Abstract

A phase-field description of brittle fracture is employed in the reported four-point bending analyses of monolithic and laminated glass plates. Our aims are: (i) to compare different phase-field fracture formulations applied to thin glass plates, (ii) to assess the consequences of the dimensional reduction of the problem and mesh density and refinement, and (iii) to validate for quasi-static loading the time-/temperature-dependent material properties we derived recently for two commonly used polymer foils made of polyvinyl butyral or ethylene-vinyl acetate. As the nonlinear response prior to fracture, typical of the widely used Bourdin–Francfort–Marigo model, can lead to a significant overestimation of the response of thin plates under bending, the numerical study investigates two additional phase-field fracture models providing the linear elastic phase of the stress-strain diagram. The typical values of the critical fracture energy and tensile strength of glass lead to a phase-field length-scale parameter that is challenging to resolve in the numerical simulations. Therefore, we show how to determine the fracture energy concerning the applied dimensional reduction and the value of the length-scale parameter relative to the thickness of the plate. The comparison shows that the phase-field models provide very good agreement with the measured stresses and resistance of laminated glass, despite the fact that only one/two cracks are localised using the quasi-static analysis, whereas multiple cracks evolve during the experiment. It was also observed that the stiffness and resistance of the partially fractured laminated glass can be well approximated using a 2D plane-stress model with initially predefined cracks, which provides a better estimation than the one-glass-layer limit.

Highlights

  • Glass, despite its brittleness, has proven to be a suitable material for load-bearing or fail-safe transparent structures when combined with polymers or other plastic interlayers [1,2]

  • This comparison illustrates that the fracture energy has to be set with respect to the applied dimensional reduction, loading type, and the value of the length-scale parameter compared with the thickness of the structure under bending

  • In order to assess the behaviour of the phase-field model and the quality of the identified material parameters for both foils, we present a validation of the numerical predictions against the experimentally measured response for the three-layer laminated glass plates

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Summary

Introduction

Despite its brittleness, has proven to be a suitable material for load-bearing or fail-safe transparent structures when combined with polymers or other plastic interlayers [1,2]. Within the scope of the widely used finite element framework, the phase-field models provide promising results for many engineering problems, e.g., [20,21,22], and became popular in the computational modelling of fracture including their recent application to glass laminates under in-plane loads [23,24] and tall laminated beams under combined in-plane tension and bending [25]. We aim at predicting the flexural response of multi-layer samples in terms of, e.g., deflections and stresses, and discuss the corresponding fracture pattern predicted by the numerical model This way, we want to assess the strengths and drawbacks of the phase-field formulation in fracture modelling of laminated glass under quasi-static bending and its usability for practical structural elements. Due to the fine mesh needed for the phase-field fracture analysis, different dimensional reduction strategies for the finite element discretization were utilized, i.e., multi-layer beam or plate models and a 2D sectional plane-stress model.

Overview of Selected Approaches
Energy Functional for Elastic Bodies with Sharp Cracks
Phase-Field Approximation
Anisotropic Formulation
Governing Equations
Specification of Selected Approaches
Staggered Scheme and Hybrid Formulation
Parameters for the Phase-Field Models and Their Relation
Numerical Case Study of a Monolithic Glass Plate under Bending
Effect of the Phase-Field Formulation and Mesh Refinement
Effect of the Dimensional Reduction
Reduced Glass Strength Near Plate Edges
Material Composition of Laminated Glass
Testing of Polymers and the Material Model
Quasi-Static Bending Tests
Validation of the Phase-Field Model against Experimental Data
Four-Point Bending Tests on Solid Laminated Glass Samples
Four-Point Bending Tests on Laminated Glass Samples with One Layer Fractured
Beam Model for Laminated Glass and the Influence of the Interlayer
Findings
Conclusions

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