Force Measurement with a Strain Gauge Subjected to Pure Bending in the Fluid-Wall Interaction of Open Water Channels

Featured Application This research has specific applications in the measurement of forces of small magnitude, which occur in the fluid-wall interaction, through a non-destructive technique that allows for measuring the shear stress in open water channels. An experimental method to measure forces of small magnitude with a strain gauge as a force sensor in the fluid-wall interaction of open water channels is presented. Six uniaxial strain gauges were employed for this purpose, which were embedded across the entire sensing area and subjected to pure bending, employing two-point bending tests. Sixteen two-point bending tests were performed to determine the existence of a direct relationship between the load and the instrument signal. Furthermore, a regression analysis was used to estimate the parameters of the model. A data acquisition system was developed to register the behavior of the strain gauge relative to the lateral displacement induced by the loading nose of the universal testing machine. The results showed a significant linear relationship between the load and the instrumental signal, provided that the strain gauge was embedded between 30% and 45% of the central axis in the sensing area of the sensor (R-2 > 0.99). Thus, the proposed sensor can be employed to measure forces of small magnitude. Additionally, the linear relationship between the load and the instrumental signal can be used as a calibration equation, provided that the strain gauge is embedded close to the central axis of the sensing area.

Automated summary

This research presents an experimental method using strain gauges to measure small forces in fluid-wall interaction. The results showed a significant linear relationship between the strain gauge and the load, allowing for accurate measurement of small forces.