Stress-strain data for aluminum 6061-T651 from 9 lots at 6 temperatures under uniaxial and plane strain tension

Aakash, B.S.; Connors, JohnPatrick; Shields, Michael D.

doi:10.1016/j.dib.2019.104085

Cited by 12 publications

(6 citation statements)

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“…Without loss of generality, the experimental flow stress-plastic strain data of Al6061 aluminum alloy from the literature 28 are applied in the present work. There were six temperatures (20, 100, 150, 200, 250, 300 °C) considered in the experiments.…”

Section: Application For Materials Modellingmentioning

confidence: 99%

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Heteroscedastic sparse Gaussian process regression-based stochastic material model for plastic structural analysis

Chen

Shen

Zhang

2022

Sci Rep

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Describing the material flow stress and the associated uncertainty is essential for the plastic stochastic structural analysis. In this context, a data-driven approach-heteroscedastic sparse Gaussian process regression (HSGPR) with enhanced efficiency is introduced to model the material flow stress. Different from other machine learning approaches, e.g. artificial neural network (ANN), which only estimate the deterministic flow stress, the HSGPR model can capture the flow stress and its uncertainty simultaneously from the dataset. For validating the proposed model, the experimental data of the Al 6061 alloy is used here. Without setting a priori assumption on the mathematical expression, the proposed HSGPR-based flow stress model can produce a better prediction of the experimental stress data than the ANN model, the conventional GPR model, and Johnson Cook model at elevated temperatures. After the HSGPR-based flow stress model is implemented into finite element analysis, two numerical examples with synthetic material properties are performed to demonstrate the model’s capability in stochastic plastic structural analysis. The results have shown that with sufficient data, the distribution of the structural load carrying capacity at elevated temperatures and the variation of load–displacement curves during the loading and unloading processes can be accurately predicted by the HSGPR-based flow stress model.

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Section: Application For Materials Modellingmentioning

confidence: 99%

“… The experimental flow stress-plastic strain data of Al6061 aluminum alloys at the temperature of ( a ) 20 °C, ( b ) 100 °C, ( c ) 150 °C, ( d ) 200 °C, ( e ) 250 °C and ( f ) 300°C 28 . …”

Section: Application For Materials Modellingmentioning

confidence: 99%

Heteroscedastic sparse Gaussian process regression-based stochastic material model for plastic structural analysis

Chen

Shen

Zhang

2022

Sci Rep

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“…After the withdrawal of the tools, the formed part undergoes significant changes in shape, which means that springback is an additional material deformation that occurs during rebound [ 6 , 7 , 8 ], as indicated in Figure 1 . The analysis of stress/strain diagrams leads to the conclusion that the intensity of springback will increase with the material strength [ 9 , 10 , 11 , 12 , 13 ].…”

Section: Introductionmentioning

confidence: 99%

“…After the withdraw the formed part undergoes significant changes in shape, which means that an additional material deformation that occurs during rebound [6][7][8], as in ure 1. The analysis of stress/strain diagrams leads to the conclusion that th springback will increase with the material strength [9][10][11][12][13]. The rebound process is elastic, but a secondary plastic flow can also oc bending and straightening around the edges of the die and punch.…”

Section: Introductionmentioning

confidence: 99%

An Adaptive Algorithm and Additively Manufactured Punch Used to Form Aluminum Sheet Metal Parts

et al. 2023

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Self-adaptive mechanisms are gaining momentum in industrial processes. It is understandable that as the complexity increases, the human work must be augmented. Considering this, the authors have developed one such solution for the punch-forming process, using additive manufacturing, i.e., a 3D-printed punch, to draw into shape 6061-T6 aluminum sheets. This paper aims to highlight the topological study used to optimize the punch form shape, the methodology of the 3D printing process, and the material used. For the adaptive algorithm, a complex Python-to-C++ bridge was created. It was necessary as the script has computer vision (used for calculating stroke and speed), punch force, and hydraulic pressure measurement capabilities. The algorithm uses the input data to control its subsequent actions. Two approaches are used in this experimental paper, a pre-programmed direction and an adaptive one, for comparison purposes. The results, namely the drawing radius and flange angle, were statistically analyzed using the ANOVA methodology for significance. The results indicate significant improvements when using the adaptive algorithm.

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“…Then, two different metals, namely aluminum AA 6061-T651 and steel 4130, were considered. The data for aluminum AA 6061-T651 was obtained from the experimental measurements presented by Aakash et al [1,2] and that were made available [3]. The data for "T_020_A_1_001_022_03", was chosen as representative of the behavior of the alloy.…”

mentioning

confidence: 99%

Auxetic behavior obtained through the large deformations of variants of the rectangular grid

Farrugia

Gatt

Mizzi

et al. 2021

Mechanics of Advanced Materials and Structures

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Stress-strain data for aluminum 6061-T651 from 9 lots at 6 temperatures under uniaxial and plane strain tension

Cited by 12 publications

References 0 publications

Heteroscedastic sparse Gaussian process regression-based stochastic material model for plastic structural analysis

Heteroscedastic sparse Gaussian process regression-based stochastic material model for plastic structural analysis

An Adaptive Algorithm and Additively Manufactured Punch Used to Form Aluminum Sheet Metal Parts

Auxetic behavior obtained through the large deformations of variants of the rectangular grid

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