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Multiaxial fatigue life estimation based on weight-averaged maximum damage plane under variable amplitude loading

Zhiqiang Tao, Guian Qian, Xiang Li, Jingyu Sun, Zi-Ling Zhang, Dao‐Hang Li

2023Journal of Materials Research and Technology15 citationsDOIOpen Access PDF

Abstract

An innovative critical plane determination approach with weight-averaged largest fatigue damage is proposed, in which the material failure modes can be considered. If material exhibits shear cracking behavior, a strain-based critical plane model with shear failure mode is selected to evaluate the weight function. Otherwise, other one with tensile failure mode is adopted. According to the proposed critical plane, a multiaxial fatigue lifetime estimation methodology is established for evaluating fatigue life. And, six kinds of materials are employed to validate the validity of presented methodology. The validation results reveal the presented methodology can estimate the orientation angles of failure plane accurately and supply satisfactory fatigue lifetime estimations for both shear and tensile failure mode materials. Furthermore, the proposed critical plane framework can be extended to be utilized with stress-based fatigue criteria, and prediction results show a good agreement with experimental data by another two materials.

Topics & Concepts

Materials scienceStructural engineeringUltimate tensile strengthAmplitudeFailure mode and effects analysisPlane (geometry)Vibration fatigueFatigue crackingShear (geology)Weight functionMode (computer interface)CrackingFatigue testingComposite materialComputer scienceMathematicsMathematical analysisEngineeringOpticsGeometryPhysicsOperating systemFatigue and fracture mechanicsNon-Destructive Testing TechniquesMechanical Behavior of Composites
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