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Overcoming the cohesive zone limit in the modelling of composites delamination with TUBA cohesive elements

Published 14 Mar 2024 in cs.CE, cs.NA, and math.NA | (2403.09895v1)

Abstract: The wide adoption of composite structures in the aerospace industry requires reliable numerical methods to account for the effects of various damage mechanisms, including delamination. Cohesive elements are a versatile and physically representative way of modelling delamination. However, using their standard form which conforms to solid substrate elements, multiple elements are required in the narrow cohesive zone, thereby requiring an excessively fine mesh and hindering the applicability in practical scenarios. The present work focuses on the implementation and testing of triangular thin plate substrate elements and compatible cohesive elements, which satisfy C1-continuity in the domain. The improved regularity meets the continuity requirement coming from the Kirchhoff Plate Theory and the triangular shape allows for conformity to complex geometries. The overall model is validated for mode I delamination, the case with the smallest cohesive zone. Very accurate predictions of the limit load and crack propagation phase are achieved, using elements as large as 11 times the cohesive zone.

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References (20)
  1. P. Harper, S. R. Hallett, Cohesive zone length in numerical simulations of composite delamination, Engineering Fracture Mechanics 75 (2008) 4774–4792.
  2. Mixed-Mode Decohesion Finite Elements in for the Simulation Composite of Delamination Materials, Journal of Composite Materials 37 (2002) 1415–1438.
  3. Q. Yang, B. Cox, Cohesive models for damage evolution in laminated composites, International Journal of Fracture 133 (2005) 107–137.
  4. N. Moës, T. Belytschko, Extended finite element method for cohesive crack growth, Engineering Fracture Mechanics 69 (2002) 813–833.
  5. Analytical and numerical investigation of the length of the cohesive zone in delaminated composite materials, in: Mechanical response of composite. Computational Methods in Applied Sciences, vol 10., Springer, Dordrecht, 2007, pp. 77–97.
  6. Cohesive zone length of orthotropic materials undergoing delamination, Engineering Fracture Mechanics 159 (2016) 174–188.
  7. An engineering solution for mesh size effects in the simulation of delamination using cohesive zone models, Engineering Fracture Mechanics 74 (2007) 1665–1682.
  8. Decohesion finite element with enriched basis functions for delamination, Composites Science and Technology 69 (2009) 2616 – 2624.
  9. A framework for cohesive element enrichment, Composite Structures 92 (2010) 454 – 459.
  10. An enriched cohesive zone model for delamination in brittle interfaces, International Journal for Numerical Methods in Engineering 80 (2009) 609–630.
  11. A self-adaptive finite element approach for simulation of mixed-mode delamination using cohesive zone models, Engineering Fracture Mechanics 78 (2011a) 2202–2219.
  12. A three-dimensional self-adaptive cohesive zone model for interfacial delamination, Computer Methods in Applied Mechanics and Engineering 200 (2011b) 3540–3553.
  13. An improved cohesive element for shell delamination analyses, International Journal for Numerical Methods in Engineering 83 (2010) 611–641.
  14. Improved cohesive stress integration schemes for cohesive zone elements, Engineering Fracture Mechanics 107 (2013) 14–28.
  15. Mode I fracture in adhesively-bonded joints: A mesh-size independent modelling approach using cohesive elements, Engineering Fracture Mechanics 115 (2014) 73–95.
  16. A level set model for delamination - Modeling crack growth without cohesive zone or stress singularity, Engineering Fracture Mechanics 79 (2012) 191 – 212.
  17. An interface thick level set model for simulating delamination in composites, International Journal for Numerical Methods in Engineering 111 (2017) 303–324.
  18. Adaptive floating node method for modelling cohesive fracture of composite materials, Engineering Fracture Mechanics 194 (2018) 240 – 261.
  19. An isogeometric analysis Bézier interface element for mechanical and poromechanical fracture problems, International Journal for Numerical Methods in Engineering 97 (2014) 608–628.
  20. R. Russo, B. Chen, Overcoming the cohesive zone limit in composites delamination: modeling with slender structural elements and higher-order adaptive integration, International Journal for Numerical Methods in Engineering 121 (2020) 5511–5545. doi:https://doi.org/10.1002/nme.6497.
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