UHMWPE/PP的共混改性研究
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摘要
通过机械共混的方法加工成型了UHMWPE/PP合金。通过比较开炼挤出注射成型和挤出注射成型两种工艺对体系力学性能所产生效果的优劣,选择开炼挤出注射成型工艺进行了全部的实验。在体系中加入自行配制地解缠剂Jc-3,研究了UHMWPE、PP和解缠剂的含量对体系力学性能、流动性能和热学性能的影响。通过DSC、SEM、偏光显微镜等分析手段,对PP/UHMWPE合金的结晶性能、合金冲击断面形状及相结构和微观相畴的分布进行了微观分析。
实验结果表明:随着UHMWPE含量的增加,体系的冲击强度、拉伸强度均有显著地提高,但是,却降低了共混体系的加工性能和热力学性能。解缠剂的加入对UHMWPE的缠结分子链产生了一定的解缠作用。DSC分析说明,体系具有两个独立的熔融吸热峰,分别是PP和UHMWPE组分的贡献,表明体系为两相结构;随着UHMWPE含量的增加,PP的结晶度明显降低,UHMWPE的结晶度则呈现显著地上升趋势,但是由于UHMWPE熔体的粘度极高,UHMWPE的晶体完善程度没有PP的晶体完善程度好。扫描电镜测试表明,UHMWPE和PP共混时,既没有达到分子水平的分散,也不是象刚性粒子或弹性粒子增韧那样,呈颗粒状分布在基体中,而是和PP形成了物理交联网络结构。偏光显微镜测试从微观的角度证明了DSC的测试结果。
UHMWPE/PP alloy is molded by mechanical blending process. Mixing-extruding-injecting molding process is chosen to do all experiments by analyzing two different processes, mixing-extruding-injecting molding process and extruding-injecting molding process, influencing on experimental results. Disentanglement agent compounded by ourselves is used, the content of UHMWPE > PP and disentanglement agent influencing on mechanical properties, rheological properties and thermal properties are researched. With Differential Scanning Calorimertric analysis (DSC) , Scanning electron microscopy (SEM) and polarizing microscope et al testing methods, properties of alloys are studied, such as crystallizing properties, impact section appearance of alloy, phase structure and distribution of microstructure.
With the content of UHMWPE increasing, the Izod impact strength and tensile strength are improved greatly, but at the cost of rheological properties and thermal properties. The adding of disentanglement agent has effects on disentangling of UHMWPE. DSC testing shows: the system has two independent absorption of heat apexes are the contribution of UHMWPE and PP phase, which declare it is two-phase structure. With the content of UHMWPE increasing, the crystallinity of PP decreases greatly and the crystallinity of UHMWPE improves. But because of poor flowability of UHMWPE, the perfection degree of UHMWPE crystallizing is lower than that of PP; The system is two-phase structure. SEM testing shows: UHMWPE with PP forms
" physical cross-linked network", but doesn't scatter molecularly. Polarizing microscope testifies the results of DSC testing from micromolecular aspect.
实验结果表明:随着UHMWPE含量的增加,体系的冲击强度、拉伸强度均有显著地提高,但是,却降低了共混体系的加工性能和热力学性能。解缠剂的加入对UHMWPE的缠结分子链产生了一定的解缠作用。DSC分析说明,体系具有两个独立的熔融吸热峰,分别是PP和UHMWPE组分的贡献,表明体系为两相结构;随着UHMWPE含量的增加,PP的结晶度明显降低,UHMWPE的结晶度则呈现显著地上升趋势,但是由于UHMWPE熔体的粘度极高,UHMWPE的晶体完善程度没有PP的晶体完善程度好。扫描电镜测试表明,UHMWPE和PP共混时,既没有达到分子水平的分散,也不是象刚性粒子或弹性粒子增韧那样,呈颗粒状分布在基体中,而是和PP形成了物理交联网络结构。偏光显微镜测试从微观的角度证明了DSC的测试结果。
UHMWPE/PP alloy is molded by mechanical blending process. Mixing-extruding-injecting molding process is chosen to do all experiments by analyzing two different processes, mixing-extruding-injecting molding process and extruding-injecting molding process, influencing on experimental results. Disentanglement agent compounded by ourselves is used, the content of UHMWPE > PP and disentanglement agent influencing on mechanical properties, rheological properties and thermal properties are researched. With Differential Scanning Calorimertric analysis (DSC) , Scanning electron microscopy (SEM) and polarizing microscope et al testing methods, properties of alloys are studied, such as crystallizing properties, impact section appearance of alloy, phase structure and distribution of microstructure.
With the content of UHMWPE increasing, the Izod impact strength and tensile strength are improved greatly, but at the cost of rheological properties and thermal properties. The adding of disentanglement agent has effects on disentangling of UHMWPE. DSC testing shows: the system has two independent absorption of heat apexes are the contribution of UHMWPE and PP phase, which declare it is two-phase structure. With the content of UHMWPE increasing, the crystallinity of PP decreases greatly and the crystallinity of UHMWPE improves. But because of poor flowability of UHMWPE, the perfection degree of UHMWPE crystallizing is lower than that of PP; The system is two-phase structure. SEM testing shows: UHMWPE with PP forms
" physical cross-linked network", but doesn't scatter molecularly. Polarizing microscope testifies the results of DSC testing from micromolecular aspect.
引文
[1] 江明,高分子合金的物理化学.四川:四川教育出版社,1988
[2] 罗河胜.实用聚苯乙烯.广东:广东科学技术出版社,1991
[3] N .A. Platzer. Multicomponent Polymer System, Acs NO. 941, 1971
[4] 吴培熙,张留成,编著.聚合物共混改性.北京:轻工业出版社,1996
[5] 何继敏,薛平,何亚东.超高分子量聚乙烯管材的应用与市场前景.塑料科技,1998,(10)
[6] 刘广建,陈和香.超高分子量聚乙烯在矿山机械中的应用.工程塑料应用,1998,12(4)
[7] 王庆昭.UHMWPE制品的受热形变和热变形加工.工程塑料应用,1999,13(6)
[8] 刘广建.改性超高分子量聚乙烯滤板的研制.塑料,1996,25(3)
[9] 刘广建.超高分子量聚乙烯.北京:化学工业出版社,2001
[10] 李志良,穆成哲.超高分子量聚乙烯的压制、挤出及注射工艺成型.塑料科技,1984,(2):51
[11] 刘广建.大型超高分子量聚乙烯制品烧结时的模具设计.现代塑料加工应用,1998,(4):45
[12] 薛启柏,薛平,何亚东,等.超高分子量聚乙烯复合材料的发展.工程塑料应用,2000,28(3):36
[13] 薛平,何继敏,何亚东,等.超高分子量聚乙烯挤出管材成型设备与技术.中国塑料,2000,14(1):81
[14] 何继敏,薛平,何亚东,等,超高分子量聚乙烯管材的单螺杆挤出及应用.塑料,1998,27(1)
[15] 王庆昭,廖先玲.超高分子量聚乙烯双螺杆挤出的研究.塑料工业,1997,(2):89
[16] 张禹飞,等,加工UHMWPE的柱塞式挤出机.工程塑料应用,1997,(3)
[17] 刘玉凤,庆苏,朱放,等.超高分子量聚乙烯的高压、高速注射工艺研究.塑料,1991,20(5)
[18] 刘玉凤,等.超高分子量聚乙烯的注射成型.塑料,1986,15(4):3
[19] S. A. R, Hashrni. Sliding wear of PP/UHMWPE blends: Effect of blend
composition. Wear, 2001, 247(1). 9
[20] 杨军,王可信,王进,等.超高分子量聚乙烯改性聚丙稀.塑料,1997,26(1):27
[21] 杨军,李炳海,王可信,等。UHMWPE改性PP的结晶行为和亚微观形态研究.塑料,1998,27(4):32
[22] 周先意,洪昆仑,朱清仁,等.超高分子量聚乙烯和聚丙稀共混体系自由体积的研究.化学物理学报,1996,9(6)
[23] 励杭泉,汪晓东,金日光.PP/UHMWPE共混合金的制备与力学性能.中国塑料,1993,7(2):8
[24] 陈寿羲,宋文辉,王强,等,聚丙稀与超高分子量聚乙烯共混行为的研究.合成纤维,1990,(1)
[25] 刘萍,王德禧.超高分子量聚乙烯的改性及其应用.工程塑料应用,2001,29(5):7
[26] USP4 281 700
[27] 刘廷华,陈利明,徐鸣.UHMWPE/HDPE共混体系同向双螺杆挤出成型.中国塑料,2001,15(4):39
[28] 刘廷华,徐鸣,陈利明.MMWPE与UHMWPE共混体系的力学性能研究.工程塑料应用2001,29(9)
[29] 赵安赤,等.超高分子量聚乙烯加工的高新技术.塑料科技,1997,(6):13
[30] 赵安赤.液晶聚合物及原位复合技术在塑料改性中的应用.中国塑料,1993,7(4):1
[31] 赵安赤.LCP/UHMWPE原位复合物的制备、性能和应用.工程塑料应用,1999,27(2):6
[32] 胡平,吕荣侠,展格.超高分子量聚乙烯填料改性的研究.塑料,1990,19(4):11
[33] 王心蕊,胡平,成诞人.超高分子量聚乙烯阻燃抗静电改性.工程塑料应用,2001,9(4):4
[34] 胡平,等.碳纳米管/UHMWPE复合材料的研究.工程塑料应用,1998,26(1):1~3
[35] Wunderlich B. Crystal nucleation growth, annealing. In. Macromolecular
Physics. Vol. 2. New York: Academic Press, 1976:115~271
[36] Flory P J, Yoon D Y. Nature, 1978, 272:226~229
[37] 陈民,顾方明,卜海山.链缠结对高聚物热变形行为的影响.高分子学报,1999,(3):332~337
[38] Smith P, Leemstra P, J Mater Sci, 1980, 15: 505
[39] OgitaT, Yamamoto R, Suzuki F, Matsuo M., Polymer, 1991, 32:822
[40] Fisher L, Haschbager R, Ziegerldor A, Rulawd W. Colloid Polym Sci, 1982, 260: 174
[41] K. Nakayama, A. Furumiya, T. Okamoto, etc. Structure and mechanical properties of ultra high molecular weight polyethylene deformed near melting temperature. Pure & ApplChem, 1991, Vol. 63, No. 12, 1793~1804
[42] 陈寿羲,金永泽.超高分子量聚乙烯的结晶形态.高分子材料与工程,1993,(2):81~85
[43] 赵勇,杨德才.聚乙烯串晶在单轴拉伸形变过程中的微结构变化和机理.高分子学报,1994,(6):647~651
[44] 许健南.塑料材料.北京:中国轻工业出版社,1999
[45] P Gao, M. Mackley. The structure and theology of molten ultra-high-molecular-mass polyethylene. Polymer, 1994, Vol. 35, No. 24, 5210~5216
[46] Tetsuya Ogita. Morphology and mechanical properties of ultra high molecular weight polyethylene prepared by elation/crystallization at various temperatures. Polymer, 1992, Vol. 33, No. 4, 698~702
[47] Won Ho Jo. Sol-gel transition and crystallization kinetics of ultra high molecular weight polyethylene & decalin solution. Polymer Eng. And Sci, 1989, Vol. 29, No. 22, 1569~1573
[48] 赵勇,杨德才.聚乙烯串晶在单轴拉伸形变过程中的微结构变化和机理.高分子学报,1994(6):647~651
[49] Tetsuya Ogita, YoshihisaKawahara, et al. Polymer Journal, 1991, Vol. 23, No. 7, 871~884
[50] 朱清仁,洪昆仑,季力强等.超高分子量PE凝胶膜的超拉伸性与旁式构象关系研究.高分子学报,1995(6):658~663
[2] 罗河胜.实用聚苯乙烯.广东:广东科学技术出版社,1991
[3] N .A. Platzer. Multicomponent Polymer System, Acs NO. 941, 1971
[4] 吴培熙,张留成,编著.聚合物共混改性.北京:轻工业出版社,1996
[5] 何继敏,薛平,何亚东.超高分子量聚乙烯管材的应用与市场前景.塑料科技,1998,(10)
[6] 刘广建,陈和香.超高分子量聚乙烯在矿山机械中的应用.工程塑料应用,1998,12(4)
[7] 王庆昭.UHMWPE制品的受热形变和热变形加工.工程塑料应用,1999,13(6)
[8] 刘广建.改性超高分子量聚乙烯滤板的研制.塑料,1996,25(3)
[9] 刘广建.超高分子量聚乙烯.北京:化学工业出版社,2001
[10] 李志良,穆成哲.超高分子量聚乙烯的压制、挤出及注射工艺成型.塑料科技,1984,(2):51
[11] 刘广建.大型超高分子量聚乙烯制品烧结时的模具设计.现代塑料加工应用,1998,(4):45
[12] 薛启柏,薛平,何亚东,等.超高分子量聚乙烯复合材料的发展.工程塑料应用,2000,28(3):36
[13] 薛平,何继敏,何亚东,等.超高分子量聚乙烯挤出管材成型设备与技术.中国塑料,2000,14(1):81
[14] 何继敏,薛平,何亚东,等,超高分子量聚乙烯管材的单螺杆挤出及应用.塑料,1998,27(1)
[15] 王庆昭,廖先玲.超高分子量聚乙烯双螺杆挤出的研究.塑料工业,1997,(2):89
[16] 张禹飞,等,加工UHMWPE的柱塞式挤出机.工程塑料应用,1997,(3)
[17] 刘玉凤,庆苏,朱放,等.超高分子量聚乙烯的高压、高速注射工艺研究.塑料,1991,20(5)
[18] 刘玉凤,等.超高分子量聚乙烯的注射成型.塑料,1986,15(4):3
[19] S. A. R, Hashrni. Sliding wear of PP/UHMWPE blends: Effect of blend
composition. Wear, 2001, 247(1). 9
[20] 杨军,王可信,王进,等.超高分子量聚乙烯改性聚丙稀.塑料,1997,26(1):27
[21] 杨军,李炳海,王可信,等。UHMWPE改性PP的结晶行为和亚微观形态研究.塑料,1998,27(4):32
[22] 周先意,洪昆仑,朱清仁,等.超高分子量聚乙烯和聚丙稀共混体系自由体积的研究.化学物理学报,1996,9(6)
[23] 励杭泉,汪晓东,金日光.PP/UHMWPE共混合金的制备与力学性能.中国塑料,1993,7(2):8
[24] 陈寿羲,宋文辉,王强,等,聚丙稀与超高分子量聚乙烯共混行为的研究.合成纤维,1990,(1)
[25] 刘萍,王德禧.超高分子量聚乙烯的改性及其应用.工程塑料应用,2001,29(5):7
[26] USP4 281 700
[27] 刘廷华,陈利明,徐鸣.UHMWPE/HDPE共混体系同向双螺杆挤出成型.中国塑料,2001,15(4):39
[28] 刘廷华,徐鸣,陈利明.MMWPE与UHMWPE共混体系的力学性能研究.工程塑料应用2001,29(9)
[29] 赵安赤,等.超高分子量聚乙烯加工的高新技术.塑料科技,1997,(6):13
[30] 赵安赤.液晶聚合物及原位复合技术在塑料改性中的应用.中国塑料,1993,7(4):1
[31] 赵安赤.LCP/UHMWPE原位复合物的制备、性能和应用.工程塑料应用,1999,27(2):6
[32] 胡平,吕荣侠,展格.超高分子量聚乙烯填料改性的研究.塑料,1990,19(4):11
[33] 王心蕊,胡平,成诞人.超高分子量聚乙烯阻燃抗静电改性.工程塑料应用,2001,9(4):4
[34] 胡平,等.碳纳米管/UHMWPE复合材料的研究.工程塑料应用,1998,26(1):1~3
[35] Wunderlich B. Crystal nucleation growth, annealing. In. Macromolecular
Physics. Vol. 2. New York: Academic Press, 1976:115~271
[36] Flory P J, Yoon D Y. Nature, 1978, 272:226~229
[37] 陈民,顾方明,卜海山.链缠结对高聚物热变形行为的影响.高分子学报,1999,(3):332~337
[38] Smith P, Leemstra P, J Mater Sci, 1980, 15: 505
[39] OgitaT, Yamamoto R, Suzuki F, Matsuo M., Polymer, 1991, 32:822
[40] Fisher L, Haschbager R, Ziegerldor A, Rulawd W. Colloid Polym Sci, 1982, 260: 174
[41] K. Nakayama, A. Furumiya, T. Okamoto, etc. Structure and mechanical properties of ultra high molecular weight polyethylene deformed near melting temperature. Pure & ApplChem, 1991, Vol. 63, No. 12, 1793~1804
[42] 陈寿羲,金永泽.超高分子量聚乙烯的结晶形态.高分子材料与工程,1993,(2):81~85
[43] 赵勇,杨德才.聚乙烯串晶在单轴拉伸形变过程中的微结构变化和机理.高分子学报,1994,(6):647~651
[44] 许健南.塑料材料.北京:中国轻工业出版社,1999
[45] P Gao, M. Mackley. The structure and theology of molten ultra-high-molecular-mass polyethylene. Polymer, 1994, Vol. 35, No. 24, 5210~5216
[46] Tetsuya Ogita. Morphology and mechanical properties of ultra high molecular weight polyethylene prepared by elation/crystallization at various temperatures. Polymer, 1992, Vol. 33, No. 4, 698~702
[47] Won Ho Jo. Sol-gel transition and crystallization kinetics of ultra high molecular weight polyethylene & decalin solution. Polymer Eng. And Sci, 1989, Vol. 29, No. 22, 1569~1573
[48] 赵勇,杨德才.聚乙烯串晶在单轴拉伸形变过程中的微结构变化和机理.高分子学报,1994(6):647~651
[49] Tetsuya Ogita, YoshihisaKawahara, et al. Polymer Journal, 1991, Vol. 23, No. 7, 871~884
[50] 朱清仁,洪昆仑,季力强等.超高分子量PE凝胶膜的超拉伸性与旁式构象关系研究.高分子学报,1995(6):658~663