Infill Geometry Influence on Tensile Strength for FDM 3d Printed Parts in Four Different Materials

Anca-Simona Horvath, Elena Peri, Jeremie Pierre Gay

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningpeer review

Resumé

The purpose of this study is to compare mechanical behaviour in relation to geometric material distribution in 3d printed objects and gain a better understanding on the impact of geometric shape rather than material in the behaviour of a part. Little work has been done in relation to objects produced using FDM desktop 3d printers. Test the following interior geometries are tested: linear (bidimensional), crossed (bidimensional), hexagonal (bidimensional), triangular (bidimensional), modified isomax, truncated octahedron, gyroid lattice, gyroid skeleton, double gyroid, D-Surface, P-Surface, Lidinoid, SplitP, Neovius, skeletal graphs.
OriginalsprogEngelsk
TidsskriftJournal of Membrane Science
ISSN0376-7388
StatusUnder udarbejdelse - 2019

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Frequency division multiplexing
Tensile Strength
Skeleton
tensile strength
Tensile strength
3D printers
printers
Geometry
geometry
musculoskeletal system
Three Dimensional Printing

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Infill Geometry Influence on Tensile Strength for FDM 3d Printed Parts in Four Different Materials. / Horvath, Anca-Simona; Peri, Elena; Pierre Gay, Jeremie.

I: Journal of Membrane Science, 2019.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningpeer review

TY - JOUR

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AU - Peri, Elena

AU - Pierre Gay, Jeremie

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AB - The purpose of this study is to compare mechanical behaviour in relation to geometric material distribution in 3d printed objects and gain a better understanding on the impact of geometric shape rather than material in the behaviour of a part. Little work has been done in relation to objects produced using FDM desktop 3d printers. Test the following interior geometries are tested: linear (bidimensional), crossed (bidimensional), hexagonal (bidimensional), triangular (bidimensional), modified isomax, truncated octahedron, gyroid lattice, gyroid skeleton, double gyroid, D-Surface, P-Surface, Lidinoid, SplitP, Neovius, skeletal graphs.

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JO - Journal of Membrane Science

JF - Journal of Membrane Science

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