Sintering phenomena and mechanical strength of nickel based materials in direct metal laser sintering process—a molecular dynamics study

Zhang, Yi; Zhang, Jing

doi:10.1557/jmr.2016.230

Cited by 45 publications

(12 citation statements)

References 19 publications

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“…In order to determine lattice diffusion coefficient, Dv, in equation 4, the mean square displacement (MSD) is calculated using the following equation [23,24]:…”

Section: Analytical Model For Resistivity Predicationmentioning

confidence: 99%

Molecular dynamics simulation of electrical resistivity in sintering process of nanoparticle silver inks

Zhang

Guo

et al. 2016

Computational Materials Science

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A molecular dynamics (MD) model is developed to simulate low temperature sintering of silver nanoparticles and resultant resistivity. Due to the high surface to volume ratio, nanoparticle silver inks can sinter at low thermal curing temperatures, which are used in intense pulsed light (IPL) sintering process. In this study, the configurational change of nanoparticle silver during sintering is studied using the MD model. Then the resultant electric resistivity is calculated using the Reimann-Weber formula. The simulation results show that the resistivity decreases rapidly in the initial sintering stage, due to the fast neck formation and growth. Additionally, the predicted temperature-dependent resistivity evolutions are in good agreement with both experimental measurements and analytical sintering model, indicating that the resistivity decreases with increasing sintering temperature. The model provides a design tool for optimizing IPL process.

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“…In order to determine lattice diffusion coefficient, Dv, in equation 4, the mean square displacement (MSD) is calculated using the following equation [23,24]:…”

Section: Analytical Model For Resistivity Predicationmentioning

confidence: 99%

Molecular dynamics simulation of electrical resistivity in sintering process of nanoparticle silver inks

Zhang

Guo

et al. 2016

Computational Materials Science

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“…In [6], the author studied the effect of processing parameters on the densification and microstructural evolution during direct laser sintering of metal powders. The sintering process and the resultant mechanical strength of nickel nanoparticles were studied in the paper [7] using molecular dynamics simulations. In work [8], the size and volume fraction of SiCp have been varied to analyse the crack and wear behaviour of the Al-based composite.…”

Section: Introductionmentioning

confidence: 99%

An Analysis of the Surface Geometric Structure and Geometric Accuracy of Cylindrical Gear Teeth Manufactured with the Direct Metal Laser Sintering (DMLS) Method

Pisula¹,

Budzik²,

Przeszłowski³

2019

SV-JME

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This paper presents findings concerning the accuracy of the geometry of cylindrical spur gear teeth manufactured with the direct metal laser sintering (DMLS) method. In addition, the results of the evaluation of the tooth surface geometric structure are presented in the form of selected two-dimensional and three-dimensional surface roughness parameters. An analysis of the accuracy of the fabricated gear teeth was performed after gear sand-blasting and gear tooth milling processes. Surface roughness was measured before and after sand-blasting and gear tooth milling. The test gear wheel was manufactured from GP1 high-chromium stainless steel on an EOS M270 machine.

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“…Different from the traditional welding models, the geometrical irregularity of the sintered powder often causes more complicated temperature distribution and unstable fluid flow [12][13][14]. The powder melting process, as well as the driving forces for fluid flow, have been studied by numerous papers [5,10,[14][15][16].…”

Section: Introductionmentioning

confidence: 99%

Modeling of solidification microstructure evolution in laser powder bed fusion fabricated 316L stainless steel using combined computational fluid dynamics and cellular automata

Zhang

2019

Additive Manufacturing

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This work presents a novel modeling framework combining computational fluid dynamics (CFD) and cellular automata (CA), to predict the solidification microstructure evolution of laser powder bed fusion (PBF) fabricated 316L stainless steel. A CA model is developed which is based on the modified decentered square method to improve computational efficiency. Using this framework, the fluid dynamics of the melt pool flow in the laser melting process is found to be mainly driven by the competing Marangoni force and the recoil pressure on the liquid metal surface. Evaporation occurs at the front end of the laser spot. The initial high temperature occurs in the center of the laser spot. However, due to Marangoni force, which drives high-temperature liquid flowing to low-temperature region, the highest temperature region shifts to the front side of the laser spot where evaporation occurs. Additionally, the recoil pressure pushes the liquid metal downward to form a depression zone. The simulated melt pool depths are compared well with the experimental data. Additionally, the simulated solidification microstructure using the CA model is in a good agreement with the experimental observation. The simulations show that

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Sintering phenomena and mechanical strength of nickel based materials in direct metal laser sintering process—a molecular dynamics study

Cited by 45 publications

References 19 publications

Molecular dynamics simulation of electrical resistivity in sintering process of nanoparticle silver inks

Molecular dynamics simulation of electrical resistivity in sintering process of nanoparticle silver inks

An Analysis of the Surface Geometric Structure and Geometric Accuracy of Cylindrical Gear Teeth Manufactured with the Direct Metal Laser Sintering (DMLS) Method

Modeling of solidification microstructure evolution in laser powder bed fusion fabricated 316L stainless steel using combined computational fluid dynamics and cellular automata

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