An ultrasensitive device with embedded phononic crystals for the detection and localisation of nonlinear guided waves

TL;DR

This paper introduces an active ultrasonic device with embedded phononic crystals that enhances the detection and localization of nonlinear guided waves, aiding in structural damage assessment.

Contribution

It presents a novel design integrating phononic crystals into ultrasonic sensors to improve sensitivity and selectivity for damage detection in structures.

Findings

Phononic crystals effectively open band gaps at excitation frequencies.

The device can detect higher harmonics indicative of damage.

Experimental validation confirms damage localization capability.

Abstract

In this work, a novel approach for the detection and localisation of nonlinear guided waves often associated with the presence of damage in structural components is proposed. The method is active and consists of a piezoelectric transducer bonded to the inspected structure exciting a narrow frequency band wave packet and sensors placed at the proposed ultrasonic devices with embedded phononic crystals. Unit cells of phononic crystals are optimized to open a band gap at the excitation frequency so that the excited waves are attenuated, while the sensitivity detection of higher harmonics is increased. The proposed approach is tested numerically and validated experimentally by considering various manufacturing methods, materials, and unit cell geometries. A parametric study of the angle of attachment of the ultrasonic devices with the embedded phononic crystals to the inspected structure is performed. Band gaps and filtering capabilities of several prototypes are tested. Numerical simulations of guided wave propagation that include the effect of delamination clapping proved that the proposed designs are sensitive enough to detect higher harmonics by simple signal thresholding. The most promising prototype is tested experimentally showing its capability of detection and localisation of a simulated damage.