Flexible Low-Density Polyethylene-BaTiO3 Nanoparticle Composites for Monitoring Leakage Current in High-Tension Equipment

Polymer-nanoparticle composites prepared using a low-density polyethylene (LDPE) matrix with BaTiO3 nanoparticle compositions of 6, 9, 12, and 15 wt % have shown insulating behavior and are evaluated for their applicability as flexible strain sensors. With increasing percentage of the nanoparticles, the LDPE crystallinity decreased from 38.11 to 33.79% and the maximum electrical displacement response was seen to increase from 2.727 x 10(-4) to 4.802 x 10(-4) C/cm(2). The maximum current, remnant current, and coercive field, all increased with the increasing nanoinclusion loading. Furthermore, the interaction radius values derived from the threedimensional (3D) model of the nanoparticle dispersion state in polymer-nanoparticle composites were found to be correlated with its key properties. The interaction radius values from the simulated 3D model gave a clear basis for comparing the electrical properties of the samples with the effect of the nanoparticles' functionalization on the dispersion state in the context of the increased NP loading and giving the values of 275, 290, 310, and 300 nm, respectively. The 12 wt % nanoparticulate-loaded sample demonstrates the best overall trade-off of key parameters studied herein. Overall, the results demonstrate that these flexible polymer-nanoparticle composites could be used for strain-based sensors in the high-tension applications.

Automated summary

As the percentage of nanoparticles increases, the crystallinity of LDPE decreases, while the maximum electrical displacement response, current, remnant current, and coercive field all increase. The simulated 3D model indicates that the 12% nanoparticulate-loaded sample demonstrates the best overall trade-off of key parameters.