Microstructure Effect of Injection Molded Nanoparticle/Polymer Composites on their Resistivity

Bao Feng Zhang; Ai Yun Jiang; De Bo Liu; Hai Hong Wu; Jing Chao Zou

doi:10.4028/www.scientific.net/AMR.472-475.1059

Paper Titles

Design of Missile Autopilot with Aerodynamic Lift and Reaction Jets Based on Auto Disturbance Rejection Controller
p.1036

New Technology and Applications on Passive Millimeter-Wave Sensors
p.1040

Adaptive Repetitive Control of Nonlinearly Parameterized Systems Based on Fuzzy Basis Function Networks
p.1045

Experimental Investigation on Cutting Forces and Temperature in High Speed Turning of Ti-5Al-2Sn-2Zr-4Mo-4Cr (Ti-17) Alloys
p.1054

Microstructure Effect of Injection Molded Nanoparticle/Polymer Composites on their Resistivity
p.1059

Fabrication and Performance of Symmetrical Gradient Ceramic Nozzles
p.1063

Effect of Machining Parameters on Nano-Cutting of SiC Ceramics
p.1069

Research on the Method to Decompose Propagation Sound Wave in Annular Duct
p.1074

The Optimization of Precision Milling Parameters for Titanium Based on Genetic Algorithm
p.1078

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 472-475Microstructure Effect of Injection Molded...

Microstructure Effect of Injection Molded Nanoparticle/Polymer Composites on their Resistivity

Abstract:

Although the progress has been achieved in conductive Nanoparticle/Polymer Composites(NPC), but there are many problems to be solved before their commercial application in a large scale, especially on their processing technology. The barriers include the dispersion of nanoparticle, the effect of nanoparticle concentration and interface on the overall properties of materials. In order to improve the application of NPC, the microstructural effect of injection molded NPC on its resistivity was investigated to build the relationship between the processing conditions and the properties in this paper. Composites used in the experiment were carbon black(CB)/polypropylene(PP). The microstructures of the injection molded parts at different positions were investigated with Scanning Electrical Microscope, and corresponsive properties were tested. The results showed that the distribution of CB nanoparticles changed with the injection pressure and had significant effect on the conductivity of the part. With the increase of injection pressure CB particles strongly oriented towards the flow direction of the polymer and thickness of oriented layer increased, which improve conductivity of the composites. The results also showed that crystallization was enhanced because of existence of nanoparticles, which should have increased the mechanical properties of the composite and decreased its resistivity because of the interfacial action between CB particles and polymer matrix.