Study of the morphology and temperature-resistivity effect of injection-molded iPP/HDPE/CB composites

被引：0

作者：

Li-Rong Tan

Chao-Lu Yin

Shi-Lin Huang

Zheng-Ying Liu

Ming-Bo Yang

Jian-Min Feng

机构：

[1] Sichuan University,State Key Laboratory of Polymer Materials Engineering, College of Polymer Science and Engineering

来源：

Polymer Bulletin | 2014年 / 71卷

关键词：

iPP/HDPE/CB composites; Morphology; Temperature-resistivity effect; Injection molding; Component ratio;

D O I：

暂无

中图分类号：

学科分类号：

摘要：

The relationship between morphology and temperature-resistivity effect of injection-molded isotactic polypropylene/high density polyethylene/carbon black (iPP/HDPE/CB) composites with special orientation structure is investigated in detail. The morphological variation induced by melting, disorientation, crystallization and movement of CB particles is responsible for the change of electrical conductivity of the iPP/HDPE/CB composites during the heating and cooling. The room temperature volume resistivity of the composites reduces markedly after a round of heating and cooling because the network is improved through morphological changes and movement of particles during annealing. The continuity of HDPE/CB phase and the effective concentration of the CB particles in HDPE simultaneously determine the temperature-resistivity effects of the composites. Samples with iPP/HDPE mass ratio of 50/50 achieve a better balance of the two factors, which results in more stable conductive properties varying with temperature.

引用

页码：1711 / 1725

页数：14

共 53 条

[1]

Zhang W(2007)Carbon based conductive polymer composites J Mater Sci 42 3408-3418

[2]

Dehghani-Sanij AA(2004)Effect of some service conditions on the electrical resistivity of conductive styrene–butadiene rubber–carbon black composites J Appl Polym Sci 92 2179-2188

[3]

Blackburn RS(2007)Electrically conductive carbon black (CB) filled in situ microfibrillar poly (ethylene terephthalate) (PET)/polyethylene (PE) composite with a selective CB distribution Polymer 48 849-859

[4]

Mohanraj G(2005)Positive temperature coefficient effect in multiwalled carbon nanotube/high-density polyethylene composites Appl Phys Lett 86 062112-062113

[5]

Dai K(2009)Positive temperature coefficient characteristic and structure of graphite nanofibers reinforced high density polyethylene/carbon black nanocomposites Compos B Eng 40 218-224

[6]

Xu X-B(2007)Piezoresistive behavior study on finger-sensing silicone rubber/graphite nanosheet nanocomposites Adv Funct Mater 17 898-904

[7]

Li Z-M(2009)Electrical conductivity and self-temperature-control heating properties of carbon nanotubes filled polyethylene films Polymer 50 1046-1053

[8]

He X(2007)Effect of morphology on the electric conductivity of binary polymer blends filled with carbon black J Appl Polym Sci 106 2008-2017

[9]

Li Q(2009)Origin of remarkable positive temperature coefficient effect in the modified carbon black and carbon fiber cofilled polymer composites J Appl Phys 106 024913-024915

[10]

Chen L(2009)Electromagnetic interference shielding mechanisms of CNT/polymer composites Carbon 47 1738-1746

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