Heat and Mass Transfer of Additive Manufacturing Processes for Metals

Wei, Zhengying; Du, Jun

doi:10.5772/intechopen.84889

Cited by 2 publications

(2 citation statements)

References 27 publications

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“…When evaporation occurs in the keyhole melting mode, however, it is reported that recoil pressure becomes the principal driving force of the molten metal [21]. Figure 1 helps to illustrate the powder melting and solidi cation evolution process in L-PBF [22]. When the laser is turned on, the beam energy is absorbed by the powder layer and the powder melts, resulting in a depression area, associated with the recoil force, caused by the evaporation of material.…”

Section: Introductionmentioning

confidence: 99%

Application of in-situ process monitoring to optimize laser parameters during laser powder bed fusion printing of Ti-6Al-4V parts with overhang structures

Power,

Humphreys,

Hartnett

et al. 2023

Preprint

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Geometrically complex features, such as overhang structures, can be a challenge in laser powder bed fusion (L-PBF), as they can be associated with print defects, such as porosity. In this study, Ti-6Al-4V alloy overhang structures were fabricated using an L-PBF system. Differences were observed in the microstructure in the region around the overhang structures, compared with that observed for the bulk alloy. These included larger grain sizes and a less homogenous microstructure in the print layers closest to overhang structures. It is hypothesized that these microstructural changes are associated with the excess heat generated in the overhang region due to the decreased thermal conductivity of the powder immediately below the print layers, compared with solid alloy. Also observed was an increased level of porosity (up to 0.08%) in the overhang print alloy, compared with the corresponding <0.02% in the alloy bulk. During printing, in-situ process monitoring of the meltpool emissions was obtained in the near-infrared range and correlated with the properties of the printed parts. This in-process data assisted in selecting optimal laser processing conditions in the first fifteen layers above the overhang to prevent meltpool overheating. By systematically controlling the laser energy during the printing of L-PBF overhang structures, the level of porosity was reduced to match that of the bulk alloy. There was also an associated reduction in the roughness of the overhang itself, with its Ra decreasing from 62.4 ± 7.3 µm to 7.5 ± 1.9 µm.

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Section: Introductionmentioning

confidence: 99%

Application of in-situ process monitoring to optimize laser parameters during laser powder bed fusion printing of Ti-6Al-4V parts with overhang structures

Power,

Humphreys,

Hartnett

et al. 2023

Preprint

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“…Changes in the product's shape, tension, quantity and material properties are significant because of the specific demands of the physical product [8]. Visual simulations for products under special conditions are used as initial tests on exploitation conditions using Elemental Analysis (EA) [9]- [11].…”

Section: Introductionmentioning

confidence: 99%

Real-Time Structural Analysis Based on Machine Learning for Custom Product Design: A Case Study of Orthopedic Fixator Product

Digdoyo,

Karno,

Hastomo

et al. 2023

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Mass customization is related to increasing the balance between the needs of companies that are focused on customers on conditions of production flexibility and efficiency. Product adjustment according to customer needs can increase the company's competitiveness. However, special production processes and adjustments are time consuming and cost inefficient. Parametric product modeling is a fairly popular technique for dealing with this problem. However, it still has challenges related to the high cost of software and a workforce that has special expertise in the field of quality control. In addition, product-specific designs cannot be tested quickly, resulting in a long production time. This study proposes a machine learning (ML) method that aims to obtain a fast time structure to analyze the production of orthopedic fixators. This research process requires a collection of training data with product attributes, physical characteristics, quality, selected ML techniques, and determination of the appropriate set of hyperparameters. Optimization results were obtained using the gradient boosting method with a value of . With these results, the orthopedic fixation device can be used in the case study of developing this machine learning model.

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Heat and Mass Transfer of Additive Manufacturing Processes for Metals

Cited by 2 publications

References 27 publications

Application of in-situ process monitoring to optimize laser parameters during laser powder bed fusion printing of Ti-6Al-4V parts with overhang structures

Application of in-situ process monitoring to optimize laser parameters during laser powder bed fusion printing of Ti-6Al-4V parts with overhang structures

Real-Time Structural Analysis Based on Machine Learning for Custom Product Design: A Case Study of Orthopedic Fixator Product

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