A Numerical Study of Diffusion of Nanoparticles in a Viscous Medium During Solidification

Rahman, Kazi Mahmudur; Amin, M. Ruhul; Mian, Ahsan

doi:10.1115/1.4041349

Cited by 2 publications

(1 citation statement)

References 40 publications

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“…The images of the transverse and longitudinal surfaces of the specimens numbered "1" were shown in (Figure 3). The pores based on gases were become large and their fraction has increased because the molten pool flow dynamics have increased through the highest energy input [8][9][10][11][12]. The larger pores were greater the buoyancy in the molten pool.…”

Section: Porosity Analysismentioning

confidence: 99%

Effect of Energy Input on Porosity and Microhardness in Laser Cladding Coating on Fgs600-3a Ductile Cast Iron

KARŞI¹,

Altay

ERGİN³

et al. 2022

METAL 2022 Conference Proeedings

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Laser cladding, which is surface modification technology, is based on melting with a laser beam by spraying powder on the base metal and generated by depositing the layers. In this study, the Metco 42C martensitic stainless steel powder material was cladded on the FGS600-3A ductile cast iron used in sheet metal forming molds. The effect of energy input on porosity and microhardness was investigated. The digital image processing method was used for porosity analysis. The energy input had a significant effect on the pore formation. The lower energy input (1.1 kW laser power, 14 mm/s scanning speed) resulted in lower porosity. The cladding thickness varied depending on the scanning speed parameter due to affecting powder efficiency, high thickness was obtained at 6 mm/s low scanning speed. In the upper layer of the cladding, high hardness values were achieved due to the martensitic phase formation. The bottom layers of cladding had lower hardness values because of the tempering of the hard martensitic phases by subsequent cladding processes. Significant increase in hardness at cladding zone was attributed to carbon transfer from the base metal. This remarkable increase in hardness was much higher at lowest energy input (1.1 kW laser power and 14 mm/s scanning speed). However, it is clear that this will increase the risk of crack formation because of brittleness. On the other hand, at the higher energy input, this significant increase in hardness is at a lower level due to rest-austenite formation and excessive annealing with subsequent cladding processes.

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Section: Porosity Analysismentioning

confidence: 99%

Effect of Energy Input on Porosity and Microhardness in Laser Cladding Coating on Fgs600-3a Ductile Cast Iron

KARŞI¹,

Altay

ERGİN³

et al. 2022

METAL 2022 Conference Proeedings

View full text Add to dashboard Cite

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A Numerical Model of Microstructure Formation Considering Nanoparticle Distribution During Selective Laser Melting Process

Alam,

Amin

2024

Journal of Manufacturing Science and Engineering

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Selective laser melting (SLM) is a popular metal additive manufacturing technique that allows the development of new metal matrix nanocomposites by fusing metallic powders with nanoparticles. In the current study, a novel numerical model was proposed to simulate microstructure formation considering local nanoparticle distribution during the SLM process. The proposed model formulates a three-dimensional computational fluid dynamics (CFD) model with Lagrangian particle tracking to simulate a single-track, single-layer SLM process of aluminum alloy reinforced with TiB2 nanoparticles in ANSYS FLUENT. A very low weight fraction (0.0009%) of nanoparticles was considered due to the computational limitations of the software package. The temperature distribution and particle distribution results calculated by the 3D CFD model were one-way coupled with a 2D Cellular Automata (CA) model to predict the solidified microstructure using MATLAB. The coupled CFD-CA model and Lagrangian particle tracking were separately validated in this study. The result showed that the nanoparticles move along the recirculation zones generated by the Marangoni and natural convection in the molten pool fluid. The microstructure predicted by this model showed that the introduction of the nanoparticles increased bulk nucleation during solidification. It disrupted columnar grain growth by promoting small, randomly oriented equiaxed grains. The average grain diameter decreased by 40% when nanoparticles were present compared to microstructures without nanoparticles.

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A Numerical Study of Diffusion of Nanoparticles in a Viscous Medium During Solidification

Cited by 2 publications

References 40 publications

Effect of Energy Input on Porosity and Microhardness in Laser Cladding Coating on Fgs600-3a Ductile Cast Iron

Effect of Energy Input on Porosity and Microhardness in Laser Cladding Coating on Fgs600-3a Ductile Cast Iron

A Numerical Model of Microstructure Formation Considering Nanoparticle Distribution During Selective Laser Melting Process

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