Spatiotemporal Evolution of Stress Field during Direct Laser Deposition of Multilayer Thin Wall of Ti-6Al-4V

Ivanov, S. Yu.; Artinov, Antoni; Zemlyakov, Evgeniy; Karpov, I. D.; Rylov, S. A.; Em, V. T.

doi:10.3390/ma15010263

Cited by 10 publications

(3 citation statements)

References 59 publications

(67 reference statements)

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“…Thermomechanical models for AM analysis have been validated in previous work to optimize material properties and process parameters but for different geometries and parameters [33][34][35][36]. In addition, the numerical results have been compared with experimental measurements reported in [18] to ensure AM simulation accuracy.…”

Section: Resultsmentioning

confidence: 99%

Process Optimization and Distortion Prediction in Directed Energy Deposition

Ben Hammouda,

Mrad,

Marouani

et al. 2024

JMMP

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Directed energy deposition (DED), a form of additive manufacturing (AM), is gaining traction for its ability to produce complex metal parts with precise geometries. However, defects like distortion, residual stresses, and porosity can compromise part quality, leading to rejection. This research addresses this challenge by emphasizing the importance of monitoring process parameters (overlayer distance, powder feed rate, and laser path/power/spot size) to achieve desired mechanical properties. To improve DED quality and reliability, a numerical approach is presented and compared with an experimental work. The parametric finite element model and predictive methods are used to quantify and control material behavior, focusing on minimizing residual stresses and distortions. Numerical simulations using the Abaqus software 2022 are validated against experimental results to predict distortion and residual stresses. A coupled thermomechanical analysis model is employed to understand the impact of thermal distribution on the mechanical responses of the parts. Finally, new strategies based on laser scan trajectory and power are proposed to reduce residual stresses and distortions, ultimately enhancing the quality and reliability of DED-manufactured parts.

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Section: Resultsmentioning

confidence: 99%

Process Optimization and Distortion Prediction in Directed Energy Deposition

Ben Hammouda,

Mrad,

Marouani

et al. 2024

JMMP

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“…Although distortion simulations can be used to avoid cost-intensive trial-and-error approaches, most of the models are limited to simple geometries or sizes such as rectangles [32,33] and thin walls [34][35][36]. The reasons are extensive computational time and convergence errors on today's software and computers.…”

Section: Introductionmentioning

confidence: 99%

Comprehensive Distortion Analysis of a Laser Direct Metal Deposition (DMD)-Manufactured Large Prototype Made of Soft Martensitic Steel 1.4313

Dey,

Floeder,

Solcà

et al. 2024

JMMP

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Additive manufacturing (AM) by using direct metal deposition (DMD) often causes erratic distortion patterns, especially on large parts. This study presents a systematic distortion analysis by employing numerical approaches using transient–thermal and structural simulations, experimental approaches using tomography, X-ray diffraction (XRD), and an analytical approach calculating the buckling distortion of a piston. The most essential geometrical features are thin walls situated between massive rings. An eigenvalue buckling analysis, a DMD process, and heat treatment simulation are presented. The eigenvalue buckling simulation shows that it is highly dependent on the mesh size. The computational effort of the DMD and heat treatment simulation was reduced through simplifications. Moreover, artificial imperfections were imposed in the heat treatment simulation, which moved the part into the buckling state inspired by the experiment. Although the numerical results of both simulations are successful, the eigenvalue and DMD simulation cannot be validated through tomography and XRD. This is because tomography is unable to measure small elastic strain fields, the simulated residual stresses were overestimated, and the part removal disturbed the residual stress equilibrium. Nevertheless, the heat treatment simulation can predict the distortion pattern caused by an inhomogeneous temperature field during ambient cooling in an oven. The massive piston skirt cools down and shrinks faster than the massive core. The reduced yield strength at elevated temperatures and critical buckling load leads to plastic deformation of the thin walls.

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“…To adapt this form of production to largescale commercial manufacturing, better predictability and control over the part qualities are required. Full simulations of the L-PBF process can help with this shift by providing information about the origins of defects and potential directions for improvement [2]. A common metallic additive manufacturing technique is laser powder bed fusion (L-PBF), which produces high-resolution components and allows for precise control of parts dimensions [3].…”

Section: Introductionmentioning

confidence: 99%

Finite Element Method in L-PBF of Ti-6Al-4V: Influence of Laser Power and Scan Speed on Residual Stress and Part Distortion

Palmeri,

Pollara,

Licari

et al. 2023

Metals

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Laser powder bed fusion (L-PBF) is widely used in automotive, aerospace, and biomedical applications thanks to its ability to produce complex geometries. In spite of its advantages, parts produced with this technology can show distortion due to the residual stresses developed during the printing process. For this reason, numerical simulations can be used to predict thermal gradients and residual stresses that can result in part distortion. Thus, instead of performing experimental tests and using a trial and error approach, it is possible to use numerical simulation to save time and material. In this work, the effect of laser power and scan speed on residual stress and part distortion was analysed using a commercial finite element analysis (FEA) software DEFORM-3D™ with a layer-by-layer approach. Moreover, the accuracy of the numerical model with respect to process parameters and the utilised mesh was also studied. The results obtained from the numerical simulation were compared to the actual distortions to evaluate the accuracy of the FEM model. The predicted distortions using FEM analysis well fit the trend of the measured ones. The accuracy of the numerical model increases by considering a finer mesh.

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Spatiotemporal Evolution of Stress Field during Direct Laser Deposition of Multilayer Thin Wall of Ti-6Al-4V

Cited by 10 publications

References 59 publications

Process Optimization and Distortion Prediction in Directed Energy Deposition

Process Optimization and Distortion Prediction in Directed Energy Deposition

Comprehensive Distortion Analysis of a Laser Direct Metal Deposition (DMD)-Manufactured Large Prototype Made of Soft Martensitic Steel 1.4313

Finite Element Method in L-PBF of Ti-6Al-4V: Influence of Laser Power and Scan Speed on Residual Stress and Part Distortion

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