Waste flame-retardant polyurethane foam/ground tire rubber/carbon nanotubes composites with hierarchical segregated structures for high efficiency electromagnetic interference shielding

Abstract

Recently, flexible conductive polymer composites (CPCs) have attracted increasing interests for their promise in electromagnetic interference (EMI) shielding. Inspired by the “steel reinforced concrete” structure, we proposed in this study a novel method to prepare a CPC with high EMI shielding performance from waste flame-retardant polyurethane foam (WFPUF) and ground tire rubber (GTR). In this CPC, WFPUF coated with carbon nanotubes (CNT) and cellulose nanofibers (CNF) served as a strong and conductive skeleton like the “steel” in “steel reinforced concrete”. Meanwhile, the GTR and CNT composite with a segregated structure occupied the pore space of WFPUF/CNT/CNF (WCC) to form the WCC/GTR/CNT composite, similar to the “concrete” in “steel reinforced concrete”. Owing to such a hierarchical structure, the resultant WCC/GTR/CNT demonstrated some coveted properties, including the enhanced mechanical properties, high electrical conductivity (84.0 S·m−1), excellent EMI shielding performance (53.8 dB), and long-term durability. Remarkably, the composite also showed great flame retardancy due to the presence of WFPUF. This work provided a promising strategy for the preparation of eco-friendly, low cost, flexible and efficient CPCs from polymer wastes, which showed high potential in EMI shielding.