Time‐dependent properties of high‐density polyethylene with wood/graphene nanoplatelets reinforcement

Abstract

AbstractThe effect of graphene nanoplatelets (GNPs) on the long‐term performance of wood fiber/high‐density polyethylene (HDPE) composite is investigated by using short‐term creep tests with an efficient, faster data analysis approach. Previously, it was shown that the addition of GNPs at 15 wt% into HDPE reduces the viscoplastic (VP) strain developed during 2 h creep by ~50%. The current study shows that 25 and 40 wt% wood content in HDPE reduce the VP strains developed during 2 h creep time by >75% with no noticeable effect of the increased wood content. However, further addition of GNPs results in more than 90% total reduction in the VP strains. The current study shows that the development of the VP strains in the hybrid composites follows Zapas model. Viscoelastic (VE) response of these composites is nonlinear and thus is described by Schapery's model. Parameters for VP and VE models are obtained from the creep experiments and were validated in a separate loading‐unloading test sequence. Results show a very good agreement between experiments and predictions for the studied materials as long as the micro‐damage is not present.