| 光谱学与光谱分析 |
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| Studies on the Reactions of Unsaturated Chloride Polyether Polyol with Trimethyl Phosphite by FTIR |
| ZHANG Tian-lin1,LI Zai-feng2,JIA Zhen1,WANG Jun-hong1 |
1. Huaihai Institute of Technology, Lianyungang 222005, China
2. Qingdao University of Science & Technology, Qingdao 266042, China |
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Abstract The reactions of unsaturated chloride polyether polyol with trimethyl phosphite have been studied by FTIR, which was prepared by copolymerization of ethanediol, allyl glycidyl ether and epoxychloropropane. The experimental results showed that the reaction included ester-exchange reaction, ester-exchange polymerization and Arbuzov rearrangement. The process conditions such as catalyst,mass rate and reaction time were determined through the experiments. The analytic results indicated that the reaction temperature was the key controling the process and the reaction products are suitable for reactive multifunctional flame retarders.
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Received: 2003-09-26
Accepted: 2003-12-28
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Corresponding Authors:
ZHANG Tian-lin
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| Cite this article: |
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ZHANG Tian-lin,LI Zai-feng,JIA Zhen, et al. Studies on the Reactions of Unsaturated Chloride Polyether Polyol with Trimethyl Phosphite by FTIR [J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2004, 24(11): 1334-1337.
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http://www.gpxygpfx.com/EN/Y2004/V24/I11/1334 |
[1] WANG Xin-long, ZHU Xu-fei, SONG Ye et al(王新龙,朱绪飞,宋 烨等). Chinese Advances in Fine Petrochemicals(精细石油化工进展), 2001, 2(5): 11.
[2] LI Xin, OU Yu-xiang(李 昕,欧育湘). J. of Beijing Institute of Technology(北京理工大学学报), 2001,21(3):388.
[3] ZHANG Tian-lin, JIA Zhen(张田林,贾 振). Polyurethyanes Industry(聚氨酯工业), 2002, 17(10):47.
[4] ZHANG Tian-lin, JIA Zhen(张田林,贾 振). J. of HuaHai Institute of Techndogy(淮海工学院学报), 2003, (2):11.
[5] YIN Lun-xiang, WANG Yan-qin(殷伦琴,王艳琴). J. of Shandong Normal University(山东师范大学学报), 1996,11(1):33.
[6] Kosolapoff G M, Organic Reactions. Loudon: John Wiley & Sons Inc.,1951. Vol. 6.
[7] XIE Hong-quan, ZHANG Cong-yun, LIU Yong(谢洪泉,张从云,刘 勇). Chem. J. of Chinese Universities(高等学校化学学报), 1992,13(12):1613.
[8] XU Pei-lin, ZHANG Shu-qin(徐培林,张淑琴). The Handbook of PU Materials(聚氨酯材料手册). Beijing:Chemical Industry Press(北京: 化学工业出版社), 2002. 179.
[9] FAN Zhong-lei, LIU Da-zhuang, ZHAO Gen-suo(范忠雷, 刘大壮, 赵根锁). Spectrocopy and Spectral Analysis(光谱学与光谱分系),2003, 23(3): 611.
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