Abstract
This study presents the adoption of locally constrained regression models (LCRMs) with logarithmic transformations in order to model the flow stress behavior of the high-temperature deformation of 5005 aluminum alloy. Hot tensile tests for 5005 aluminum alloy were conducted under the temperatures of 290 °C, 360 °C, 430 °C, and 500 °C, and the strain rates of 0.0003/s, 0.003/s, and 0.03/s. The flow stress behavior was analyzed based on variations in temperature and strain rate. The flow stress during the hot deformation was modeled using the traditional Arrhenius type constitutive equation and the neural network approach. Then, for improved prediction accuracy, the flow stress was modeled using LCRMs. The prediction accuracies of the models were compared by calculating the MAE (Maximum Absolute Error) and RMSE (Root-Mean-Squared Errors) values. The MAE and RMSE of the LCRMs were lower than the errors of the Arrhenius equation and the neural network model. The results show that LCRMs can be useful in modeling the flow stress of 5005 aluminum alloy, and that the developed model can accurately predict the flow stress.
Highlights
The results show that the Arrhenius equation has low prediction accuracy
The results showed that the errors by the Arrhenius equation and Neural Network (NN) were dispersed
The Maximum Absolute Error (MAE) and Root-Mean-Squared Errors (RMSE) values obtained by the locally constrained regression models (LCRMs) were smaller than those obtained by the Arrhenius equation and the NN
Summary
5xxx series aluminum alloys—which contain magnesium (Mg) as the main alloying element—have good corrosion resistance, weldability, and strength to weight ratios [1,2,3], and they are non-heat treatable. These advantages make such alloys premier materials for a wide range of applications, including vessel structures, ship construction, the automotive industry, the aircraft industry, the chemical industry, and food handling [2,3,4,5].
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