The influence of entanglement degree controlled by complex shear field on the performance of long-chain branched polypropylene

The entanglement of polymers can cause a sharp increase in the viscosity of polymer melt, which is adverse to polymer processing. Disentanglement is an effective method to improve the processing performance of polymers without sacrificing mechanical properties. Although there are some methods to reduce the entanglement degree of polymers, few methods can preserve the disentangled state in pellets for secondary processing. Long-chain branched polypropylene (LCB-PP) has a slower entanglement recovery rate due to its branched chain. Thus, it is worth studying whether the disentangled state of LCB-PP can be kept in pellets to improve processing performance during secondary processing. In this work, disentangled LCB-PP was successfully prepared using the self-designed polymer melt disentanglement device that can apply a complex shear field (a superposition of rotational shear and oscillatory shear) to polymers. The effect of the rotational shear, oscillatory shear, and complex shear on disentanglement was studied. The results show that the complex shear field has a better effect on the disentanglement of LCB-PP, which is endowed with lower viscosity and higher melt flow rate compared to rotational shear and oscillatory shear. In secondary processing, the processing temperature and injection pressure required for disentangled LCB-PP are significantly reduced while mechanical properties are maintained.

Graphical abstract