Improved mechanical properties and structure of PP/nano‐CaCO3 blends prepared by low‐frequency vibration injection molding

AbstractBACKGROUD: Melt vibration technology was used to prepare injection samples of polypropylene (PP)/nano‐CaCO3 blends. It is well known that nano‐CaCO3 particles are easy to agglomerate owing to their large surface energy. Improving the distribution of nano‐CaCO3 particles in PP/nano‐CaCO3 blends is very important for enhancing the mechanical properties. In this work, low‐frequency vibration was imposed on the process of injection molding of PP/nano‐CaCO3 blends. The aim of importing a vibration field was to change the crystal structure of PP as we studied previously and improve the distribution of nano‐CaCO3 particles. Furthermore, the mechanical properties were improved.RESULTS: Through melt vibration, the mechanical properties of PP/nano‐CaCO3 samples were improved significantly. Compared with conventional injection molding, the enhancement of the tensile strength and impact strength of the samples molded by vibration injection molding was 17.68 and 175.96%, respectively. According to scanning electron microscopy, wide‐angle X‐ray diffraction and differential scanning calorimetry measurements, it was found that a much better dispersion of nano‐CaCO3 in samples was achieved by vibration injection molding. Moreover, the crystal structure of PP in PP/CaCO3 vibration samples changed. The γ crystal form was achieved at the shear layer of vibration samples. Moreover, the degree of crystallinity of PP in vibration samples increased 6% compared with conventional samples.CONCLUSION: Concerning the microstructure, melt vibration could effectively change the crystal structure and increase the degree of crystallinity of PP besides improving the distribution of nano‐CaCO3 particles. Concerning the macrostructure, melt vibration could enhance the mechanical properties. The improvement of mechanical properties of PP/nano‐CaCO3 blends prepared by low‐frequency vibration injection molding should be attributed to the even distribution of nano‐CaCO3 particles and the formation of γ‐PP and the increase of the degree of cystallinity. Copyright © 2007 Society of Chemical Industry