Search results for "Crack tip plasticity"

showing 2 items of 2 documents

On relation between J-integral and heat energy dissipation at the crack tip in stainless steel specimens

2019

In this paper, an experimental procedure to evaluate the elastic-plastic J-integral at the tip of a fatigue crack is presented. According to this new approach, the elastic component of the J-integral is derived from Thermoelastic Stress Analysis, while the plastic component of the J-integral is derived from the heat energy loss. An analytical link is proposed to apply this new experimental technique. Therefore, the elastic-plastic J-integral range was evaluated starting from infrared temperature maps measured in situ during crack propagation tests of AISI 304L stainless steel specimens. It was found that the range of the infrared thermography-based J-integral correlated well the crack growt…

J-integralMaterials scienceInfraredCrack tip plasticityMechanical EngineeringFracture Mechanicslcsh:Mechanical engineering and machineryEnergy methodlcsh:TA630-695Fracture mechanicslcsh:Structural engineering (General)DissipationFracture MechanicFinite element methodStress (mechanics)Settore ING-IND/14 - Progettazione Meccanica E Costruzione Di MacchineEnergy methodsThermoelastic dampingMechanics of MaterialsCrack tip plasticity; Energy methods; Fracture Mechanics; J-integral; Thermoelastic Stress AnalysisThermographyRange (statistics)Thermoelastic Stress Analysislcsh:TJ1-1570Composite materialFrattura ed Integrità Strutturale

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Infrared thermography-based evaluation of the elastic-plastic J-integral to correlate fatigue crack growth data of a stainless steel

2019

Abstract The elastic-plastic J-integral is adopted to correlate fatigue crack growth data of ductile metals. An analytical link is known to exist between the J-integral and the strain energy density averaged in a control volume embracing the crack tip. On the other hand, the strain energy fluctuation is the source of temperature variations close to a fatigue crack tip of a metal material; hence the possibility to measure the J-integral from infrared thermographic scanning at the crack tip is envisaged and it is the focus of this paper. It is proposed that the elastic component of the J-integral is derived from a thermoelastic stress analysis, while the plastic component of the J-integral is…

Materials scienceFracture mechanic02 engineering and technologyIndustrial and Manufacturing EngineeringStrain energyStress (mechanics)Thermoelastic damping0203 mechanical engineeringThermoelastic Stress AnalysisGeneral Materials ScienceComposite materialFatigueJ-integralCrack tip plasticityMechanical EngineeringEnergy methodTemperatureStrain energy density functionFracture mechanicsParis' law021001 nanoscience & nanotechnologyFinite element method020303 mechanical engineering & transportsMechanics of MaterialsModeling and SimulationFracture mechanics Crack tip plasticity Thermoelastic Stress Analysis Energy methods Fatigue Temperature J-integralThermography0210 nano-technology

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