Polypropylene-carbon nanofiber composites as strain-gauge sensor

Abstract

Polymeric materials have been replacing other materials in various applications, from structural to electronic components. In particular, since the discovery of conducting polymers and the beginning of the manufacture of conducting composites with carbon fillers, their use in electronics is growing up. A group of electronic components with large potential for industrial applications such as structural monitoring, biomedical or robotics are sensors based on the piezoresistive effect, fabricated from conductive polymers and/or composites. The aim of this article is to characterize the piezoresistive effect of conductive polymer composites based on polypropylene filled with carbon nanofibers, and to demonstrate a way of fabricating strain gauges from these materials, using industrial techniques. With this purpose, some films were prepared by shear extrusion, which allows the composites to be produced industrially in a standard non-expensive process. Then, both the dependence of the electrical response on the preparation conditions and on the mechanical solicitations was measured. The obtained gauge factor values, up to 2.5, and piezoresistive coefficients up to 0.0019 mm2/N, prove the viability of these materials for fabricating strain-gauges, where their main advantages are the lower price and the ability to deal with much higher deformations, when compared to metal or semiconductor strain-gauges.