碱式氯化镁晶须合成及应用的研究
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摘要
在课题组已成功合成碱式氯化镁晶须的基础上,为提高碱式氯化镁晶须的产率,进行了在结晶母液中补加氨水或同时加入氨水和氯化镁的循环试验,并进行了在合成碱式氯化镁结晶过程中加入添加剂、晶种和表面活性剂试验,研究对碱式氯化镁晶须合成及性能的影响。同时对碱式氯化镁晶须在造纸、塑料及热熔型胶粘剂等方面的应用进行了一定的研究。研究结果表明:母液循环可以提高碱式氯化镁晶须的产率;添加晶种可明显的改善晶形;合适的添加剂可以降低晶体生长速度并可提高晶须的粒径分布;而同时加入不同用量的晶种和Pb~(2+),试验结果表明晶种含量在0.075%,Pb~(2+)在20~50ppm时,晶须的产率高,晶形好;表面活性剂对产品的分散性能有所改进。晶须作为造纸填料,可使纸张的白度和不透明度提高,留着率比造纸常用填料轻质碳酸钙高;用作塑料填料,可使塑料的冲击强度提高,阻燃性能比常用阻燃材料氢氧化镁有较大的提高;添加到热熔型胶粘剂中,与轻质碳酸钙混合使用可明显提高热熔胶的剥离强度、软化点、硬度、耐侯性以及固化速度。
本研究为提高碱式氯化镁晶须合成产率以及晶须的应用开发提供了一定的理论依据。
The topic is on the basis of the synthesis of the basic magnesium chloride whisker. The research perform the recycling experiment on the synthesis and property of the basic magnesium chloride whisker by adding ammonia or magnesium chloride and ammonia simultaneously into the mother liquid of crystal and during the synthesization of the basic magnesium chloride whisker, we add the seed crystal, additive, or surfactant in order to increase the yield of crystal. At the same time, The applications of the papermaking, plastics and thermo tropic adhesives on the basic magnesium chloride whisker are studied. The experimental results show that the cycle of the mother liquid increases the yield of the product, the seed crystal can improve long-diameter ratio remarkably, the proper additive reduces the speed of crystal growth and make size distribution homogenize. Through appending different seed crystal and bivalent lead at one time, we may receive when the content of the seed crystal is 0.075% and Pb2+ is 20-50ppm, the yield of the basic magnesium chloride whisker is high and crystal shape is good. The surface active agent can improve dispersion performance of the basic magnesium chloride whisker. The crystal is applied to the papermaking that can raise whiteness and non-transparency, remains-proportion of the crystal is higher than the usual light calcium carbonate. As for plastics, it can improve impact strength in the plastics, its inhibiting-burning capability is advancing bigger than the common inhibiting-burning material of magnesium hydroxide. Concerning the thermo tropic adhesives, the physical property of compound-packing is higher than the one of single-packing, namely remover strength ,softening point, hardness, climate tolerance and the speed of consolidation are high.
The experiment settles the foundation for its further application and offers the basis for the yield's improvement of the basic magnesium chloride whisker.
本研究为提高碱式氯化镁晶须合成产率以及晶须的应用开发提供了一定的理论依据。
The topic is on the basis of the synthesis of the basic magnesium chloride whisker. The research perform the recycling experiment on the synthesis and property of the basic magnesium chloride whisker by adding ammonia or magnesium chloride and ammonia simultaneously into the mother liquid of crystal and during the synthesization of the basic magnesium chloride whisker, we add the seed crystal, additive, or surfactant in order to increase the yield of crystal. At the same time, The applications of the papermaking, plastics and thermo tropic adhesives on the basic magnesium chloride whisker are studied. The experimental results show that the cycle of the mother liquid increases the yield of the product, the seed crystal can improve long-diameter ratio remarkably, the proper additive reduces the speed of crystal growth and make size distribution homogenize. Through appending different seed crystal and bivalent lead at one time, we may receive when the content of the seed crystal is 0.075% and Pb2+ is 20-50ppm, the yield of the basic magnesium chloride whisker is high and crystal shape is good. The surface active agent can improve dispersion performance of the basic magnesium chloride whisker. The crystal is applied to the papermaking that can raise whiteness and non-transparency, remains-proportion of the crystal is higher than the usual light calcium carbonate. As for plastics, it can improve impact strength in the plastics, its inhibiting-burning capability is advancing bigger than the common inhibiting-burning material of magnesium hydroxide. Concerning the thermo tropic adhesives, the physical property of compound-packing is higher than the one of single-packing, namely remover strength ,softening point, hardness, climate tolerance and the speed of consolidation are high.
The experiment settles the foundation for its further application and offers the basis for the yield's improvement of the basic magnesium chloride whisker.
引文
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26.师昌绪.材料大辞典.北京:化学工业出版社,1994
27. Yuchun O. Feng Y. Jin C. Journal of Applied Polymer Science. 1997, 64(12): 2317~2322
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31.尚文宇,谢大荣,刘庆峰.中国塑料.2000(3):24~26
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37. Yamada Shinichi. Hamano Masaaki. JP87-190256
38. Tjong S C. Meng Y Z. Polymer, 1999,40(5):1109~1117
39. Jiang Wei,Tjong S C. Polym Degrad Stab, 1999, 66(2) :241~246
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41. Tjong S C. Meng Y Z. J Appl Polym Sci, 1999, 72(4):501~508
42. Umeda Takashi. Nakazato Teruhiko. JP96-259789
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44.贺奉嘉,黄伯云.粉末冶金技术.1993,11(3):213~217
45.潘金生,陈永华.复合材料学报.1995,12(4):1~7
46. Tabuchi Akira. Nakamura Morihiko. et al. JP87-241966
47. Hisashi Hideyuki. JP99-53941
48. Kondo Takao. JP88193835
49.周祚万,彭卫明,邓海.化工新型材料.1998(11):13~15,26
50.张文,陈长勇,金增平等.青岛海洋学院学报,1998(4):361~364
51.孟季茹,赵磊,梁国正,贾巧英.化工新型材料.2001(29):1~6
52.隆言泉等.造纸原理与工程
53.制浆造纸试验技术.1998.12
54.李子东,李广宇,于敏.实用胶粘剂原材料手册.北京:国防工业出版社,1999:581
55.李慧青,张旖,孙萱,张淑芬.无机盐工业.2002 34(2):17~19
56.袁俊生,刘燕兰,大有发展前途的海洋无机盐晶须,海湖盐与化工,2000,3
57. Cockayne B, Filby J D. The Growth of Mgo Crystal from the Vapour, Jornal of Crystal Growth, 1971, 9:340~345
58. Metushevsk ii A S. Kinetics of Magnesium Oxide Crystal Whisker Growth During the Reaction of Magnesium Oxide with Aluminum Tr, Mosk, Khim. Tekhnol. Inst, 1973, 72:105~107
59. Hayashi, Shinuke. Influnce of Starting Materials on the Chemical Reaction Process During the Vapor Growth of Magnesia. Yogyo KyokaiShi, 1974,82(4):229~233
60. Sandulov D B. Mechanical Properties of Magnesium Oxide Whiskers. Izv. Akad. Nauk. SSSR, Neorg, Mater, 1976, 12 (7): 1315~1317
61.夏赤丹,余汉年,周丽彬等.甲苯二异氰酸酯与水基乙烯醇胶粘剂交联反应的研究.化学与粘和,2001(5):197~199
62.田卫红.用环球法测试沥青软化点的探讨和建议.轻金属,2000(10):27~28
63.曾晓飞,陈建峰等.纳米CaCO_3-PVC复合材料微观结构和力学性能研究.北京化工大学学报,2001,28(4):1~3
64.李东明,漆宗能.非弹性体增韧—聚合物增韧的新途径.高分子通报,1989(3):32
2.袁建君,方琪,刘智恩.晶须材料的研究进展.材料科学与工程,1996,14(4):1
3.刘玲,殷宁,亢茂青.晶须增韧复合机理的研究.材料科学与工程,2000,18(2):116
4.北村孝雄.无机纤维开发的现状.机能纸研究会志,1985,24
5.孙新华.硼酸铝晶须的应用与制备.化工新型材料,1998,4:33
6.H.S.卡茨.塑料用填料及增强剂手册,化学工业出版社,1982,132-133
7.姚连增.晶体生长基础.北京:中国科学技术出版社,1994,20
8.孙新华.硼酸铝晶须的应用与制备.化工新型材料,1998,4:33
9.师昌绪.材料大辞典.北京:化学工业出版社,1994
10.邱孜学,贺学峰.工程塑料应用.2000(8):1~4
11. Honda Toshikazu, Sezume Tadashi, et al. JP94-136260
12. Ezure Noritomo, Isoi Masaaki, et al. JP95316360
13. Tong SC, Meng YZ.J Appl Polymer Sci. 1998, 70(3):431~439
14. Tsunmine Kunio, Suzuki Atsushi. JP99217504
15. Miura Masamori. JP93287200
16. Wang G. Jiang Z. Yu C, Ma R, Wu Z. Polymer Preprints, 1999, 40(1) :199~200
17.吕建通,赵宽放等.钛酸钾晶须增强PA6的研究.工程塑料应用,1995,23(6):5-8
18.钱世淮.玻璃钢.1999(3):8~14
19. Tiegs. Z. N. Hamis L. A, Bether. P.F. Am. Ceram. Soc. Bull, 1987, 66:549
20. MaiY. W. , Lawn B.R.J. Amer. Ceram. Soc. , 1987, 70:289
21. Masahiro Y. Hiroyuki S, Kengo O, et al. Mat. Sci, 1994, 29:3399
22.化学工业时报 1992年2月15日 第2123号
23.林莉译.碳化硅纤维的生产及市场.化工新型材料,1998;(9):29
24.董殿权,王军.碱式硫酸镁晶须的研制.功能材料,1999,30(5):559-560
25.顾里之.纤维增强复合材料.北京:机械工业出版社,1988
26.师昌绪.材料大辞典.北京:化学工业出版社,1994
27. Yuchun O. Feng Y. Jin C. Journal of Applied Polymer Science. 1997, 64(12): 2317~2322
28.曹有名.化工新型材料.1998(10):23~24,37
29.尚文宇,刘庆峰,陈寿田.工程塑料应用.1999(10):7~11
30.刘庆峰,王德生,尚文宇等.中国塑料,2000(3):5~9
31.尚文宇,谢大荣,刘庆峰.中国塑料.2000(3):24~26
32.廖明义,隗学礼.塑料科技.1999(6):41~43
33.孙勤良.热固性树脂.1998,(1):55~59
34. Tasaka Takio. Tawaguchi Akyoshi, et al. JP96-283494
35. Honda Toshikazu, Sezune Tadashi. JP96-11129
36. Inada Eiji. JP99-246758
37. Yamada Shinichi. Hamano Masaaki. JP87-190256
38. Tjong S C. Meng Y Z. Polymer, 1999,40(5):1109~1117
39. Jiang Wei,Tjong S C. Polym Degrad Stab, 1999, 66(2) :241~246
40. Tjong S C. Meng Y Z. Polymer, 1998,39(22):5461~5466
41. Tjong S C. Meng Y Z. J Appl Polym Sci, 1999, 72(4):501~508
42. Umeda Takashi. Nakazato Teruhiko. JP96-259789
43. Okuzono Toshiaki. JP95-258426
44.贺奉嘉,黄伯云.粉末冶金技术.1993,11(3):213~217
45.潘金生,陈永华.复合材料学报.1995,12(4):1~7
46. Tabuchi Akira. Nakamura Morihiko. et al. JP87-241966
47. Hisashi Hideyuki. JP99-53941
48. Kondo Takao. JP88193835
49.周祚万,彭卫明,邓海.化工新型材料.1998(11):13~15,26
50.张文,陈长勇,金增平等.青岛海洋学院学报,1998(4):361~364
51.孟季茹,赵磊,梁国正,贾巧英.化工新型材料.2001(29):1~6
52.隆言泉等.造纸原理与工程
53.制浆造纸试验技术.1998.12
54.李子东,李广宇,于敏.实用胶粘剂原材料手册.北京:国防工业出版社,1999:581
55.李慧青,张旖,孙萱,张淑芬.无机盐工业.2002 34(2):17~19
56.袁俊生,刘燕兰,大有发展前途的海洋无机盐晶须,海湖盐与化工,2000,3
57. Cockayne B, Filby J D. The Growth of Mgo Crystal from the Vapour, Jornal of Crystal Growth, 1971, 9:340~345
58. Metushevsk ii A S. Kinetics of Magnesium Oxide Crystal Whisker Growth During the Reaction of Magnesium Oxide with Aluminum Tr, Mosk, Khim. Tekhnol. Inst, 1973, 72:105~107
59. Hayashi, Shinuke. Influnce of Starting Materials on the Chemical Reaction Process During the Vapor Growth of Magnesia. Yogyo KyokaiShi, 1974,82(4):229~233
60. Sandulov D B. Mechanical Properties of Magnesium Oxide Whiskers. Izv. Akad. Nauk. SSSR, Neorg, Mater, 1976, 12 (7): 1315~1317
61.夏赤丹,余汉年,周丽彬等.甲苯二异氰酸酯与水基乙烯醇胶粘剂交联反应的研究.化学与粘和,2001(5):197~199
62.田卫红.用环球法测试沥青软化点的探讨和建议.轻金属,2000(10):27~28
63.曾晓飞,陈建峰等.纳米CaCO_3-PVC复合材料微观结构和力学性能研究.北京化工大学学报,2001,28(4):1~3
64.李东明,漆宗能.非弹性体增韧—聚合物增韧的新途径.高分子通报,1989(3):32