Impact Fracture and Fragmentation of Glass via the 3D Combined Finite-Discrete Element Method

A driving technical concern for the automobile industry is their assurance that developed windshield products meet Federal safety standards. Besides conducting innumerable glass breakage experiments, product developers also have the option of utilizing numerical approaches that can provide further insight into glass impact breakage, fracture, and fragmentation. The combined finite-discrete element method (FDEM) is one such tool and was used in this study to investigate 3D impact glass fracture processes. To enable this analysis, a generalized traction-separation model, which defines the constitutive relationship between the traction and separation in FDEM cohesive zone models, was introduced. The mechanical responses of a laminated glass and a glass plate under impact were then analyzed. For laminated glass, an impact fracture process was investigated and results were compared against corresponding experiments. Correspondingly, two glass plate impact fracture patterns, i.e., concentric fractures and radial fractures, were simulated. The results show that for both cases, FDEM simulated fracture processes and fracture patterns are in good agreement with the experimental observations. The work demonstrates that FDEM is an effective tool for modeling of fracture and fragmentation in glass.

Automated summary

The study utilized the combined finite-discrete element method (FDEM) to investigate 3D impact glass fracture processes, showing that FDEM is an effective tool for modeling fracture and fragmentation in glass. Mechanical responses of laminated glass and glass plate under impact were analyzed, with results comparing well against corresponding experiments. The simulated fracture processes and patterns in both laminated glass and glass plate cases were in good agreement with experimental observations, demonstrating the effectiveness of FDEM in modeling glass fracture.