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

Anca-Simona Horvath; Elena Peri; Jeremie Pierre Gay

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 tidsskrift › Tidsskriftartikel › Forskning › peer 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.

Originalsprog	Engelsk
Tidsskrift	Journal of Membrane Science
ISSN	0376-7388
Status	Under udarbejdelse - 2019

Fingerprint

Frequency division multiplexing

Tensile Strength

Skeleton

tensile strength

Tensile strength

3D printers

printers

Geometry

geometry

musculoskeletal system

Three Dimensional Printing

Citer dette

Horvath, A-S., Peri, E., & Pierre Gay, J. (2019). Infill Geometry Influence on Tensile Strength for FDM 3d Printed Parts in Four Different Materials. Manuskript under forberedelse.

Horvath, Anca-Simona ; Peri, Elena ; Pierre Gay, Jeremie. / Infill Geometry Influence on Tensile Strength for FDM 3d Printed Parts in Four Different Materials. I: Journal of Membrane Science. 2019.

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

abstract = "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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Horvath, A-S , Peri, E & Pierre Gay, J 2019, 'Infill Geometry Influence on Tensile Strength for FDM 3d Printed Parts in Four Different Materials', Journal of Membrane Science.

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 tidsskrift › Tidsskriftartikel › Forskning › peer review

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T1 - Infill Geometry Influence on Tensile Strength for FDM 3d Printed Parts in Four Different Materials

AU - Horvath, Anca-Simona

AU - Peri, Elena

AU - Pierre Gay, Jeremie

PY - 2019

Y1 - 2019

N2 - 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.

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

SN - 0376-7388

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Horvath A-S , Peri E, Pierre Gay J. Infill Geometry Influence on Tensile Strength for FDM 3d Printed Parts in Four Different Materials. Journal of Membrane Science. 2019.