Numerical investigation on the uniaxial compressive behaviour of an epoxy resin and a nanocomposite

The current work aims at exploring the relationship between complex failure behaviour and the presence of defects for RTM6 epoxy resin as well as hyperbranched polyester (HBP)/RTM6 nanocomposite under compressive loading. Numerical simulations were performed in LS-DYNA by means of a statistical appr...

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Bibliographic Details
Published in:European journal of mechanics, A, Solids A, Solids, 2022-03, Vol.92, p.104500, Article 104500
Main Authors: Ma, Dayou, Giglio, Marco, Manes, Andrea
Format: Article
Language:English
Subjects:
Addition polymerization
Axial stress
Compressive properties
Computer simulation
Damage assessment
Defects
Domains
Epoxy resins
Failure modes
Finite element method
Fracture
Mathematical models
Mechanical properties
Monte Carlo simulation
Nanocomposites
Nanomaterials
Nanoparticles
Polymeric material
Polymers
Spatial distribution
Stochastic
Voids and inclusions
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Summary:The current work aims at exploring the relationship between complex failure behaviour and the presence of defects for RTM6 epoxy resin as well as hyperbranched polyester (HBP)/RTM6 nanocomposite under compressive loading. Numerical simulations were performed in LS-DYNA by means of a statistical approach that exploits different failure strains among elements. It allows a phenomenological description of the effect of defects and different stress triaxialities on the failure modes of polymer/nanocomposite materials. Additionally, a parameter describing defects, named defect severity, was added to the model in order to quantify and explore the effect of defects on the mechanical behaviour during the damage process. Both the generalized incremental stress-state dependent damage model (GISSMO) and Monte Carlo method were employed to simulate the effect of stress triaxiality and the spatial distribution of defects on the mechanical performances. The relationship between the defect severity and the failure modes (tensile-domain and shear-domain) was also discussed. Numerical results of neat RTM6 showed that the presence of a large number of defects can lead to more brittle (tensile-domain) failure, while numerical results of HBP/RTM6 nanocomposite presented that the addition of nanoparticles can compensate the negative effect of the existing defects in polymer materials under uniaxial compression, which provides a novel insight for potential applications of nanomaterials. [Display omitted] •A numerical method with stochastic damage model and Monte Carlo method was developed for compressive behaviours of polymer.•The effect of defects inside polymer materials was investigated numerically with a parameter, defect severity, in the model.•Two different failure modes of RTM6 epoxy resin under uniaxial compression were captured numerically.•Nanoparticles may compensate the negative effect of existing defects on compressive mechanical properties of polymer materials .
ISSN:0997-7538
1873-7285
DOI:10.1016/j.euromechsol.2021.104500