程,2005,33(3):4-7. WANG Guangquan,YUAN Xigang,LIU Chunjiang,et al. Recent progress in researches on pressure drop of structured packing[J]. Chemical Engineering,2005,33(3):4-7. [83] WOERLEE G F,BERENDS J A. Capacity model for vertical pipes and packed columns based on entrainment[J]. Chemical Engineering Journal,2001,84(6):355-366. [84] HUTTON B E T,LEUNG L S,BROOKS P C,et al. On flooding in packed columns[J]. Chemical Engineering Science,1974,29(2):493-500. [85] BILLET R,SCHULTES M. Fluid dynamics and mass transfer in the total capacity range of packed columns up to the flood point[J]. Chemical Engineering & Technology,1995,18(6):371-379. [86] ECKERT J S. What affects packing performance[J]. Chemical Engineer Progress,1966,62(1):18-26. [87] BILLET R,SCHULTES M. Predicting mass transfer in packed columns[J]. Chemical Engineering & Technology,1993,16(1):1-9. [88] BRAVO J L,ROCHA J A,FAIR J R. Mass transfer in gauze packings[J]. Hydrocarbon Processing,1985,64(1):91-95. [89] OLUJIC Z. Development of a complete simulation model for predicting the hydraulic and separation performance of distillation columns equipped with structured packings[J]. Chemical and Biochemical Engineering Quarterly,1997,11(1):31-46. [90] 周伟,梁泰安,于长江,等. 组片式波纹填料:2231577Y[P]. 1996-07-24. ZHOU Wei,LIANG Taian,YU Changjiang. Group-type corrugated packing:2231577Y[P]. 1996-07-24. [91] 史斌豪,陈雁. 浅析填料塔在空分装置中的应用[J]. 广东化工,2013,40(15):164-165. SHI Binhao,CHEN Yan. Packed tower analyzed in the application of air separation unit[J]. Guangdong Chemical Industry,2013,40(15):164-165. [92] 马国平. 填料在高浓度淀粉废水生物处理中的应用研究[D]. 兰州:西北师范大学,2007. MA Guoping. Application of carriers in the biotreatment of high concentration starch wastewater[D]. Lanzhou:Northwest Normal University,2007 [93] 姜美美. 新型组合填料塔处理抗生素废水的研究[D]. 广州:华南理工大学,2011. JIANG Meimei. The study of treatment of wastewater containing amoxicillin in a novel style combing biological packing tower[D]. Guangzhou:South China University of Technology,2011. [94] 韦玮. 硅胶基质固相萃取填料及其在医药,食品,环境分析中的应用[D]. 天津:天津大学,2007. WEI Wei. Silicone matrix solid phase extraction and its application in medicine,food and environmental analysis[D]. Tianjin:Tianjin University,2007. [95] 兰州石油机械研究所. 现代塔器技术[M]. 北京:中国石化出版社,2005. Lanzhou Petroleum Machinery Research Institute. Modern tower technology[M]. Beijing:China Petrochemical Press,2005. [96] 皮耀,李群生,田云苗. 导向固定阀型塔板上气液流体力学性能的研究[J]. 化工进展,2005,26(s1):111-114. PI Yao,LI Qunsheng,TIAN Yunmiao. Hydrodynamic performance of flow-guided fixed valve trays[J]. Chemical Industry and Engineering Progress,2005,26(s1):111-114. [97] CONG H,LI X,LI Z,et al. Combination of spiral nozzle and column tray leading to a new direction on the distillation equipment innovation[J]. Separation and Purification Technology,2016,158:293-301. [98] HUNT C A,HANSON D N,WILKE C R. Capacity factors in the performance of perforated-plate columns[J]. AIChE Journal,1955,1(4):441-451. [99] 张志恒. 浮阀塔板流体力学和传质性能的研究[D]. 天津:天津大学,2005. ZHANG Zhiheng. Study on hydrodynamic Performance and mass transfer efficiency of valve trays[D]. Tianjin:Tianjin University,2005. [100] COLWELL C J. Clear liquid height and froth density on sieve trays[J]. Industrial & Engineering Chemistry Process Design and Development,1981,20(2):298-307. [101] 薛珺. 多种塔板传质性能的比较研究[D]. 上海:华东理工大学,2013. XUE Jun. Comparative study of mass transfer performance for trays[D]. Shanghai:East China University of Science and Technology,2013. [102] 杨宏喜. 一种新型浮阀塔板传质性能的研究[D]. 上海:华东理工大学,2012. YANG Hongxi. Research of mass transfer efficiency for a new floating valve tray[D]. Shanghai:East China University of Science and Technology,2012. [103] 李春利,马晓冬. 大通量高效传质技术——立体传质塔板CTST的研究进展[J]. 河北工业大学学报,2013,42(1):19-28. LI Chunli,MA Xiaodong. The research progress of high throughput high-efficient mass transfer technology-three-dimensional mass transfer tray CTST[J]. Journal of Hebei University of Technology,2013,42(1):19-28. [104] 李春利,孙玉春,王志英,等. 新型立体传质塔板CTST的研究与开发进展[J]. 河北工业大学学报,2004,33(2):155-162. LI Chunli,SUN Yuchun,WANG Zhiying,et al. The research and developments of CTST[J]. Journal of Hebei University of Technology,2004,33(2):155-162. [105] 姚克俭,祝玲钰,计建炳,等. 复合塔板的开发及其工业应用[J]. 石油化工,2000,29(10):772-775. YAO Kejian,ZHU Lingjue,JI Jianbing,et al. The development of composite plate and its industrial application[J]. Petrochemical Technology,2000,29(10):772-775 [106] 姚克俭,章渊昶,王良华,等. 新型高效大通量DJ系列塔板的研究与工业应用[J]. 化工进展,2003,22(3):228-232. YAO Kejian,ZHANG Yuanchang,WANG Lianghua,et al. Research and applications of high efficiency and high capacity DJ series tray[J]. Chemical Industry and Engineering Progress,2003,22(3):228-232. [107] 俞晓梅,徐崇嗣. MD型塔板及其改进型的研究和应用[J]. 全面腐蚀控制,1994,8(4):49-51. YU Xiaomei,XU Chongsi. The research and application of the MD type tray and its modified type[J]. Total Corrosion Control,1994,8(4):49-51. [108] LI H,FU L,LI X,et al. Mechanism and analytical models for the gas distribution on the SiC foam monolithic tray[J]. AIChE Journal,2015,61(12):4509-4516. [109] YAN P,LI X,LI H,et al. Hydrodynamics and flow mechanism of foam column trays:contact angle effect[J]. Chemical Engineering Science,2018,176:220-232. [110] LI X,YAN P,LI H,et al. Fabrication of tunable,stable,and predictable superhydrophobic coatings on foam ceramic materials[J]. Industrial & Engineering Chemistry Research,2016,55(38):10095-10103. [111] AGRAWAL R,FIDKOWSKI Z T. Are thermally coupled distillation columns always thermodynamically more efficient for ternary distillations[J]. Industrial & Engineering Chemistry Research,1998,37(8):3444-3454. [112] DEJANOVIC I,MATIJASEVIC L,OLUJIC Z. Dividing wall column-A breakthrough towards sustainable distilling[J]. Chemical Engineering and Processing:Process Intensification,2010,49(6):559-580. [113] YILDIRIM Ö,KISS A A,KENIG E Y. Dividing wall columns in chemical process industry:a review on current activities[J]. Separation and Purification Technology,2011,80(3):403-417. [114] RONG B G. Systematic synthesis of dividing-wall columns for multicomponent distillations[D] Eindhoven:Eindhoven University of Technology,2010:205-210. [115] LUSTER E W. Apparatus for fractionating cracked products:US1915681[P].1933-06-27. [116] WRIGHT R O. Fractionation apparatus:US2471134[P]. 1949-05-24. [117] OLUJIA B K,JANSEN H,RIETFORT T,et al. Distillation column internals/configurations for process intensification[J]. Chemical and Biochemical Engineering Quarterly,2003,17:301-309. [118] 孙兰义,李军,李青松. 隔壁塔技术进展[J]. 现代化工,2008,28(9):38-41. SUN Lanyi,LI Jun,LI Qingsong. Progress in technology of dividing wall column[J]. Modern Chemical Industry,2008,28(9):38-41. [119] KOLBE B,WENZEL S. Novel distillation concepts using one-shell columns[J]. Chemical Engineering and Processing:Process Intensification,2004,43(3):339-346. [120] SPENCER G,RUIZ F J. Consider dividing wall distillation to separate solvents:using an established technology as part of a revamp installation provided new products at lower capital and operating costs than conventional methods[J]. Hydrocarbon Processing,2005,84(7):90-94. |
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