Ultrasonic waves for materials evaluation in fatigue, thermal and corrosion damage: A review

Marcantonio, Vera; Monarca, Danilo; Colantoni, Andrea; Cecchini, Massimo

doi:10.1016/j.ymssp.2018.10.012

Cited by 142 publications

(55 citation statements)

References 113 publications

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“…Recent theories and related experimental studies have shown that the fatigue damage of metal materials in the early stage is related to the non-linear effect of ultrasonic waves [1][2][3][4][5]. In the early stage of fatigue damage to metals, the waveform is distorted when ultrasonic waves at a single frequency propagate therein due to the presence of various micro-defects such as dislocations, persistent slip bands (PSB), and micro-cracks, thus generating second harmonics.…”

Section: Introductionmentioning

confidence: 99%

Measurement of the Acoustic Non-Linearity Parameter of Materials by Exciting Reversed-Phase Rayleigh Waves in Opposite Directions

Yan

Song

Nie

et al. 2020

Sensors

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The acoustic non-linearity parameter of Rayleigh waves can be used to detect various defects (such as dislocation and micro-cracks) on material surfaces of thick-plate structures; however, it is generally low and likely to be masked by noise. Moreover, conventional methods used with non-linear Rayleigh waves exhibit a low detection efficiency. To tackle these problems, a method of exciting reversed-phase Rayleigh waves in opposite directions is proposed to measure the acoustic non-linearity parameter of materials. For that, two angle beam wedge transducers were placed at the two ends of the upper surface of a specimen to excite two Rayleigh waves of opposite phases, while a normal transducer was installed in the middle of the upper surface to receive them. By taking specimens of 0Cr17Ni4Cu4Nb martensitic stainless steel subjected to fatigue damage as an example, a finite element simulation model was established to test the proposed method of measuring the acoustic non-linearity parameter. The simulation results show that the amplitude of fundamentals is significantly reduced due to offset, while that of second harmonics greatly increases due to superposition because of the opposite phases of the excited signals, and the acoustic non-linearity parameter thus increases. The experimental research on fatigue damage specimens was carried out using this method. The test result was consistent with the simulation result. Thus, the method of exciting reversed-phase Rayleigh waves in opposite directions can remarkably increase the acoustic non-linearity parameter. Additionally, synchronous excitation with double-angle beam wedge transducers can double the detection efficiency.

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Section: Introductionmentioning

confidence: 99%

Measurement of the Acoustic Non-Linearity Parameter of Materials by Exciting Reversed-Phase Rayleigh Waves in Opposite Directions

Yan

Song

Nie

et al. 2020

Sensors

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show abstract

“…Continuous degradation leads to predictable and unpredictable problems, sometimes with serious consequences. Therefore, it is necessary to do health testing for structures or materials in practical engineering [1][2][3][4][5].…”

Section: Introductionmentioning

confidence: 99%

Simulation of Three Constitutive Behaviors Based on Nonlinear Ultrasound

Zhan

Wang

et al. 2020

Applied Sciences

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Nonlinear ultrasound has attracted more and more attention. In classical acoustic nonlinear theory, the source of nonlinearity is the change of constitutive relation of materials. Structure response that distorts after a single tone ultrasound wave is important to detect imperfection. This is rarely found in current simulations. The current simulation always introduces defects which do not match to the classical acoustic nonlinear theory. In this manuscript, the recurrence expressions of three kinds of imperfect materials for subroutine are given. The verifying simulation model that is used for verifying recurrence equations and wave propagation model that are used for analysing the process of ultrasonic propagation are established. The results show that the two constitutive models are effective in the verifying simulation and the hysteresis material has some special characteristics. Finally, ultrasonic propagation in two types of materials produce the expected harmonics, which build foundations for simulations of nonlinear ultrasound.

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“…Another important recent development exploits the much greater sensitivity of TOECs as compared with second-order elastic constants to dislocation driven damage (fatigue, creep, etc) [21][22][23]. This effect motivated the development of experimental techniques, such as second and higher harmonic generation to evaluate the so-called early damage [24][25][26][27], i.e. damage accumulated prior to the formation of a propagating crack.…”

Section: Introductionmentioning

confidence: 99%

On the determination of the third-order elastic constants of homogeneous isotropic materials utilising Rayleigh waves

et al. 2019

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Ultrasonic waves for materials evaluation in fatigue, thermal and corrosion damage: A review

Cited by 142 publications

References 113 publications

Measurement of the Acoustic Non-Linearity Parameter of Materials by Exciting Reversed-Phase Rayleigh Waves in Opposite Directions

Measurement of the Acoustic Non-Linearity Parameter of Materials by Exciting Reversed-Phase Rayleigh Waves in Opposite Directions

Simulation of Three Constitutive Behaviors Based on Nonlinear Ultrasound

On the determination of the third-order elastic constants of homogeneous isotropic materials utilising Rayleigh waves

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