Non-bituminous binders formulated with bio-based and recycled materials for energy-efficient roofing applications

Non-bituminous binders have been designed as potential roofing materials with sustainable characteristics. To that end, three bio-based rosin esters (R), a waste cooking oil (O) and a recycled polyethylene from greenhouse agriculture (LDPEr) have been used in their formulations. A comprehensive rheological, microstructural, calorimetric, and technological characterization have been performed on binary (polymer/oil or rosin/oil) and ternary (polymer/rosin/oil) blends, allowing the compatibility among binder compounds to be studied. Additionally, thermal conductivity and solar radiation tests have been conducted on a selected non-bituminous binder and compared with a reference polymer modified bitumen. The formulation composed of 61.0% phenolicmodified rosin, 30.5% oil and 8.5% LDPEr has shown suitable mechanical properties for roofing materials, and has exhibited enhanced energy efficiency derived from its light yellowish to brownish color. Under the experimental radiant flux conditions, surface temperature of the non-bituminous binder was 8 degrees C lower than that of the black bitumen. Moreover, conduction heat transfer through this roofing material was about 14% lower than that conducted through a bitumen-based membrane with the same thickness. Accordingly, developed binders are expected to behave as reflective building materials aiming to reduce the heat island effects and save energy.

Automated summary

Non-bituminous binders have been developed as sustainable roofing materials using bio-based rosin esters, waste cooking oil, and recycled polyethylene. The compatibility of binder compounds was studied through comprehensive characterization. Thermal conductivity and solar radiation tests revealed the enhanced energy efficiency of the non-bituminous binder compared to a reference polymer modified bitumen. The developed binders are expected to act as reflective building materials to reduce heat island effects and save energy.