双转子连续混炼挤出机转子结构对聚丙烯/多壁碳纳米管复合材料性能的影响
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摘要
双转子连续混炼挤出机转子结构对制备的复合材料性能有较大影响。文中运用2种不同结构的转子,通过母粒熔融共混方法制备了聚丙烯/多壁碳纳米管导电复合材料,并对其微观结构、流变学、导电性、力学性能进行了测试,研究了转子结构对复合材料性能的影响。结果表明,低转速下混沌转子的分散和分布混合能力均高于经典转子;采用混沌转子制备的复合材料性能更优;其导电渗流阈值低至0. 4%,体积电阻率低至105Ω·cm量级,拉伸强度达到26. 52 MPa,弯曲模量达到1544. 85 MPa,冲击韧性达到23. 98 k J/m2,断裂伸长率在16. 14%以上。
The rotor structure of two-rotor continuous mixing extruder has a great influence on properties of the prepared composites. In this paper,PP/multiwall carbon nanotube conductive composites were prepared by masterbatch melt blending method. Its microstructure,rheology,conductivity,mechanical properties,and further effect of rotor structure on the properties of composites were studied. The research results indicate that the chaotic rotors at low rotational speed have better dispersive and distributed mixing ability than the classic rotors; the properties of composites prepared by the chaotic rotors are better than by the classic rotors. The conductive threshold of composites prepared by the chaotic rotors is as low as 0. 4%; its resistivity is reduced to the magnitude of 105Ω·cm; its tensile strength reaches26. 52 MPa; its impact toughness also reaches 23. 98 k J/m2; its elongation at break is above 16. 14%.
The rotor structure of two-rotor continuous mixing extruder has a great influence on properties of the prepared composites. In this paper,PP/multiwall carbon nanotube conductive composites were prepared by masterbatch melt blending method. Its microstructure,rheology,conductivity,mechanical properties,and further effect of rotor structure on the properties of composites were studied. The research results indicate that the chaotic rotors at low rotational speed have better dispersive and distributed mixing ability than the classic rotors; the properties of composites prepared by the chaotic rotors are better than by the classic rotors. The conductive threshold of composites prepared by the chaotic rotors is as low as 0. 4%; its resistivity is reduced to the magnitude of 105Ω·cm; its tensile strength reaches26. 52 MPa; its impact toughness also reaches 23. 98 k J/m2; its elongation at break is above 16. 14%.
引文
[1]Jafariesfad N,Ramazani S A A,Azinfar B.Property investigation of polypropylene/multiwall carbon nanotube nanocomposites prepared via in situ polymerization[J].Polym.Int.,2014,62:689-694.
[2]Zhong J,Isayev A I,Huang K,et al.Influence of ultrasonic treatment in PP/CNT composites using masterbatch dilution method[J].Polymer,2014,55:1745-1755.
[3]Park S B,Lee M S,Park M.Study on lowering the percolation threshold of carbon nanotube-filled conductive polypropylene composites[J].Carbon Lett.,2014,15:117-124.
[4]Besco S,Lorenzetti A,Hrelja D.Influence of melt viscosity on the structure and properties of electrically conductive nanocomposittes produced by masterbatch process[J].Macromol.Mater.Eng.,2014,299:814-824.
[5]Sha J,Li G,Chen X,et al.Simultaneous ultrasonication-assisted internal mixing to prepare MWNTs-filled epoxy composites with increased strength and thermal conductivity[J].Polym.Compos.,2016,37:870-880.
[6]Wegrzyn M,Galindo B,Benedito A.Morphology,thermal,and electrical properties of polypropylene hybrid composites co-filled with multi-walled carbon nanotubes and graphene nanoplatelets[J].J.Appl.Polym.Sci.,2015,132:DOI:10.1002/app.42793.
[7]张霞,谢林生,马玉录.双转子连续混炼机混炼段拉伸作用的研究[J].中国塑料,2010,24(3):108-113.Zhang X,Xie L S,Ma Y L.Study on stretching effect in mixing section of two-rotor continuous mixers[J].China Plastics,2010,24(3):108-113.
[8]Xie L,Li P,Ma Y,et al.A representation method for describing a deagglomerating process in continuous mixer[J].Polym.Compos.,2012,33:476-483.
[9]谢林生,马玉录.双转子连续混炼机中的混沌混合行为研究[J].中国塑料,2009,23(4):104-108.Xie L S,Ma Y L.Study on mixing performance of chaotic rotors in two-rotor continuous mixers[J].China Plastics,2009,23(4):104-108.
[10]Pan Y Z,Li L.Percolation and gel-like behavior of multiwalled carbon nanotube/polypropylene composites influenced by nanotube aspect ratio[J].Polymer,2013,54:1218-1226.
[2]Zhong J,Isayev A I,Huang K,et al.Influence of ultrasonic treatment in PP/CNT composites using masterbatch dilution method[J].Polymer,2014,55:1745-1755.
[3]Park S B,Lee M S,Park M.Study on lowering the percolation threshold of carbon nanotube-filled conductive polypropylene composites[J].Carbon Lett.,2014,15:117-124.
[4]Besco S,Lorenzetti A,Hrelja D.Influence of melt viscosity on the structure and properties of electrically conductive nanocomposittes produced by masterbatch process[J].Macromol.Mater.Eng.,2014,299:814-824.
[5]Sha J,Li G,Chen X,et al.Simultaneous ultrasonication-assisted internal mixing to prepare MWNTs-filled epoxy composites with increased strength and thermal conductivity[J].Polym.Compos.,2016,37:870-880.
[6]Wegrzyn M,Galindo B,Benedito A.Morphology,thermal,and electrical properties of polypropylene hybrid composites co-filled with multi-walled carbon nanotubes and graphene nanoplatelets[J].J.Appl.Polym.Sci.,2015,132:DOI:10.1002/app.42793.
[7]张霞,谢林生,马玉录.双转子连续混炼机混炼段拉伸作用的研究[J].中国塑料,2010,24(3):108-113.Zhang X,Xie L S,Ma Y L.Study on stretching effect in mixing section of two-rotor continuous mixers[J].China Plastics,2010,24(3):108-113.
[8]Xie L,Li P,Ma Y,et al.A representation method for describing a deagglomerating process in continuous mixer[J].Polym.Compos.,2012,33:476-483.
[9]谢林生,马玉录.双转子连续混炼机中的混沌混合行为研究[J].中国塑料,2009,23(4):104-108.Xie L S,Ma Y L.Study on mixing performance of chaotic rotors in two-rotor continuous mixers[J].China Plastics,2009,23(4):104-108.
[10]Pan Y Z,Li L.Percolation and gel-like behavior of multiwalled carbon nanotube/polypropylene composites influenced by nanotube aspect ratio[J].Polymer,2013,54:1218-1226.
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