Optimization of CMT Characteristic Parameters for Swing Arc Additive Manufacturing of AZ91 Magnesium Alloy Based on Process Stability Analysis

Zhang, Zhongrui; Shen, Junqi; Hu, Sun; Chen, Yang; Yin, Chengxuan; Bu, Xianzheng

doi:10.3390/ma16083236

Cited by 3 publications

(2 citation statements)

References 33 publications

(37 reference statements)

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“…Preformed walls, each comprising a single cord per layer and consisting of 5 layers, were systematically deposited. Employing a zig-zag deposition strategy along the z-axis, as outlined in prior works by Zhang et al [37,38] and Rodideal et al [39], facilitated the attainment of uniform height at both ends of the preform. To ensure consistent heat transfer conditions across all samples, 316L-Si stainless steel preforms were fabricated atop low carbon steel substrates measuring 120 mm× 50 mm × 19.54 mm.…”

Section: Methodsmentioning

confidence: 99%

Effects of Contaminations on Electric Arc Behavior and Occurrence of Defects in Wire Arc Additive Manufacturing of 316L-Si Stainless Steel

Souto,

Lima,

Castro

et al. 2024

Metals

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Additive Manufacturing is a manufacturing process that consists of obtaining a three-dimensional object from the deposition of material layer by layer, unlike conventional subtractive manufacturing methods. Wire Arc Additive Manufacturing stands out for its high productivity among the Additive Manufacturing technologies for manufacturing metal parts. On the other hand, the excessive heat input promotes increased residual stress levels and the occurrence of defects, such as pores, voids, a lack of fusion, and delamination. These defects result in abnormalities during the process, such as disturbances in electrical responses. Therefore, process monitoring and the detection of defects and failures in manufactured items are of fundamental importance to ensure product quality and certify the high productivity characteristic of this process. Thus, this work aimed to characterize the effects of different contaminations on the electric arc behavior of the Wire Arc Additive Manufacturing process and the occurrence of microscopic defects in thin walls manufactured by this process. To investigate the presence of defects in the metal preforms, experimental conditions were used to promote the appearance of defects, such as the insertion of contaminants. To accomplish the electric arc behavior analysis, voltage and current temporal data were represented through histograms and cyclograms, and the arc stability was assessed based on the Vilarinho index for a short circuit. Effectively, the introduction of contaminants caused electric arc disturbances that led to the appearance of manufacturing defects, such as inclusions and porosities, observed through metallographic characterization. The results confirm that the introduction of contaminations could be identified early in the Wire Arc Additive Manufacturing process through electric arc data analysis.

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Section: Methodsmentioning

confidence: 99%

Effects of Contaminations on Electric Arc Behavior and Occurrence of Defects in Wire Arc Additive Manufacturing of 316L-Si Stainless Steel

Souto,

Lima,

Castro

et al. 2024

Metals

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“…They determined the ideal EP/EN ratio, which yielded optimal forming accuracy and ensured stable deposition, to be 13:7. Zhang et al [18] examined the metal transfer behavior and stability in the swing arc additive manufacturing of AZ91 magnesium alloy through the CMT process. They analyzed electrical waveforms, high-speed images of the weld pool, and forces acting on the droplet to achieve optimum parameters for stable deposition.…”

Section: Introductionmentioning

confidence: 99%

Effect of Current Waveforms during Directed Energy Deposition of 4043 Aluminum Alloy on Microstructure, Hardness, and Wear of Alloy

Ujjwal,

Anand Kumar,

Anand

et al. 2023

Materials

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Wire arc additive manufacturing (WAAM) was employed to fabricate 4043 aluminum alloy walls. To investigate the effects of sinusoidal, triangular, and rectangular waveforms of alternating current (AC) and their transients on the wall geometry, microstructure evolution, hardness, and wear properties were evaluated. The root mean square (RMS) current value was maximum for the rectangular and minimum for the triangular waveform. The section produced by the triangular waveform had the highest height-to-width ratio, indicating that this waveform can be a favorable choice for creating components using WAAM. The optical micrographs of the transverse cross-section of the printed sections revealed the grain structure produced with this waveform to be heterogeneous, having a columnar dendritic structure at the bottom and equiaxed at the top portion. The waveforms also had an impact on the hardness and wear characteristics of all the walls, which were attributed to their cooling rate.

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Effect of wire arc additive manufacturing parameters on geometric, hardness, and microstructure of 316LSi stainless steel preforms

de Lima,

da Silva Neto,

Maciel

et al. 2024

Int J Adv Manuf Technol

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Optimization of CMT Characteristic Parameters for Swing Arc Additive Manufacturing of AZ91 Magnesium Alloy Based on Process Stability Analysis

Cited by 3 publications

References 33 publications

Effects of Contaminations on Electric Arc Behavior and Occurrence of Defects in Wire Arc Additive Manufacturing of 316L-Si Stainless Steel

Effects of Contaminations on Electric Arc Behavior and Occurrence of Defects in Wire Arc Additive Manufacturing of 316L-Si Stainless Steel

Effect of Current Waveforms during Directed Energy Deposition of 4043 Aluminum Alloy on Microstructure, Hardness, and Wear of Alloy

Effect of wire arc additive manufacturing parameters on geometric, hardness, and microstructure of 316LSi stainless steel preforms

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