Hysteresis Heat Build-up and Low Temperature Processing of Polymer under the Vibration Force Field

Guang Sheng Zeng; Chao Xu; Yue Jun Liu; Jin Ping Qu

doi:10.4028/www.scientific.net/AMR.415-417.200

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Crude Oil Adsorption on Fe₂O₃/EPDM Composite to the outside Environmental Variations
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Metal Ions Doped Complex Cobalt Blue Pigment Research
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Hysteresis Heat Build-up and Low Temperature Processing of Polymer under the Vibration Force Field
p.200

TiCl₄ Treatment to the Substrate of Dye-Sensitized Solar Cell for the Applications on BIPV
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Microstructure Analysis of in-Plane Quasi-Isotropic Composites Reinforced by Multi-Direction and Multi-Layer Three Dimensional Fabric
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Study on Optimal Design of Light-Weight Composite Hood
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Influence of Laser Power on the Microstructure and Anti-Corrosion Performance of LHPS NiCrAlY Coatings
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Hysteresis Heat Build-up and Low Temperature Processing of Polymer under the Vibration Force Field

Abstract:

By using dynamic capillary and multi-dimensional vibration experiment desktop, isotactic polypropylene ( iPP ) is selected for the objective material to investigate the effect of the vibration parameters on the viscoelastic properties of polymer and its molding process. And a series conclusions can be draw that: The phase angle of polymer tends to decrease after a increase with vibration frequency increasing. The phase angle reach maximum value of 90° when the vibration frequency equals to the material natural frequency. Which polymer experience as pure viscous materials, also hysteresis heat build-up rate goes up to the peak. The plasticizing rate of polymer increase as the vibration amplitude, but the higher requirement for the equipment leveled up as well. The polymer plasticizing rate display the same law with that of phase angle against vibration frequency. When the vibration frequency equals to the material natural frequency, the plasticizing rate reach maximum. The investigation of this study will offers valuable theoretical references for polymer processing and novel equipment design in low-temperature.