A new pressure sensor array for local normal stress measurement in complex fluids

TL;DR

This paper introduces a novel pressure sensor array integrated into a rheometer to measure local normal stresses in complex fluids, enabling detailed stress mapping and revealing heterogeneities in shear-thickening suspensions.

Contribution

It presents a unique piezo-capacitive foam sensor array for local stress measurement, extending rheometer capabilities with high spatial resolution and sensitivity.

Findings

Successfully measured normal stress differences with 2 Pa precision

Detected negative normal stresses in complex fluids

Identified rotating heterogeneities in shear-thickening suspensions

Abstract

A new pressure sensor array, positioned on the bottom plate of a standard torsional rheometer is presented. It is built from a unique piezo-capacitive polymeric foam, and consists of twenty-five capacitive pressure sensors (of surface 4.5$\times$4.5 mm$^2$ each) built together in a 5$\times$5 regular array. The sensor array is used to obtain a local mapping of the normal stresses in complex fluids, which dramatically extends the capability of the rheometer. We demonstrate this with three examples. First, the pressure profile is reconstructed in a polymer solution, which enable the simultaneous measurement of the first and the second normal stress differences $N_1$ and $N_2$, with a precision of 2 Pa. In a second part, we show that negative normal stresses can also be detected. Finally, we focus on the normal stress fluctuations that extend both spatially and temporally ina shear-thickening suspension of cornstarch particles. We evidence the presence of local a unique heterogeneity rotating very regularly. In addition to their low-cost and high versatility, the sensors show here their potential to finely characterize the normal stresses in viscosimetric flows.