Pressure sensing by electro-mechanical coupling in compliant dielectric membranes polarized by a bias voltage

TL;DR

This paper introduces a novel pressure sensing method using electro-mechanical coupling in compliant dielectric membranes polarized by a bias voltage, expanding the range of usable materials.

Contribution

It demonstrates polarization of dielectric materials with bias voltage to enable pressure sensing in soft elastomers like silicone rubber membranes.

Findings

Capacitance change in silicone membranes produces measurable voltage signals during deformation.

Bias voltage polarization allows use of soft elastomers as pressure sensors.

The approach broadens material options for compliant pressure sensing devices.

Abstract

Among smart materials, piezoelectric materials occupy a very prominent position for sensing and actuation functions. Combined with simple or more advanced shunts, they are also proposed in various vibration mitigation schemes. However, the selection of available piezoelectric materials is mainly limited to ceramics (with an elastic modulus in the order of 10 Gpa (e.g. PZT ceramics) and a few polymer materials, with elastic modulus in the range of 1 Gpa (e.g. PVDF). In both cases, the high mechanical impedance and, consequently, the small dynamic strains limit the application of these materials to stiff structures. In this contribution, we discuss using a bias voltage to polarize dielectric materials and thereby compensate for the lack of spontaneous polarization observed in piezoelectrics. This enables access to materials with a wider range of elastic properties, such as soft elastomers, e.g. poly(dimethylsiloxane). As an example, we present a practical implementation of a silicone rubber membrane used as a highly compliant dynamic pressure sensor. For such nearly-incompressible materials, the capacitance change during dynamic deformation of the membranes is sufficiently large to generate a measurable dynamic voltage change over the membrane.