Papers
Topics
Authors
Recent
Search
2000 character limit reached

Experimental and numerical investigations on the acoustoelastic effect in hyperelastic waveguides

Published 4 Dec 2023 in cs.CE | (2312.01810v1)

Abstract: Guided ultrasonic wave based structural health monitoring has been of interest over decades. However, the influence of pre-stress states on the propagation of Lamb waves in thin-walled structures is not fully covered, yet. So far experimental work presented in the literature only focuses on a few individual frequencies, which does not allow a comprehensive verification of the numerous numerical investigations. Furthermore, most work is based on the strain-energy density function by Murnaghan. To validate the common modeling approach and to investigate the suitability of other non-linear strain-energy density functions an extensive experimental and numerical investigation covering a large frequency range is presented here. The numerical simulation comprises the use of the Neo-Hooke as well as the Murnaghan material model. It is found that these two material models show qualitatively similar results. Furthermore, the comparison with the experimental results reveals, that the Neo-Hooke material model reproduces the effect of pre-stress on the difference in the Lamb wave phase velocity very well in most cases. For the $A_0$ wave mode at higher frequencies, however, the sign of this difference is only correctly predicted by the Murnaghan model. In contrast to this the Murnaghan material model fails to predict the sign change for the $S_0$ wave mode.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (62)
  1. Giurgiutiu V. Structural health monitoring with piezoelectric wafer active sensors. Amsterdam: Academic Press/Elsevier, 2008.
  2. Lamb-Wave Based Structural Health Monitoring in Polymer Composites. Springer International Publishing, 2018.
  3. Acoustoelastic waves in orthotropic media. The Journal of the Acoustical Society of America 1985; 77(3): 806–812.
  4. Effects of Residual Stress on Guided Waves in Layered Media. Boston, MA: Springer US, 1998. pp. 1635–1642.
  5. Biot MA. Non-linear theory of elasticity and the linearized case for a body under initial stress. The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science 1939; 27(183): 468–489.
  6. Biot MA. The influence of initial stress on elastic waves. Journal of Applied Physics 1940; 11(8): 522–530.
  7. Towards an acoustoelastic theory for measurement of residual stress. Journal of Elasticity 1987; 32: 159–182.
  8. Hoger A. On the determination of residual stress in an elastic body. Journal of Elasticity 1986; 16: 303–324.
  9. Murnaghan FD. Finite deformation of an elastic solid. NY: Dover Publications, 1951.
  10. Second-order elastic deformation of solids. Physical Review 1953; 92(5): 1145–1149.
  11. Third-order elastic constants and the velocity of small amplitude elastic waves in homogeneously stressed media. Physical Review 1964; 135: A1604–A1610.
  12. Sound waves in deformed perfectly elastic materials. acoustoelastic effect. The Journal of the Acoustical Society of America 1961; 33(2): 216–225.
  13. Crecraft D. The measurement of applied and residual stresses in metals using ultrasonic waves. Journal of Sound and Vibration 1967; 5(1): 173–192.
  14. Hsu NN. Acoustical birefringence and the use of ultrasonic waves for experimental stress analysis. Experimental Mechanics 1974; 14: 169–176.
  15. Application of ultrasonic-pulse-spectroscopy measurements to experimental stress analysis. Experimental Mechanics 1976; 16: 448–453.
  16. The physical fundamentals of the ultrasonic nondestructive stress analysis of solids. International Applied Mechanics 2000; 36: 1119–1149.
  17. Surface waves in deformed elastic materials. Archive for Rational Mechanics and Analysis 1961; 8(1): 358–380.
  18. Husson D. A perturbation theory for the acoustoelastic effect of surface waves. Journal of Applied Physics 1985; 57(5): 1562–1568.
  19. The effect of load on guided wave propagation. Ultrasonics 2007; 47: 111–122.
  20. Modeling of the influence of a prestress gradient on guided wave propagation in piezoelectric structures. The Journal of the Acoustical Society of America 2006; 120(4): 1964–1975.
  21. Loveday P. Semi-analytical finite element analysis of elastic waveguides subjected to axial loads. Ultrasonics 2008; 49: 298–300.
  22. Implication of changing loading conditions on structural health monitoring utilising guided waves. Smart Materials and Structures 2018; 27(2): 025003.
  23. Dispersion curves for Lamb wave propagation in prestressed plates using a semi-analytical finite element analysis. The Journal of the Acoustical Society of America 2018; 143(2): 829–840.
  24. Acoustoelastic guided wave propagation in axial stressed arbitrary cross-section. Smart Materials and Structures 2019; 28(4): 045013.
  25. Finite element prediction of acoustoelastic effect associated with Lamb wave propagation in pre-stressed plates. Smart Materials and Structures 2019; 28(9): 095007.
  26. Gandhi N, Michaels JE and Lee SJ. Acoustoelastic lamb wave propagation in biaxially stressed plates. The Journal of the Acoustical Society of America 2012; 132(3): 1284–1293.
  27. Multiphysics simulation method of lamb wave propagation with piezoelectric transducers under load condition. Chinese Journal of Aeronautics 2019; 32(5).
  28. Experimental study of the acoustoelastic Lamb wave in thin plates. AIP Conference Proceedings 2016; 1706(1): 070009.
  29. Nonlinear Finite Elements for Continua and Structures. Wiley, 2013.
  30. Ogden RW. Non-Linear Elastic Deformations. Dover Civil and Mechanical Engineering, Dover Publications, 2013.
  31. Shams M, Destrade M and Ogden R. Initial stresses in elastic solids: Constitutive laws and acoustoelasticity. Wave Motion 2011; 48(7): 552–567.
  32. Modelling the layer-specific three-dimensional residual stresses in arteries, with an application to the human aorta. Journal of the Royal Society 2010; 7: 787–799.
  33. Hoger A. The elasticity tensors of a residually stressed material. Journal of Elasticity 1993; 31: 219–237.
  34. Experimental determination of dispersion diagrams over large frequency ranges for guided ultrasonic waves in fiber metal laminates. Smart Materials and Structures 2023; 32(8): 085011.
  35. Barth T, Rauter N and Lammering R. Experimental determination of Lamb wave dispersion diagrams using 2d fourier transform and laser vibrometry. Preprint at https://wwwresearchsquarecom/article/rs-1321459/v1 2022; 10.21203/rs.3.rs-1321459/v1.
  36. Investigations on guided ultrasonic wave dispersion behavior in fiber metal laminates using finite element eigenvalue analysis. PAMM 2023; 23(1): e202200149.
  37. Murnaghan FD. Finite deformations of an elastic solid. Am J Math 1937; 59: 235–260.
  38. Acoustoelastic coefficients in thick steel plates under normal and shear stresses. Experimental Mechanics 2016; 56: 1559–1575.
  39. Rivlin RS. The solution of problems in second order elasticity theory. Archive for Rational Mechanics and Analysis 1953; 2: 53–81.
  40. Köhler B. Dispersion relations in plate structures studied with a scanning laser vibrometer. In Proceedings of the 9th European NDT conference. pp. 1–11.
  41. Accurate determination of dispersion curves of guided waves in plates by applying the matrix pencil method to laser vibrometer measurement data. CEAS Aeronautical Journal 2013; 4: 61–68.
  42. Zimmermann E, Eremin A and Lammering R. Analysis of the continuous mode conversion of Lamb waves in fiber composites by a stochastic material model and laser vibrometer experiments. GAMM-Mitteilungen 2018; 41(1): e201800001.
  43. Lamb H. On waves in an elastic plate. Proceedings of the Royal Society of London Series A, Containing Papers of a Mathematical and Physical Character 1917; 93(648): 114–128.
  44. Graff K. Wave Motion in Elastic Solids. Dover Books on Physics, Dover Publications, 2012.
  45. Alleyne DN. The nondestructive testing of plates using ultrasonic Lamb waves. PhD Thesis, Imperial College of Science, Technology and Medicine, London, 1991.
  46. Determination of Lamb wave dispersion curves by means of fourier transform. Applied and Computational Mechanics 2012; 6: 5–16.
  47. Identification of Damage Using Lamb Waves: From Fundamentals to Applications, volume 48. Springer, London, 2009.
  48. The Measurement of Power Spectra, from the Point of View of Communications Engineering. Dover Publications, 1959.
  49. Shannon C. Communication in the presence of noise. Proceedings of the IRE 1949; 37(1): 10–21.
  50. Vu NN. Zur Wellenausbreitung in geschichteten Faserverbundstrukturen unter Verwendung nichtlinearer Stoffgesetze (in German). PhD Thesis, Helmut-Schmidt-Universität, Hamburg, 2020.
  51. Comsol multiphysics: Reference manual, 2005.
  52. Using Floquet periodicity to easily calculate dispersion curves and wave structures of homogeneous waveguides. AIP Conference Proceedings 2018; 1949(1): 020016.
  53. Floquet-bloch theory and its application to the dispersion curves of nonperiodic layered systems. Mathematical Problems in Engineering 2015; Volume 2015.
  54. Extraction of dispersion curves for waves propagating in free complex waveguides by standard finite element codes. Ultrasonics 2011; 51: 503 – 515.
  55. Ahmad ZAB. Numerical simulations of Lamb waves in plates using a semi-analytical finite element method. PhD Thesis, Otto-von-Guericke-Universität Magdeburg, 2011. 10.25673/5299.
  56. Numerical simulation of Lamb wave scattering in semi-infinite plates. International Journal for Numerical Methods in Engineering 2002; 53(5): 1145–1173.
  57. Gao H. Ultrasonic guided wave mechanics for composite material structural health monitoring. PhD Thesis, The Pennsylvania State University, 2007.
  58. Investigation of elastic modes propagating in multi-wire helical waveguides. Journal of Sound and Vibration 2010; 329: 1702–1716.
  59. Stobbe D. Acoustoelasticity in 7075-T651 Aluminum and Dependence of Third Order Elastic Constants on Fatigue Damage. PhD Thesis, Georgia Tech, 2005.
  60. Modelling wave propagation in two-dimensional structures using finite element analysis. Journal of Sound and Vibration 2008; 318: 884–902.
  61. Ichchou MN, Akrout S and Mencik JM. Guided waves group and energy velocities via finite elements. Journal of Sound and Vibration 2007; 305: 931–944.
  62. Numerical analysis of the main wave propagation characteristics in a steel-cfrp laminate including model order reduction. Acoustics 2022; 4(3): 517–537.

Summary

No one has generated a summary of this paper yet.

Sign Up to Summarize

Paper to Video (Beta)

No one has generated a video about this paper yet.

Sign Up to Generate All Videos Subscribe on YouTube

Whiteboard

No one has generated a whiteboard explanation for this paper yet.

Sign Up to Generate

Open Problems

We haven't generated a list of open problems mentioned in this paper yet.

Generate Now

Continue Learning

We haven't generated follow-up questions for this paper yet.

Generate Now

Collections

Sign up for free to add this paper to one or more collections.

Sign Up