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Numerical Modeling of Delamination in Fiber-Metal Laminates Caused by Low-Velocity Impact

  • Katerina A. BeklemyshevaEmail author
  • Alexey V. Vasyukov
  • Igor B. Petrov
Conference paper
Part of the Smart Innovation, Systems and Technologies book series (SIST, volume 133)

Abstract

The Grid-Characteristic Method (GCM) used in this research shows good results in many areas that require modeling of the elastic wave pattern: seismic survey, ultrasound, and failure of fragile materials. Barely visible impact damage that occurs in composites under a low-velocity impact can also be explained in terms of interaction of elastic waves with the complex structure of a composite. One of the most dangerous damage types is delamination because it reduces the longitudinal compression strength of the material. The GCM allows us to use various types of border and contact conditions, including elliptic contact destruction criterion described in this chapter. Several problem statements are considered to demonstrate capabilities of the method. A comparison of numerical and experimental data results in a qualitative agreement.

Keywords

Grid-characteristic method Numerical modeling Fiber-metal laminates Composites Low-velocity impact Barely visible impact damage Delamination 

Notes

Acknowledgements

The research was supported by the Russian Science Foundation, grant 17-71-10240.

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Copyright information

© Springer Nature Switzerland AG 2019

Authors and Affiliations

  • Katerina A. Beklemysheva
    • 1
  • Alexey V. Vasyukov
    • 1
  • Igor B. Petrov
    • 1
  1. 1.Moscow Institute of Physics and Technology (MIPT)DolgoprudnyRussian Federation

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