Article | REF: IN226 V1

Monitoring of fatigue of materials from acoustic emission

Authors: Stéphanie DESCHANEL, Jérôme WEISS

Publication date: December 10, 2018, Review date: January 13, 2021

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ABSTRACT

Fatigue, i.e. the failure of mechanical structures under cyclic loading, remains a considerable technological challenge as it occurs unexpectedly when a structure is operating apparently in a safe and steady-state regime, with no external signs of mechanical deterioration. After introducing this context together with classical methods of fatigue monitoring from acoustic emission (AE), we present a new, non-destructive method to unambiguously detect fatigue crack propagation from specific, repeating AE signals with quasi-identical waveforms. Perspectives for in-service fatigue control are then given.

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AUTHORS

  • Stéphanie DESCHANEL: Senior lecturer at INSA Lyon - MATEIS, INSA de LYON/Université de Lyon, France

  • Jérôme WEISS: Research Director, CNRS - ISTerre, CNRS/Université Grenoble-Alpes, France

 INTRODUCTION

Fatigue is one of the most dangerous mechanical processes leading to the failure of parts or structures, encountered in a variety of modern industrial situations ranging from nuclear reactors to microelectronic connections. However, we do not yet have non-destructive methods or indicators capable of predicting fatigue life, generally still estimated today from empirical relationships such as the Manson-Coffin law, which relates the number N R of cycles to fatigue failure to the imposed cyclic plastic strain amplitude Δε p : NR=c×Δεpβ . The problem with this type of approach is that the parameters c and β depend on the material, as well as the loading mode (triaxiality, for example), and must therefore be determined by numerous calibration tests. This article presents, in various metallic materials, the detection of acoustic emission signals specific to fatigue crack propagation. These signals, known as acoustic multiplets, are characterized by almost identical waveforms, the signature of a single source, and are repeatedly triggered over many successive loading cycles at the same stress level. They mark the slow, incremental propagation of a fatigue crack at each cycle, or friction along fracture surfaces. Being specific to incremental fatigue cracking, they can be used as early warnings of crack propagation, which will ultimately lead to global failure. Their detection and characterization thus pave the way for new, reliable monitoring of the onset of fatigue cracks during mechanical testing or within structures in service.

Key points

Field: Non-destructive testing

Degree of technology diffusion: Emergence

Technologies involved: Acoustic emission

Applications: Non-destructive testing of fatigue cracking

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Controlling material fatigue by acoustic emission