固体酸催化在维生素C生产中的应用研究
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摘要
固体酸催化剂是石油化工和有机合成工业中比较有前途的催化剂之一,本文研究了以2-酮基-L-龙酸、甲醇为原料,以沉淀浸渍法制备的SO_4~(2-)/Fe_2O_3为催化剂,催化合成2-酮基-L-古龙酸甲酯的酯化反应体系。
根据对SO_4~(2-)/Fe_2O_3和SO_4~(2-)/ZrO2两种固体酸催化剂催化活性和寿命的研究对比,筛选出较为理想的SO_4~(2-)/Fe_2O_3作为催化剂。在实验中,研究了影响2-酮基-L-古龙酸甲酯化反应的主要操作条件:催化剂用量、反应温度、反应时间、醇酸的摩尔比对酯化反应的影响,并利用正交实验设计法筛选出最佳的酯化反应工艺条件,即催化剂用量为2~3%,反应温度在66~68℃,反应时间为2.5~3h,甲醇与2-酮基-L-古龙酸的摩尔比为19~20。结果表明,采用酯化新工艺进行维生素C中间体维生素C钠的合成,2-酮基-L-古龙酸与甲醇反应的酯化率可达到93.87%以上,比原工艺提高了2.37%,维生素C钠干品质量明显提高,含量达到了91.5%,提高了2%。同时,考察了通过过滤方法回收催化剂的情况。
研究结果表明,SO_4~(2-)/Fe_2O_3作为维生素C生产中2-酮基-L-古龙酸与甲醇的酯化反应的催化剂所确定的新工艺与原工艺相比,无论从酯化反应的收率及中间体的质量方面都有明显提高。而SO_4~(2-)/Fe_2O_3作为反应的催化剂具有易分离、无污染、无腐蚀性,克服了浓硫酸的缺点,是一种极具潜力的新型绿色环保催化剂。
Solid acid catalyst is the petrochemical and industrial organic synthesis in the future more of a catalyst, In this paper, a 2-Keto-L-Lung acid, methanol as raw materials and precipitation prepared by soaking the SO_4~(2-)/Fe_2O_3 as a catalyst, Synthesis of 2-Keto-L-Gulong methyl esterification system.
According to SO_4~(2-)/Fe_2O_3 and SO_4~(2-)/ZrO2 two solid acid catalyst activity and life of contrast, Screening to a more satisfactory SO_4~(2-)/Fe_2O_3 as a catalyst. In the experiment to study the impact of 2-Keto-L-Gulong reaction of methyl the main operating conditions: The amount of catalyst, temperature, reaction time, the ratio of alkyd esterification of the impact and use of orthogonal experimental design selected the best esterification process, That is, the amount of catalyst for 2 to 3 percent, the reaction temperature in the 66 ~ 68℃, the reaction time is 2.5 ~ 3 h, methanol and 2-Keto-L-Gulong acid ratio of 19 to 20. The results showed that the use of new technology esterification intermediate vitamin C synthesis of vitamin C sodium, 2-L-gulonic acid and methanol reaction yield up to 93.87 percent more than the original process than the 2.37 percent increase, Vitamin C sodium dry goods significantly improve the quality, content reached 91.5 percent, increased by 2%. At the same time, inspected the catalyst for recovery through the filter approach the situation.
The results show that SO_4~(2-)/Fe_2O_3 as the production of vitamin C 2-L-gulonic acid and methanol catalyst identified by the new technology compared with the original process, Whether from the yield and the quality of both intermediate increased significantly. The reaction SO_4~(2-)/Fe_2O_3 as a catalyst for easy separation and pollution-free, non-corrosive, has overcome the shortcomings of concentrated sulphuric acid, is a great potential of the new green catalyst.
根据对SO_4~(2-)/Fe_2O_3和SO_4~(2-)/ZrO2两种固体酸催化剂催化活性和寿命的研究对比,筛选出较为理想的SO_4~(2-)/Fe_2O_3作为催化剂。在实验中,研究了影响2-酮基-L-古龙酸甲酯化反应的主要操作条件:催化剂用量、反应温度、反应时间、醇酸的摩尔比对酯化反应的影响,并利用正交实验设计法筛选出最佳的酯化反应工艺条件,即催化剂用量为2~3%,反应温度在66~68℃,反应时间为2.5~3h,甲醇与2-酮基-L-古龙酸的摩尔比为19~20。结果表明,采用酯化新工艺进行维生素C中间体维生素C钠的合成,2-酮基-L-古龙酸与甲醇反应的酯化率可达到93.87%以上,比原工艺提高了2.37%,维生素C钠干品质量明显提高,含量达到了91.5%,提高了2%。同时,考察了通过过滤方法回收催化剂的情况。
研究结果表明,SO_4~(2-)/Fe_2O_3作为维生素C生产中2-酮基-L-古龙酸与甲醇的酯化反应的催化剂所确定的新工艺与原工艺相比,无论从酯化反应的收率及中间体的质量方面都有明显提高。而SO_4~(2-)/Fe_2O_3作为反应的催化剂具有易分离、无污染、无腐蚀性,克服了浓硫酸的缺点,是一种极具潜力的新型绿色环保催化剂。
Solid acid catalyst is the petrochemical and industrial organic synthesis in the future more of a catalyst, In this paper, a 2-Keto-L-Lung acid, methanol as raw materials and precipitation prepared by soaking the SO_4~(2-)/Fe_2O_3 as a catalyst, Synthesis of 2-Keto-L-Gulong methyl esterification system.
According to SO_4~(2-)/Fe_2O_3 and SO_4~(2-)/ZrO2 two solid acid catalyst activity and life of contrast, Screening to a more satisfactory SO_4~(2-)/Fe_2O_3 as a catalyst. In the experiment to study the impact of 2-Keto-L-Gulong reaction of methyl the main operating conditions: The amount of catalyst, temperature, reaction time, the ratio of alkyd esterification of the impact and use of orthogonal experimental design selected the best esterification process, That is, the amount of catalyst for 2 to 3 percent, the reaction temperature in the 66 ~ 68℃, the reaction time is 2.5 ~ 3 h, methanol and 2-Keto-L-Gulong acid ratio of 19 to 20. The results showed that the use of new technology esterification intermediate vitamin C synthesis of vitamin C sodium, 2-L-gulonic acid and methanol reaction yield up to 93.87 percent more than the original process than the 2.37 percent increase, Vitamin C sodium dry goods significantly improve the quality, content reached 91.5 percent, increased by 2%. At the same time, inspected the catalyst for recovery through the filter approach the situation.
The results show that SO_4~(2-)/Fe_2O_3 as the production of vitamin C 2-L-gulonic acid and methanol catalyst identified by the new technology compared with the original process, Whether from the yield and the quality of both intermediate increased significantly. The reaction SO_4~(2-)/Fe_2O_3 as a catalyst for easy separation and pollution-free, non-corrosive, has overcome the shortcomings of concentrated sulphuric acid, is a great potential of the new green catalyst.
引文
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[3]王瑾,刘志敏,维生素C生产及应用概况[J],辽宁化工,1995,5:17~19
[4]聂国军,固体酸催化酯化反应进展,化工时刊,1991,(3):10~15
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[6]杜长海,刘蕴天,贺岩峰,SO42-/MxOy型固体超强酸催化剂的发展与应用,长春工业大学学报,2002,23(8):102~107
[7]黄仲涛,林维明,庞先,工业催化剂设计与开发,广州:华南理工大学出版社,1991
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[9]郭灿雄,固体超强酸催化剂上异丁烷/丁烯烷基化反应的研究,博士学位论文,吉林大学,1995
[10]田部浩三,小野嘉夫,服部英等,新固体酸和碱及其催化作用,北京:化学工业出版社,1991
[11]张毓瑞,韩丽君,蔡树兴,用固体酸催化羧酸酯化反应(Ⅰ),石油化工,1986,15(7):441~443
[12]张毓瑞,韩丽君,苏慈生,用固体酸催化羧酸酯化反应(Ⅱ),石油化工,1987,16(1):38~41
[13]马德埒,顾树珍,用分子筛催化剂液相合成乙酸丁酯,石油化工,1989,18(7):431~433
[14]刘勇,成本诚,酯化反应中的固体酸催化剂,湖南化工,1991,21(3):10~13
[15] Ziegler F .E., Berger G. D., A mild method for the esterification of fatty acids, Synth. Commun.,1979,9(6):539
[16]魏荣宝,梁娅,高铁男等,改性HZSM-5分子筛催化合成巯基乙酸酯有研究[J].应用化学,1994,11(6):61~64
[17]林进,张艳峰,磷钨酸催化合成癸二酸二乙酯的研究[J],精细化工,2000,17(2):86~87
[18]刘淑芝,焦文贞,赵兴茹,用路易斯酸作催化剂制取羧酸酯[J],河北化工,1990(4):22~23
[19]俞善信,唐艳春,蔡湘雯,强酸性树脂催化合成二乙酸二乙醇酯[J],化学试剂,1998,20(3):180~181
[20]赵汝淇,稀土固体超强酸SO42––TiO2–La3+催化合成马来酸二丁酯[J] ,精细化工,2000,17(3):180~182
[21]田部浩三,郑禄彬译,新固体超强酸和碱及其催化作用,北京:化学工业出版社,1991
[22]曾健表,罗庆云,王琴,SO42-/MxOy型固体超强酸催化剂的研究进展,石油化工,1994,23(3):191~197
[23]蒋文伟,超强酸催化剂的研究进展,精细化工,1997,14(1):46~49
[24] Arata K, Hino M. Synthesis of the solid surperacid catalysr of tin oxide treated with sulfate ion [J]. Appl. Catal., 1990, (59): 205~212
[25]张黎,王琳,张建民,SO42-/TiO2固体超强酸的研究,高等学校化学学报,2000,21(1):116~119
[26]夏勇德,华伟明,高滋,Al促进SO42-/MxOy(M=Zr、Ti、Fe)固体超强酸的研究,化学学报,2000,58(1):86~90
[27] Hino M., Arata K., Reaction of butane to isobutene catalyzed by iron oxide treated with sulfate ion.Solid superacid catalyst, Chem. Lett., 1979, 94(10): 1259
[28]高滋,陈建民,SO42-/ZrO2和SO42-/Fe2O3固体超强酸研究,高等学校化学学报,1994,15(6):873~877
[29]蒋先明等,磷钨酸催化合成富马酸二甲酯的研究,化学世界,1995,36(3):133~135
[30]钱建华,李希章,SnO催化合成环烷酸异辛酯,抚顺石油学院学报,1995,15(4):15~17
[31]罗来龙,SnO催化合成乙二醇酯增塑剂的研究,化学工程师,1994,(6):4~9
[32]张粉宝,徐秋,离子交换树脂催化酯化反应的研究辽宁化工,1993,(3):38~40
[33]李鹏飞等,在离子交换树脂上负载AlCl3的固体超强酸催化剂的研究,精细石油化工,1993,(3):33~36
[34]龙立平,杨忠娥,钟桐生等,强酸性阳离子交换树脂催化合成丁二酸二丁酯,合成化学,2004,(2):194~196
[35]杨辉荣等,羧酸酯催化合成的新方法,精细化工,1995,12(1):33~36
[36]张惠玲等,固体超强酸催化合成醋酸丁酯,广西化工,1995,24(1):16~18
[37]唐薰,张新胜,大孔磺酸树脂为载体的超强酸催化剂的合成石油化工,1986,15(10):589~592
[38]李鹏飞等,在离子交换树脂上负载AlCl3的固体超强酸催化剂的研制,精细石油化工,1993,(1):17~20
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