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An extended maximum tangential strain energy density criterion considering T‐stress for combined mode I–III brittle fracture

Wen Hua, Jiuzhou Huang, Xin Pan, Jianxiong Li, Shiming Dong

2020Fatigue & Fracture of Engineering Materials & Structures53 citationsDOI

Abstract

Abstract The maximum tangential strain energy density (MTSED) criterion was modified by taking the influences of stress intensity factors and T‐stress into consideration for combined mode I–III brittle fracture. Furthermore, the Poisson's ratio and T‐stress influencing the fracture characteristics of cracked components were discussed by using the extended MTSED criterion. Moreover, the predicted values of this extended MTSED criterion and some testing results were comparatively analysed. The results indicate that the Poisson's ratio and T‐stress have no impact on the out‐of‐plane initiation angle; however, their effects on fracture resistance ratios are significant especially for pure mode III. A positive T‐stress increases the fracture resistance ratio, and it is opposite for a negative T‐stress. The predicted values calculated by the extended MTSED criterion agree very well with the testing data obtained with edge‐notched disc bend samples especially for pure mode III case.

Topics & Concepts

Strain energy density functionMaterials scienceStress intensity factorFracture (geology)BrittlenessStress (linguistics)Composite materialPoisson's ratioMode (computer interface)Plane stressPoisson distributionBrittle fractureStructural engineeringFracture mechanicsMathematicsStatisticsFinite element methodEngineeringComputer sciencePhilosophyLinguisticsOperating systemFatigue and fracture mechanicsNumerical methods in engineeringHydrogen embrittlement and corrosion behaviors in metals
An extended maximum tangential strain energy density criterion considering T‐stress for combined mode I–III brittle fracture | Litcius