Litcius/Paper detail

MEMS Vibrometer for Structural Health Monitoring Using Guided Ultrasonic Waves

Jan Niklas Haus, Walter Lang, Thomas Roloff, Liv Rittmeier, Sarah Bornemann, Michael Sinapius, Andreas Dietzel

2022Sensors14 citationsDOIOpen Access PDF

Abstract

Structural health monitoring of lightweight constructions made of composite materials can be performed using guided ultrasonic waves. If modern fiber metal laminates are used, this requires integrated sensors that can record the inner displacement oscillations caused by the propagating guided ultrasonic waves. Therefore, we developed a robust MEMS vibrometer that can be integrated while maintaining the structural and functional compliance of the laminate. This vibrometer is directly sensitive to the high-frequency displacements from structure-borne ultrasound when excited in a frequency range between its first and second eigenfrequency. The vibrometer is mostly realized by processes earlier developed for a pressure sensor but with additional femtosecond laser ablation and encapsulation. The piezoresistive transducer, made from silicon, is encapsulated between top and bottom glass lids. The eigenfrequencies are experimentally determined using an optical micro vibrometer setup. The MEMS vibrometer functionality and usability for structural health monitoring are demonstrated on a customized test rig by recording application-relevant guided ultrasonic wave packages with a central frequency of 100 kHz at a distance of 0.2 m from the exciting ultrasound transducer.

Topics & Concepts

Laser Doppler vibrometerLaser scanning vibrometryAcousticsUltrasonic sensorStructural health monitoringMaterials scienceTransducerMicroelectromechanical systemsPiezoresistive effectCapacitive micromachined ultrasonic transducersShear wavesOpticsOptoelectronicsShear (geology)WavelengthPhysicsDistributed feedback laserComposite materialUltrasonics and Acoustic Wave PropagationAcoustic Wave Resonator TechnologiesAdvanced Fiber Optic Sensors