Sage Journals: Discover world-class research

Abstract

In this article, experimental verification and validation of a peridynamics-based simulation technique, called peri-elastodynamics, are presented while simulating the guided Lamb wave propagation and wave–damage interaction for ultrasonic nondestructive evaluation and structural health monitoring applications. Peri-elastodynamics is a recently developed elastodynamic computation tool where material particles are assumed to interact with the neighboring particles nonlocally, distributed within an influence zone. First, in this article, peri-elastodynamics was used to simulate the Lamb wave modes and their interactions with the damages in a three-dimensional plate-like structure, while the accuracy and the efficacy of the method were verified using the finite element simulation method (FEM). Next, the peri-elastodynamics results were validated with the experimental results, which showed that the newly developed method is more accurate and computationally cheaper than the FEM to be used for computational nondestructive evaluation and structural health monitoring. Specifically, in this work, peri-elastodynamics was used to accurately simulate the in-plane and out-of-plane symmetric and anti-symmetric guided Lamb wave modes in a pristine plate and was extended to investigate the wave–damage interaction with damage (e.g. a crack) in the plate. Experiments were designed keeping all the simulation parameters consistent. The accuracy of the proposed technique is confirmed by performing error analysis on symmetric and anti-symmetric Lamb wave modes compared to the experimental results for pristine and damaged plates.

Keywords

Lamb wave peridynamics peri-elastodynamics wave–damage interaction wave propagation wavenumber–frequency analysis nonlocal mechanics

Get full access to this article

View all access options for this article.

References

Patra

Ahmed

Banerjee

Peri-elastodynamic simulations of guided ultrasonic waves in plate-like structure with surface mounted PZT. Sensors 2018; 18(1): E274.

Patra

Banerjee

Material state awareness for composites part II: precursor damage analysis and quantification of degraded material properties using quantitative ultrasonic image correlation (QUIC). Materials 2017; 10(12): E1444.

Patra

Banerjee

Material state awareness for composites part I: precursor damage analysis using ultrasonic guided coda wave interferometry (CWI). Materials 2017; 10(12): E1436.

Patra

Banerjee

Habtour

, et al. A novel ultrasonic technique for the detection of distributed precursor damages in composites. In: Proceedings of the ASME 2016 international mechanical engineering congress and exposition, Phoenix, AZ, 11–17 November 2016. New York: American Society of Mechanical Engineers.

Ghosh

Kundu

Karpur

Efficient use of Lamb modes for detecting defects in large plates. Ultrasonics 1998; 36(7): 791–801.

Farrar

Worden

An introduction to structural health monitoring. Philos Trans A Math Phys Eng Sci 2007; 365(1851): 303–315.

Giurgiutiu

Structural health monitoring: with piezoelectric wafer active sensors. Waltham, MA: Academic Press, 2007.

Patra

Ahmed

Saadatzi

, et al. Evidence of dissipative and growing nonlinearity in Lamb waves due to respective stress-relaxation and material degradation in composites. Ultrasonics. Epub ahead of print 14 January 2019. DOI: 10.1016/j.ultras.2019.01.002.

Giurgiutiu

Lamb wave generation with piezoelectric wafer active sensors for structural health monitoring. Smart Mater Struct 2003; 5056: 111–122.

10.

Kim

Chang

Time-domain spectral element method for built-in piezoelectric-actuator-induced Lamb wave propagation analysis. AIAA J 2008; 46(3): 591–600.

11.

Cho

Rose

JL.

A boundary element solution for a mode conversion study on the edge reflection of Lamb waves. J Acoust Soc Am 1996; 99(4): 2097–2109.

12.

Doyle

A spectral element approach to wave motion in layered solids. J Vib Acoust 1992; 114(4): 569–577.

13.

Gopalakrishnan

Chakraborty

Mahapatra

DR.

Spectral finite element method: wave propagation, diagnostics and control in anisotropic and inhomogeneous structures. London: Springer-Verlag, 2007.

14.

Ostachowicz

WM.

Damage detection of structures using spectral finite element method. Comput Struct 2008; 86(3): 454–462.

15.

Yim

Sohn

Numerical simulation and visualization of elastic waves using mass-spring lattice model. IEEE T Ultrason Ferr 2000; 47(3): 549–558.

16.

Moser

Jacobs

Modeling elastic wave propagation in waveguides with the finite element method. NDT&E Int 1999; 32(4): 225–234.

17.

Nishawala

Ostoja-Starzewski

Leamy

, et al. Simulation of elastic wave propagation using cellular automata and peridynamics, and comparison with experiments. Wave Motion 2016; 60: 73–83.

18.

Balasubramanyam

Quinney

Challis

, et al. A finite-difference simulation of ultrasonic Lamb waves in metal sheets with experimental verification. J Phys D Appl Phys 1996; 29(1): 147.

19.

Leckey

CAC

Rogge

Miller

, et al. Multiple-mode Lamb wave scattering simulations using 3D elastodynamic finite integration technique. Ultrasonics 2012; 52(2): 193–207.

20.

Lowe

MJ.

Matrix techniques for modeling ultrasonic waves in multilayered media. IEEE T Ultrason Ferr 1995; 42(4): 525–542.

21.

Banerjee

Kundu

Alnuaimi

NA.

DPSM technique for ultrasonic field modelling near fluid-solid interface. Ultrasonics 2007; 46(3): 235–250.

22.

Shrestha

Banerjee

Virtual nondestructive evaluation for anisotropic plates using Symmetry Informed Sequential Mapping of Anisotropic Green’s function (SISMAG). Ultrasonics 2018; 88: 51–63.

23.

Shrestha

Banerjee

. DPSM modeling of wave propagation in anisotropic half space. In: Proceedings of the American society for composites: thirty-first technical conference, Williamsburg, VA, 19–21 September 2016.

24.

Marzani

Viola

Bartoli

, et al. A semi-analytical finite element formulation for modeling stress wave propagation in axisymmetric damped waveguides. J Sound Vib 2008; 318(3): 488–505.

25.

Nadella

Cesnik

CES

. Local interaction simulation approach for modeling wave propagation in composite structures. CEAS Aeronaut J 2013; 4(1): 35–48.

26.

Paćko

Bielak

Spencer

, et al. Lamb wave propagation modelling and simulation using parallel processing architecture and graphical cards. Smart Mater Struct 2012; 21(7): 075001.

27.

Hafezi

Kundu

Peri-ultrasound modeling of dynamic response of an interface crack showing wave scattering and crack propagation. J Nondestruct Eval Diagn Progn Eng Syst 2018; 1(1): 011003.

28.

Hafezi

Kundu

Peri-ultrasound modeling for surface wave propagation. Ultrasonics 2018; 84: 162–171.

29.

Hafezi

Alebrahim

Kundu

Peri-ultrasound for modeling linear and nonlinear ultrasonic response. Ultrasonics 2017; 80: 47–57.

30.

Diehl

Schweitzer

MA.

Simulation of wave propagation and impact damage in brittle materials using peridynamics. In: Mehl

Bischoff

Schäfer

(eds) Recent trends in computational engineering-CE2014: optimization, uncertainty, parallel algorithms, coupled and complex problems. Cham: Springer, 2015, pp. 251–265.

31.

Shen

Giurgiutiu

. WFR-2D: an analytical model for PWAS-generated 2D ultrasonic guided wave propagation. In: Proceedings of the SPIE smart structures and materials + nondestructive evaluation and health monitoring, San Diego, CA, 9 March 2014. Bellingham, WA: International Society for Optics and Photonics (SPIE).

32.

Shen

Giurgiutiu

. WaveFormRevealer: An analytical framework and predictive tool for the simulation of multi-modal guided wave propagation and interaction with damage. Struct Health Monit Submitted 2013; 13(5): 497–511.

33.

Silling

SA.

Reformulation of elasticity theory for discontinuities and long-range forces. J Mech Phys Solids 2000; 48(1): 175–209.

34.

Silling

Askari

A meshfree method based on the peridynamic model of solid mechanics. Comput Struct 2005; 83(17): 1526–1535.

35.

Silling

Epton

Weckner

, et al. Peridynamic states and constitutive modeling. J Elasticity 2007; 88(2): 151–184.

36.

Giurgiutiu

Tuned Lamb wave excitation and detection with piezoelectric wafer active sensors for structural health monitoring. J Intel Mat Syst Str 2005; 16(4): 291–305.

37.

Shen

Giurgiutiu

WaveFormRevealer: an analytical framework and predictive tool for the simulation of multi-modal guided wave propagation and interaction with damage. Struct Health Monit 2014; 13(5): 491–511.

38.

Leckey

CAC

Rogge

Raymond

Parker guided waves in anisotropic and quasi-isotropic aerospace composites: three-dimensional simulation and experiment. Ultrasonics 2014; 54(1): 385–394.

39.

Michaels

Ruzzene

Frequency–wavenumber domain analysis of guided wavefields. Ultrasonics 2011; 51(4): 452–466.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

Experimental verification and validation of nonlocal peridynamic approach for simulating guided Lamb wave propagation and damage interaction

Abstract

Keywords

Get full access to this article

References

Supplementary Material