A mathematical model for gravity-induced distortion during liquid-phase sintering

Raman, R. V.; German, Randall M.

doi:10.1007/bf02663915

Cited by 44 publications

(17 citation statements)

References 12 publications

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“…Other deformation mechanisms, especially the effects of gravity and nonuniform density, are well studied and documented 1,4,5 . The significance of particle orientation has been reported in some of our recent studies, 2,3,6 and is now being fairly well understood.…”

Section: Introductionmentioning

confidence: 65%

Packing Structure of Particles in a Green Compact and Its Influence on Sintering Deformation

Tanaka

Kuwano

Uematsu

2007

Journal of the American Ceramic Society

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The anisotropy of the structure in a die-pressed compact was studied directly through detailed analysis by confocal scanning laser fluorescent micrographs. The use of confocal optics and an immersion liquid produced micrographs that represented the structure of a cross section at a certain depth along two directions: parallel and normal to the pressing direction. The network formed by particles in contact was analyzed by measuring the components of particle contact parallel and normal to the pressing direction in the green compact. Different values were obtained in the total components of particle contact for the horizontal and normal directions for the cross section parallel to the direction of pressing: the ratio between these values was 1.15. This suggests that there should be 15% more shrinkage in the direction parallel to pressing, at least during the initial stages of sintering when the particle geometry is preserved.

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Section: Introductionmentioning

confidence: 65%

Packing Structure of Particles in a Green Compact and Its Influence on Sintering Deformation

Tanaka

Kuwano

Uematsu

2007

Journal of the American Ceramic Society

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“…For materials, for which large differences between low‐ and high‐viscosity ‐phase densities can be present in the specimen, the gravitational settlement, and a final microstructural gradient can occur, as suggested in different works 21,46,48 . Considering the different viscosity between the two phases (low‐ and high‐viscosity) and the limited and the distance that the high‐viscosity phase can travel, the settling derived from the influence of the gravitational forces during the sintering can be described through the Stokes’ approach.…”

Section: Constitutive Model Of Sinteringmentioning

confidence: 99%

“…The driving mechanism and the effects on the microstructure of the grain migration are the object of many studies. 21,43,44,45,46,47,48,49 In the present work, the assumption proposed by German and Liu 48 is followed. In their study, the grain dispersion and contact engagement during liquid-phase sintering are considered to be the consequences of the action of the shear stresses induced by the specimen's reshaping.…”

Section: Solid Grain Settlementmentioning

confidence: 99%

“…For materials, for which large differences between low-and high-viscosity -phase densities can be present in the specimen, the gravitational settlement, and a final microstructural gradient can occur, as suggested in different works. 21,46,48 Considering the different viscosity between the two phases (low-and high-viscosity) and the limited and the distance that the high-viscosity phase can travel, the settling derived from the influence of the gravitational forces during the sintering can be described through the Stokes' approach. If the assumptions of the negligible edge effect and grain aggregation can be considered 47 then it is possible to use the Stokes' law for describing the settling velocity of a single grain at low Reynolds number and in an unbounded low-viscosity phase:…”

Section: Solid Grain Settlementmentioning

confidence: 99%

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Influence of gravity on sintering of 3D‐printed powder components

et al. 2021

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Present technologies of additive manufacturing (such as binder‐jetting, stereolithography, robocasting, etc.) of complex‐shape powder‐components necessitate fine‐tuning of sintering as applied to highly porous 3D‐printing products. The densification of low‐density, complex shapes requires control of the gravity‐related phenomena to ensure a nearly full and distortion‐free densification. The present study addresses these issues through the involvement of comprehensive finite element simulations, the determination of the additively manufactured powder specimens’ sintering behavior, and the experimental validation of the developed models describing sintering of 3D‐printed objects. The paper describes the application of a numerical approach based on continuum mechanics‐based modeling of the gravity‐induced distortions during sintering of 3D‐printed powder components. The validation of the model is conducted through the comparison with the experimental results obtained for the sintering of the beam‐shape components printed using ceramic stereolithography technology. A practical semi‐analytical criterion, which can be used for sintered 3D‐printed parts’ design recommendations applicable to various material systems, is derived. Based on the obtained design criterion, a design map is developed indicating the allowable 3D‐printed elements’ configurations enabling the avoidance of the excessive gravity‐induced shape distortions.

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“…This general pathway (second phase precipitation facilitating more rapid mass transport) is conceptually similar to what happens in liquid phase sintering and supersolidus liquid phase sintering [3][4][5][6][7][8][9][10] , but importantly, in NPSS all of this structural evolution occurs completely in the solid state. NPSS therefore avoids the slumping that can occur in some liquid phase sintering systems, and can be used to free-sinter complex green geometries [11][12][13][14] . This provides an advantage to additive manufacturing techniques such as binder jet printing, by maintaing high dimensional tolerences of the as-printed geometry [13,15,16] .…”

Section: -Introductionmentioning

confidence: 99%

The Structural Evolution and Densification Mechanisms of Nanophase Separation Sintering

Oliver

Schuh

2021

Metall Mater Trans A

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A mathematical model for gravity-induced distortion during liquid-phase sintering

Cited by 44 publications

References 12 publications

Packing Structure of Particles in a Green Compact and Its Influence on Sintering Deformation

Packing Structure of Particles in a Green Compact and Its Influence on Sintering Deformation

Influence of gravity on sintering of 3D‐printed powder components

The Structural Evolution and Densification Mechanisms of Nanophase Separation Sintering

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