Guided waves for damage identification in pipeline structures: A review

Summary The present study focuses on estimating material nonlinearity and consequently remaining useful life of fatigued specimens using the amplitude‐ and physics‐based material nonlinearity parameters evaluated for Lamb wave motion in plate specimens. The amplitude‐based nonlinearity parameter depends on amplitudes of the Lamb wave harmonics generated due to material nonlinearity. Here, it is employed to estimate the inherent and dislocation induced material nonlinearities for different stages of fatigue. The cumulative effect is obtained from the strict matching of phase and group velocities of the S1 − S2 mode pair. The physics‐based nonlinearity parameter is obtained from the higher order elastic coefficients, plastic coefficients, and substructural evolution parameters. It does not depend on wave propagation distance; however, it depends on percent fatigue life. Thus, it is used to construct a theoretical nonlinearity curve. A spectral amplitude normalization technique is given to systematically evaluate the material nonlinearity, once the Lamb wave data over different wave propagation distances are known either from experiments or from simulations. The values of amplitude‐based nonlinearity parameter thus estimated through the simulation and experiments for different fatigue stages are then plotted onto the obtained theoretical nonlinearity curve. A reasonably good agreement is seen between the fatigue life estimations given by both the nonlinearity parameters. Thus, the amplitude‐based nonlinearity parameter obtained from the Lamb wave response can be effectively used to estimate the remaining useful life of the fatigued plate specimens.

Section: Evaluation Ofphysics‐based Materials Nonlinearity Parametermentioning

confidence: 99%

“…The internal tensile stress σ psb generated in the PSBs can be given as

σ_{psb} \approx \frac{5.7}{2 π ((), 1 - ν)} italicGϵ,

Section: Evaluation Ofphysics‐based Materials Nonlinearity Parametermentioning

confidence: 99%

See 1 more Smart Citation

Estimation of remaining useful life of fatigued plate specimens using Lamb wave‐based nonlinearity parameters

Tse

Masurkar

Yelve³

2020

“…The ultrasonic waves propagating through such material produce additional wave components with frequencies multiple of the excitation frequency called as higher harmonics . The higher harmonics generation takes place in waves because of the material nonlinearity, classified as the classical nonlinearity . The classical nonlinearity is induced in a pristine state material through lattice anharmonicity, which is generally represented by the higher order elastic constants .…”

Section: Introductionmentioning

confidence: 99%

Theoretical and experimental evaluation of material nonlinearity in metal plates using Lamb waves

Yelve

Tse

Masurkar

2018

Summary In this study, an equation is proposed considering Lamb wave motion in a plate in order to estimate the nonlinearity in plate material. The equation evaluates material nonlinearity in terms of amplitudes of the fundamental and second harmonics of Lamb waves. Because the Lamb wave second harmonic can be generated in a nonlinear material through the experiments or simulation, the proposed equation is practically useful to estimate the material nonlinearity. Accordingly, authors carried out experiments on pristine 1100‐H14 Aluminium (Al) specimens using Lamb waves and obtained their inherent material nonlinearity using the amplitude‐based equation. Additionally, authors obtained the value of inherent material nonlinearity in 1100‐H14 Al using the constitutive nonlinear stress‐strain relation containing higher order elastic constants. The material nonlinearity parameters estimated using the experimental results and amplitude‐based equation are then compared with that obtained using the constitutive nonlinear equation. The difference between the results is marginal. Thus, using amplitudes of the fundamental and second harmonics of Lamb waves obtained through the experiments, the proposed amplitude‐based equation can be used to estimate the material nonlinearity in metal plates with fair accuracy.

“…Three fundamental tasks of the SHM techniques are detection, localization, and characterization of damage. There are many methods for SHM including acoustic emissions, vibration, laser scanning, digital imaging, electrical impedance, ultrasonic waves, thermal imaging, impact echo, and eddy current . For the purpose of damage detection, a large number of damage indices (DI) has been developed, which make it possible to determine the existence of damage and monitor its further propagation in time.…”

Section: Introductionmentioning

confidence: 99%

Experimental and numerical research on damage localization in plate-like concrete structures using hybrid approach

Stojić

Nestorović

Marković

et al. 2018

This paper presents an experimental–numerical analysis of damage localization of concrete plate‐like elements on the basis of hybrid approach. The proposed hybrid approach uses the fast discrete wavelet transform, energy approach, and time of flight criterion for the purpose of localization of single and multidamage problems inside or on the periphery of concrete elements. Verification of the proposed damage localization approach has been performed under laboratory conditions using a laser scanning‐based system with piezoelectric excitation of the wave propagation. Numerical simulation of the wave propagation is performed using the explicit finite element method using 3D models with linear‐elastic material model of concrete with Rayleigh damping. The Rayleigh damping coefficients are determined on the basis of experimental data and implemented in numerical models. Validation of the numerical model is conducted, based on the comparison with sensor output signals obtained through experimental measuring and a very good agreement of results is obtained. The proposed hybrid approach to damage localization is verified using 15 different models/specimens, varying the number, shape (circular or notched), and position of damage, as well as the number and placement of actuators/sensors. For all the analyzed scenarios, the hybrid approach successfully localized the damage even for the least number of used sensor positions. In the models with the circular damage, the damage image created on the basis of the hybrid approach is almost identical to the actual shape of the damage, indicating a good potential of the method for damage localization.