Experimental investigation and development of a deep learning framework to predict process-induced surface roughness in additively manufactured aluminum alloys

Muhammad, Waqas; Kang, Jidong; Ibragimova, Olga; Inal, Kaan

doi:10.1007/s40194-022-01445-8

Cited by 12 publications

(3 citation statements)

References 48 publications

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“…In the prediction of surface roughness for an AlSi10Mg aluminum alloy fabricated through laser powder bed fusion (LPBF), a deep learning framework was developed [ 160 ]. The framework involved fabricating specimens, measuring surface topography, extracting and streamlining roughness and LPBF processing data, and developing a deep neural network model.…”

Section: Ai-based Surface Roughness Prediction Methods For Additively...mentioning

confidence: 99%

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Application of Artificial Intelligence for Surface Roughness Prediction of Additively Manufactured Components

Batu,

Lemu,

Shimels

2023

Materials

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Additive manufacturing has gained significant popularity from a manufacturing perspective due to its potential for improving production efficiency. However, ensuring consistent product quality within predetermined equipment, cost, and time constraints remains a persistent challenge. Surface roughness, a crucial quality parameter, presents difficulties in meeting the required standards, posing significant challenges in industries such as automotive, aerospace, medical devices, energy, optics, and electronics manufacturing, where surface quality directly impacts performance and functionality. As a result, researchers have given great attention to improving the quality of manufactured parts, particularly by predicting surface roughness using different parameters related to the manufactured parts. Artificial intelligence (AI) is one of the methods used by researchers to predict the surface quality of additively fabricated parts. Numerous research studies have developed models utilizing AI methods, including recent deep learning and machine learning approaches, which are effective in cost reduction and saving time, and are emerging as a promising technique. This paper presents the recent advancements in machine learning and AI deep learning techniques employed by researchers. Additionally, the paper discusses the limitations, challenges, and future directions for applying AI in surface roughness prediction for additively manufactured components. Through this review paper, it becomes evident that integrating AI methodologies holds great potential to improve the productivity and competitiveness of the additive manufacturing process. This integration minimizes the need for re-processing machined components and ensures compliance with technical specifications. By leveraging AI, the industry can enhance efficiency and overcome the challenges associated with achieving consistent product quality in additive manufacturing.

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Section: Ai-based Surface Roughness Prediction Methods For Additively...mentioning

confidence: 99%

“…In the prediction of surface roughness for an AlSi10Mg aluminum alloy fabricated through laser powder bed fusion (LPBF), a deep learning framework was developed [160].…”

Section: Deep Neural Networkmentioning

confidence: 99%

Application of Artificial Intelligence for Surface Roughness Prediction of Additively Manufactured Components

Batu,

Lemu,

Shimels

2023

Materials

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“…Aluminum alloys are widely used in many industrial manufacturing fields such as aerospace and rail transportation [1][2][3][4], as they provide good mechanical properties and corrosion resistance. In the manufacturing of aluminum alloy components, welding is currently one of the most important jointing methods.…”

Section: Introductionmentioning

confidence: 99%

Microstructure and Hardness Analysis of Laser Welded A357 Semi-Solid Cast Alloy

Zhu,

Liu

et al. 2024

Preprint

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A357.0 alloy was casted by using RheoMetal™ process, and then welded using laser deep penetration welding. After welding, the specimens were subjected to microstructural characterization and microhardness testing. The results indicate that a surface liquid segregation (SLS) layer enriched of alloying elements was formed on the surface, resulting in an increase of Si content in molten pool compared to that in the ingot. The microstructure of the molten pool is mainly composed of fine equiaxed and columnar crystals. A small amount of spherical α1-Al phases were found in the boundary of the molten pool. The eutectic region in the melt pool is mainly composed of Si phases, and small amount of MgSi, and AlFeMgSi phases. Compared to the matrix, the content of Mg and Fe in the molten pool has significantly decreased, which may be the result of burning loss of Mg and Fe under the high laser energy. The hardness testing of the samples in this study showed that the hardness of the heat affected zone (HAZ) was significantly higher than that of the melt pool and SLS layer. The hardness of equiaxed crystals in the molten pool is slightly higher than that of columnar crystals.

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A novel machine learning-based approach for in-situ surface roughness prediction in laser powder-bed fusion

Toorandaz,

Taherkhani,

Liravi

et al. 2024

Additive Manufacturing

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Experimental investigation and development of a deep learning framework to predict process-induced surface roughness in additively manufactured aluminum alloys

Cited by 12 publications

References 48 publications

Application of Artificial Intelligence for Surface Roughness Prediction of Additively Manufactured Components

Application of Artificial Intelligence for Surface Roughness Prediction of Additively Manufactured Components

Microstructure and Hardness Analysis of Laser Welded A357 Semi-Solid Cast Alloy

A novel machine learning-based approach for in-situ surface roughness prediction in laser powder-bed fusion

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