固体超强酸SO_4~(2-)/TiO_2/La~(3+)催化合成TDCPP、TBC的研究
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摘要
以三氯氧磷和环氧氯丙烷合成磷酸三(1,3-二氯-2-丙基)酯(TDCPP),以柠檬酸、正丁醇合成柠檬酸三丁酯(TBC)。考察了TDCPP和TBC的酯化合成体系。研究了固体超强酸SO_4~(2-)/TiO_2/La~(3+)在合成TDCPP和TBC中的催化性能。并通过催化剂的活性评价和物化性能表征来研究催化剂的结构与性能的关系,为固体超强酸催化合成TDCPP和TBC的工业化提供了有益的依据。
首先通过正交实验,考察了硫酸浓度、浸渍时间、焙烧温度、焙烧时间对固体超强酸催化剂SO_4~(2-)/TiO_2/La~(3+)的催化活性的影响,并通过IR、XRD、热分析、SEM等方法对催化剂进行了表征。
对TDCPP的酯化反应进行了考察,分别在TiCl_4、AlCl_3和自制固体超强酸催化剂SO_4~(2-)/TiO_2/La~(3+)催化下研究了TDCPP的产率和酸值。研究了催化剂在TDCPP的合成反应中的催化性能和稳定性。结果表明硫酸浓度为0.8mol/L,焙烧温度为550℃,La~(3+)的用量为5 mol%,浸渍时间为24 h,焙烧时间为3h,此时所制得催化剂具有较高的催化活性,TDCPP的产率高达98.5%。并通过IR,热分析等对TDCPP的结构进行了表征。
对柠檬酸三丁酯(TBC)的酯化反应进行了考察,分别在无催化剂、浓硫酸、自制固体超强酸催化剂SO_4~(2-)/TiO_2/La~(3+)催化下,研究了柠檬酸三丁酯(TBC)酯化合成反应中酸转化率、出水量与反应时间的关系,并在固体超强酸催化剂催化下通过单因素实验对酸醇比、催化剂用量等酯化反应条件进行了优化。当催化剂用量为总质量的3.5%,酸醇摩尔比为1:4.5,酯化温度控制在145℃左右时产率高达96.4%。通过IR、热分析对TBC、ATBC的结构进行了表征。
To phosphorus oxychloride and epichlorohydrin Synthesis of (1,3-dichloro-2-propyl) ester (TDCPP), citric acid, n-butyl alcohol synthesis of Tributyl Citrate (TBC). The catalytic properties of the catalyst SO_4~(2-)/TiO_2/La~(3+) in esterification of citric acid with n-butanoland phosphorus oxychloride with epichlorohydrin were studied. The correlation between its structure and properties was also investigated. And through evaluation of the activity of catalysts and physico-chemical characterization of the catalysts to study the relationship between structure and properties of the catalytic synthesis of solid superacid TDCPP、TBC industrialization and provide a useful basis.
By orthogonal experiment, inspected the concentration of sulfuric acid, soaking time, the calcination temperature and baking time on the solid superacid catalyst SO_4~(2-)/TiO_2/La~(3+) the impact of the catalytic activity, and through IR and XRD, thermal analysis and SEM methods of catalyst were characterized.
This paper reported the Acid Value and esterification synthesis of Tris (1, 3-dichloro-2-propyl) ester under TiCl_4、AlCl_3 or solid super acid SO_4~(2-)/TiO_2/La~(3+). The catalytic properties and stability of SO_4~(2-)TiO_2/La~(3+) was surveyed. The suitable synthesis condition are defined as follows: Sulfuric acid concentration is 0.8mol/L, roasting temperature550℃, the mass of La~(3+)5mol%, impregnation time 24h, roasting time 3h. The yield of TDCPP was about 98. 5%. The structure of the product was defined by IR and TG.
This paper reported the esterification synthesis of TBC under no catalyst, H_2S0_4, or solid super acid S0_4~(2-)/Ti0_2/La~(3+) The correlation between reaction conversion, water yieldand reaction time was surveyed. The effects of initial molar ratio and catalyst quantity were investigated and the optimum synthesis conditions were found. The suitable synthesis condition are defined as follows: the mass of catalyst 3.5%, n (citric acid): (n-butyl alcohol) =1: 4.5, esterification of temperaturel45℃. The yield of TBC was about 96. 5%. The structure of the products was defined by IR and TG.
首先通过正交实验,考察了硫酸浓度、浸渍时间、焙烧温度、焙烧时间对固体超强酸催化剂SO_4~(2-)/TiO_2/La~(3+)的催化活性的影响,并通过IR、XRD、热分析、SEM等方法对催化剂进行了表征。
对TDCPP的酯化反应进行了考察,分别在TiCl_4、AlCl_3和自制固体超强酸催化剂SO_4~(2-)/TiO_2/La~(3+)催化下研究了TDCPP的产率和酸值。研究了催化剂在TDCPP的合成反应中的催化性能和稳定性。结果表明硫酸浓度为0.8mol/L,焙烧温度为550℃,La~(3+)的用量为5 mol%,浸渍时间为24 h,焙烧时间为3h,此时所制得催化剂具有较高的催化活性,TDCPP的产率高达98.5%。并通过IR,热分析等对TDCPP的结构进行了表征。
对柠檬酸三丁酯(TBC)的酯化反应进行了考察,分别在无催化剂、浓硫酸、自制固体超强酸催化剂SO_4~(2-)/TiO_2/La~(3+)催化下,研究了柠檬酸三丁酯(TBC)酯化合成反应中酸转化率、出水量与反应时间的关系,并在固体超强酸催化剂催化下通过单因素实验对酸醇比、催化剂用量等酯化反应条件进行了优化。当催化剂用量为总质量的3.5%,酸醇摩尔比为1:4.5,酯化温度控制在145℃左右时产率高达96.4%。通过IR、热分析对TBC、ATBC的结构进行了表征。
To phosphorus oxychloride and epichlorohydrin Synthesis of (1,3-dichloro-2-propyl) ester (TDCPP), citric acid, n-butyl alcohol synthesis of Tributyl Citrate (TBC). The catalytic properties of the catalyst SO_4~(2-)/TiO_2/La~(3+) in esterification of citric acid with n-butanoland phosphorus oxychloride with epichlorohydrin were studied. The correlation between its structure and properties was also investigated. And through evaluation of the activity of catalysts and physico-chemical characterization of the catalysts to study the relationship between structure and properties of the catalytic synthesis of solid superacid TDCPP、TBC industrialization and provide a useful basis.
By orthogonal experiment, inspected the concentration of sulfuric acid, soaking time, the calcination temperature and baking time on the solid superacid catalyst SO_4~(2-)/TiO_2/La~(3+) the impact of the catalytic activity, and through IR and XRD, thermal analysis and SEM methods of catalyst were characterized.
This paper reported the Acid Value and esterification synthesis of Tris (1, 3-dichloro-2-propyl) ester under TiCl_4、AlCl_3 or solid super acid SO_4~(2-)/TiO_2/La~(3+). The catalytic properties and stability of SO_4~(2-)TiO_2/La~(3+) was surveyed. The suitable synthesis condition are defined as follows: Sulfuric acid concentration is 0.8mol/L, roasting temperature550℃, the mass of La~(3+)5mol%, impregnation time 24h, roasting time 3h. The yield of TDCPP was about 98. 5%. The structure of the product was defined by IR and TG.
This paper reported the esterification synthesis of TBC under no catalyst, H_2S0_4, or solid super acid S0_4~(2-)/Ti0_2/La~(3+) The correlation between reaction conversion, water yieldand reaction time was surveyed. The effects of initial molar ratio and catalyst quantity were investigated and the optimum synthesis conditions were found. The suitable synthesis condition are defined as follows: the mass of catalyst 3.5%, n (citric acid): (n-butyl alcohol) =1: 4.5, esterification of temperaturel45℃. The yield of TBC was about 96. 5%. The structure of the products was defined by IR and TG.
引文
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[1]陈河如,郭锡坤,陈敏霞.叔胺作用下无毒增塑剂柠檬酸三丁酯的合成J.汕头大学学报自然科学版1997,12 2:69.
[2]蒋文伟 超强酸催化剂的研究进展。精细化工。1997,(2);13
[3] Tsutomu Yamaguchi, et al.J. phys. chera. 1986,90:3148-3152
[4]肖小时,刘桂元.湖南师范大学自然科学学报,1994,17(1):54
[5]曾健青,罗庆云,王琴等.石油化工,1994,23(3):191-197
[6]张术华.毛支安,化学研究与应用,1997,9(4):327-331
[7]蒋文伟 超强酸催化剂的研究进展[J].精细化工,1997,14(1):46-49
[8]周海峰 固体超强酸催化酯化放应的研究进展2004,12(23):1-6
[9]高滋等.物理化学学报,1994,10(8):698
[10] Ono Y. et. al. Jcat al. Characterization of superacid [J]. 1981, (68): 132.
[11]陈宝树.新型精细化工讲座[J].石油化工,1990,(5):63-70.
[12]缪长喜,陈庆龄,高滋.SO_4~(2-)/ZrO_2超细粒子固体超强酸研究[J].工业催化.1997(4):26-30
[13] Bai, X. - L. ; Su, L. -H. ; Lin, S. -T. Adv. Fine Petrochem.2000,1,40(in Chinese).
[14]林进,化学世界,2000,41,465.
[15] Lin, J. Chin. J. Org. Chem. 2000, 20, 805(in Chinese).
[16]王秋莹,杨青山,许学翔,管盘铭,苏中兴,许言和,应用化学,1998,5,76.
[17]于世涛,高根之,杨锦宗,精细化工,1996,13,46
[18]王茂元,仇立干.固体超强酸Al_2O_3/SO_4~(2-)催化合成乙酸苄酯的研究,化学与黏合,2007,29,1
[19]张萍,李平,贾振斌 纳米级SO_4~(2-)/TiO_2固体超强酸的红外光谱及催化活性[J]精细化工,2003,20(3):160-186
[20]高滋,陈建民等SO_4~(2-)/ZrO_2固体超强酸催化剂上的正构烧烃反应[J].化学学报.1994,56(1).
[21]王春华,纪春暖,曲荣君,等.稀土La介掺杂固体超强酸SO_4~(2-)/TiO_2催化合成一芳基乙烷的研究[J].化学研究与应用,2005,17(1):78-80
[22]张强,矫庆泽,阂恩泽.固体超强酸(SO_4~(2-)/ZrO_2)的异丁烷/1-丁烯烷基化反应性能和失活研究[J].高等学校化学学报,2005,26(6):1 130-1132.
[23]王知彩,孙正俊.SO_4~(2-)/ZrO_2固体化剂催化甲苯与氯化苄的苄基化反应[J].石油化工,2005,34(10):954-958.
[24] Colo' n G, Hidalgo M C, Munuera G, et al. Structural and surface approach to the enhanced photocatalytic activity of sulfated TiO_2 photocatalys [J]. applied catalysis B: Environmental, 2006, 63: 45-59.
[25] Nakajima A, ObataH, KameshimaY, et al. Photocatalytic destruction of gaseous toluene by sulfated TiO2 powder[J]. Catalysis Communications, 2006, 6: 716-720.
[26]白秀丽,苏丽宏,林淑田,精细石油化工进展,2000,1,40.
[27]孙旭,王小凤,靳通收,李同双,河北大学学报(自然科学版),2001,21,49.
[28]于世涛,宋湛谦,精细化工,1999,16,34.
[29]李远志,魏富智,周俊婷,精细化工,2000,17,88
[30] Liu,K.; Meuzelaar, H. L C. Fuel. Technol. 1996 49,1.
[31] Jin, T. S. ; Guo, J. J. ; Yin, Y. H. ; Zhang, S. H. ; Li, T. S. J . Chem. Res.,Synop. 2002(inpress).
[32] Na. gi, S. M.. ;Zubkov, E.A. ; Shubin, V. G.. Izv. Akad. Nauk SSSR,Ser. Khim. 1990,1650.
[33] K, Arata, M . Hino. prepration of superacds by metal oxides and theircatalyic action[J]. Materials chemistry and Physics, 1990, 26:213-237.
[34]王静雅.改性固体超强酸SO_4~(2-)/TiO_2制备及其催化酷化反应活性研究[J]沈阳化工学院学报,1998,(3):189-198.
[35]胡百华,王琪.固体超强酸在酷化反应中的应用[J].精细石油化工,1989,(1):32-35.
[36]廖世军,张海,罗忠,等.醇醋化反应的催化作用[J]精细石油化工,1991,(3):12-14.
[37] IK, Arata, M. Hino. preparation of superacds by metal ox ides and their catalyic action[J].Meterials Chemistry and Physics, 1990, 26:213 - 237.
[38]王新平,唐新硕.石油化工,1996,25(1):20
[39]陈建民,缪一长喜等.高等学校化学学报,1995,17(5):797
[40]唐新硕,朱逸七,王明.石油化工,1984,13(4):252
[41] Tanabe K, Misono M, One Y et al.New Solid Acids and Bases. Kodansha,Tokyo, 1989: 6-7.
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