A simple model to fit and interpret creep curves-behaviour of modified micro-cellulose particulate composites

Micro crystalline cellulose is mostly used to improve thermo-mechanical properties of composites. This study aims to evaluate the creep behaviour of micro-cellulose epoxy-based composites, and the effect of silanization treatment on the reinforcements. A new viscoelastic model, based on the generalized logistic function was successfully tested. The results were directly associated with the material's structure-property relationships. Rigid particles restricted the molecular chain's motion, mainly on the amorphous segments. This difference achieved the needing of more energy, to achieve creep deformation. Then, MCC improved the structural integrity, when incorporated into an epoxy matrix. On one hand, the incorporation of silanized-MCC increased the mechanical behavior of the composite, due to the stiffer structure. Furthermore, the chemical modification provided an increment in the glassy plateau, associated with higher thermal energy required to initiate strain of the amorphous polymeric chains. This behaviour resulted in an abrupt decrease of load-bearing capability for the composites. Finally, the proposed model is suitable to be employed in creep curves, aiming to easily interpret the structure-property relationships of this test.

Automated summary

This study evaluated the creep behavior of micro-cellulose epoxy-based composites and investigated the effect of silanization treatment on the reinforcements. The results showed that micro crystalline cellulose improved the structural integrity of the composites, and the incorporation of silanized-MCC increased the mechanical behavior of the composite.