Thermomechanical Simulations of Residual Stresses and Distortion in Electron Beam Melting with Experimental Validation for Ti-6Al-4V

Abdullah, Fawaz M.; Anwar, Saqib; Al-Ahmari, Abdulrahman

doi:10.3390/met10091151

Cited by 11 publications

(3 citation statements)

References 28 publications

(33 reference statements)

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“…Subsequently, the calculated results of the temperature field were applied as loads to the stress field using the sequential coupling method. Finally, the analysis of thermal stress and distortion was conducted based on the fundamental equations of thermoelastic-plastic mechanics [10], [25], [26]. To ensure a realistic simulation process, the study employed the "birthdeath element" technique to simulate the deposition process of the part.…”

Section: E Finite Element Modelmentioning

confidence: 99%

Residual Stress and Distortion Prediction for Laser Directed Energy Deposition Based on Cyclic Heat Transfer Model

Chai,

Li,

Miao

et al. 2024

IEEE Access

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Predicting the residual stress and distortion caused by inhomogeneous temperature fields in the laser directed energy deposition (LDED) process is a challenging task. This study proposes a novel thermodynamic coupling simulation method based on the cyclic heat transfer model to accurately predict temperature, stress, and distortion evolution during the deposition process. The model effectively calculates the layer-by-layer superposition of thermal effects and cyclic accumulation of thermal stress during the deposition process, leading to improved prediction accuracy for temperature, residual stress, and distortion. Initially, the heat source model, the cyclic heat transfer model, and the thermoelastic matrix are established. The thermoelastic constitutive equation and the equilibrium differential equation are formulated to capture the actual process characteristics of the LDED accurately in order to achieve the thermodynamic coupling solution. Then, numerical simulations are performed on a typical model specimen, with simulation parameters consistent with the actual deposition parameters. Finally, the predicted results are validated through actual deposition experiments, and the temperature, stress, and distortion history are analyzed. The results demonstrate that the cyclic thermodynamic coupling model proposed in this study can effectively predict the deposited components' temperature, residual stress, and distortion evolution. This study establishes a crucial foundation for achieving precision and performance control in the deposition process and reducing residual stress and distortion in the components.INDEX TERMS Laser directed energy deposition (LDED), cyclic heat transfer model, thermodynamic coupling, residual stress, distortion.

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Section: E Finite Element Modelmentioning

confidence: 99%

Residual Stress and Distortion Prediction for Laser Directed Energy Deposition Based on Cyclic Heat Transfer Model

Chai,

Li,

Miao

et al. 2024

IEEE Access

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“…Additive Manufacturing: AM is defined as the joining of materials to create objects from three-dimensional (3D) model data, typically layer by layer [64,65]. AM techniques are increasingly developing and take highly viable applications into the real industry [66].…”

Section: B Industry 40 Technologiesmentioning

confidence: 99%

The Impact of Industry 4.0 Technologies on Manufacturing Strategies: Proposition of Technology-Integrated Selection

2022

Self Cite

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Industry 4.0 (I4.0) has increasingly been adopted as an advanced manufacturing strategy to counter global competition. The capability of a company to compete on various manufacturing strategy outputs (MSOs) such as cost, quality, delivery, flexibility, performance and innovativeness play a significant role in motivating the whole company to take advantage of its competitors. I4.0 is comprised of various technologies, and how I4.0 technologies can influence the MSOs are still unclear, and it took less interest in the literature. This article aims to analyze the influence of the I4.0 technologies on MSOs to achieve market competitiveness from the perspective of academic and industry experts. To do so, the influence of the adoption of various I4.0 technologies on the MSOs was investigated. Expert opinions were gathered on the relationship between manufacturing competitive capabilities and I4.0 technologies. The identification of the influential relationships provides arguments for the proposed I4.0 technology selections, which will allow companies to gain a highly competitive advantage. The results showed that the performance (regarding the MSOs) had a high potential for integration with different I4.0 technologies.

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“…It is necessary to put forward a new study on the effect of the substrate structure and the constraints on residual stress. In this paper, a sequentially coupled thermomechanical model [26,27] was utilized to simulate the residual stresses in DED AM products with different substrate structures and constraints. Then an experiment was also developed to validate the simulation results.…”

Section: Introductionmentioning

confidence: 99%

Numerical Studies of the Effects of the Substrate Structure on the Residual Stress in Laser Directed Energy Additive Manufacturing of Thin-Walled Products

Jing

Zhang

et al. 2022

Metals

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A new method of controlling the residual stress in laser directed energy deposition additive manufacturing (DED AM) products proposed based on constraints used in manufacturing and the substrate design. The simulation results of the residual stress, which were validated with the experimental measured data, showed that weaker constraints on the substrate could greatly decrease the residual stress in the laser DED AM products. In addition, by designing local reduced thickness regions into the substrate, such as long strip holes or support legs, the residual stress in DED AM products could be further decreased. In this study, when long strip holes were designed in the substrate, the tensile residual stress was decreased by 28%. An even smaller amount of residual stress was achieved when the design structure was changed to support legs. The tensile residual stress decreased by more than 30%. The fewer support legs, the smaller the residual stress. The residual stress in DED AM products could be well-controlled by design, while the stiffness can be weakened with fewer constraints.

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Thermomechanical Simulations of Residual Stresses and Distortion in Electron Beam Melting with Experimental Validation for Ti-6Al-4V

Cited by 11 publications

References 28 publications

Residual Stress and Distortion Prediction for Laser Directed Energy Deposition Based on Cyclic Heat Transfer Model

Residual Stress and Distortion Prediction for Laser Directed Energy Deposition Based on Cyclic Heat Transfer Model

The Impact of Industry 4.0 Technologies on Manufacturing Strategies: Proposition of Technology-Integrated Selection

Numerical Studies of the Effects of the Substrate Structure on the Residual Stress in Laser Directed Energy Additive Manufacturing of Thin-Walled Products

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