采用不同极性的溶剂作为环己酮肟的溶剂,考察了溶剂极性对B2O3/TiO2-ZrO2催化环己酮肟气相Beckmann重排反应性能的影响. 结果表明,除乙醇外,随着溶剂极性的增大,己内酰胺的收率逐渐提高. 在所考察的溶剂范围内,当采用极性最强的乙腈为溶剂时,B2O3/TiO2-ZrO2的催化性能最佳,连续反应9 h,环己酮肟的转化率为100%,己内酰胺的选择性高达98.6%. 极性较强的溶剂可显著改善B2O3/TiO2-ZrO2催化性能的原因主要是其有利于反应所生成的己内酰胺从催化剂表面快速脱附,从而可抑制己内酰胺进一步发生聚合及分解等副反应.
参考文献
| [1] | 毛东森,卢文奎,陈庆龄,卢冠忠.固体酸代替液体酸催化剂的环境友好新工艺[J].石油化工,2001(02):152-156. |
| [2] | 毛东森,卢冠忠,陈庆龄,卢文奎,谢在库.环己酮肟气相Beckmann重排制己内酰胺催化剂研究进展[J].工业催化,1999(03):3. |
| [3] | 陶伟川,毛东森,陈庆龄.分子筛催化环己酮肟气相Beckmann重排制己内酰胺研究新进展[J].石油化工,2004(05):475-480. |
| [4] | 毛东森,卢冠忠,陈庆龄,卢文奎,谢在库.固体酸催化环己酮肟Beckmann重排制己内酰胺研究进展[J].化工进展,2000(03):25-29. |
| [5] | Landis P S;Venuto P B .[J].Journal of Catalysis,1966,6(02):245. |
| [6] | 程时标;徐柏庆;唐守平;蒋山,蔡天锡,王祥生 .[J].催化学报,1996,17(04):330. |
| [7] | Xu B Q;Cheng Sh B;Zhang X;Zhu Q M .[J].Catalysis Today,2000,63(2-4):275. |
| [8] | Kitamura M;Ichihashi H .[J].Studies in Surface Science and Catalysis,1994,90:67. |
| [9] | Rseler J;Heitmann G;Hlderich W F .[J].Applied Catalysis A:General,1996,144(1/2):319. |
| [10] | Dai L X;Hayasaka R;Iwaki Y;Koyano K A, Tatsumi T.[J].Chemical Communications,1996(09):1071. |
| [11] | Dai L X;Koyama K;Miyamoto M;Tatsumi T .[J].Applied Catalysis A:General,1999,189(02):237. |
| [12] | Dai LX.;Tatsumi T.;Koyama K. .Catalytic application of mesoporous molecular sieves to vapor-phase Beckmann rearrangement of cyclohexanone oxime[J].Catalysis Letters,1998(3/4):211-214. |
| [13] | 毛东森,卢冠忠,陈庆龄,谢在库,张玉贤.B2O3/TiO2-ZrO2催化环己酮肟气相Beckmann重排反应的研究Ⅰ. B2O3含量的影响[J].催化学报,2002(01):9-14. |
| [14] | 毛东森,陈庆龄,卢冠忠,张玉贤.B2O3/TiO2-ZrO2催化环己酮肟气相Beckmann重排反应的研究Ⅲ. 反应条件的影响[J].催化学报,2002(05):443-447. |
| [15] | 毛东森,陈庆龄,卢冠忠.B2O3/TiO2-ZrO2催化环己酮肟气相Beckmann重排反应研究Ⅳ. TiO2-ZrO2组成的影响[J].催化学报,2002(06):525-529. |
| [16] | Mao D S;Lu G Zh;Chen Q L;Xie Z K, Zhang Y X .[J].Catalysis Letters,2001,77(1-3):119. |
| [17] | Mao D S;Chen Q L;Lu G Zh .[J].Applied Catalysis A:General,2003,244(02):273. |
| [18] | Mao D S;Lu G Zh;Chen Q L .[J].Applied Catalysis A:General,2004,263(01):83. |
| [19] | Wypych G;范耀华.溶剂手册[M].北京:中国石化出版社,2002:448. |
| [20] | Anand R;Khomane R B;Rao B S;Kulkarni B D .[J].Catalysis Letters,2002,78(1-4):189. |
| [21] | Komatsu T;Maeda T;Yashima T .[J].Microporous and Mesoporous Materials,2000,35-36(1-3):173. |
| [22] | Yashima T;Oka N;Komatsu T .[J].Catalysis Today,1997,38(02):249. |
| [23] | Kob N;Drago R S .[J].Catalysis Letters,1997,49(3-4):229. |
| [24] | Takahashi T;Kai T;Nakao E .[J].Applied Catalysis A:General,2004,262(02):137. |
| [25] | Butler J D;Poles T C .[J].Journal of the Chemical Society Perkin Transactions 2,1973,2(01):41. |
| [26] | Ushikubo T;Wada K .[J].Journal of Catalysis,1994,148(01):138. |
| [27] | Zbinden R;Hall H K Jr .[J].Journal of the American Chemical Society,1960,82(05):1215. |
| [28] | Hall H K;Zbinden R .[J].Journal of the American Chemical Society,1958,80(23):6428. |
| [29] | Delmastro A;Gozzelino G;Mazza D;Vallino M, Busca G, Lorenzelli V .[J].Journal of the Chemical Society,Faraday Transactions,1992,88(23):2065. |
| [30] | Curtin T;McMonagle J B;Ruwet M;Hodnett B K .[J].Journal of Catalysis,1993,142(01):172. |
| [31] | Budavari S;O'Neil M J;Heckelman P E;Kinneary J F.The Merck Index. 12th Ed[M].Whitehouse Station (NJ):Merck & Co Inc,1996:1655. |
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