Publication | Closed Access
Numerical and Experimental Study of Strain Rate Effects in Laser Forming
72
Citations
9
References
2000
Year
Laser Processing (Laser Material Processing)EngineeringMechanical EngineeringLaser ApplicationsConstant Peak TemperatureStrain RateHigh-power LasersLaser Micro-processingMechanicsLaser ManufacturingLaser FormingMaterials ScienceLaser Processing TechnologySolid MechanicsLaser-assisted DepositionStrain Rate EffectsLaser Processing (Business Administration)Applied PhysicsDirected Energy DepositionExperimental StudyMechanical PerformanceMechanics Of MaterialsHigh Strain Rate
The study investigates strain‑rate effects in laser forming through experimental and numerical methods, introducing a constant‑peak‑temperature approach to isolate temperature‑dependent strain‑rate influence. Using a constant‑peak‑temperature method and a numerical model that incorporates temperature‑ and strain‑rate‑dependent flow stress, the authors examined how strain rate affects forming efficiency, residual stress, and hardness. Simulation results agree with experimental observations, validating the model. Article ID: S1087-1357(00)01004-2.
Experimental investigation and numerical simulation of the influence of the strain rate in laser forming are presented. To isolate and effectively study the strain rate effects, which are temperature dependent, a “constant peak temperature” method is developed with the aid of numerical modeling and solution. Under the condition of the constant peak temperature, the effects of strain rate on forming efficiency, residual stress and hardness of the formed parts are studied both experimentally and numerically. In the numerical model, the temperature dependence and strain-rate dependence of the flow stress and other material properties are considered. The simulation results are consistent with the experimental observations. [S1087-1357(00)01004-2]
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