Increased Strength of 3D Printed Parts With Z-Pin Approach

Clemon, L; Christopher, K

Increased Strength of 3D Printed Parts With Z-Pin Approach

Clemon, L

Christopher, K

Permalink

Publisher:: ASME
Publication Type:: Conference Proceeding
Citation:: ASME International Mechanical Engineering Congress and Exposition, Proceedings (IMECE), 2021, 2A-2021
Issue Date:: 2021-01-01

Closed Access

	Filename	Description	Size
	v02at02a002-imece2021-67743.pdf	Published version	4.53 MB	Adobe PDF	View/Open

Copyright Clearance Process

Recently Added
In Progress
Closed Access

This item is closed access and not available.

Full metadata record

Field	Value	Language
dc.contributor.author	Clemon, L https://orcid.org/0000-0003-3808-7749
dc.contributor.author	Christopher, K
dc.date	2021-11-01
dc.date.accessioned	2022-06-10T06:30:19Z
dc.date.available	2022-06-10T06:30:19Z
dc.date.issued	2021-01-01
dc.identifier.citation	ASME International Mechanical Engineering Congress and Exposition, Proceedings (IMECE), 2021, 2A-2021
dc.identifier.isbn	9780791885550
dc.identifier.uri	http://hdl.handle.net/10453/158068
dc.description.abstract	Current extrusion-based 3D printing technologies adopt a layer-by-layer material deposition approach which is equivalent to stacking layers of material. This traditional 2.5D deposition plan is limited to depositing discrete, cross-sectional layers of the model. Such stacked layers are well known to induce anisotropic material behavior subject to part orientation during fabrication. Parts are loaded in their build direction (perpendicularly to layers), have up to a 50% decrease in tensile strength, and a significant 95% decrease in toughness when compared to x-y plane loading. In this work, we adopt a z-pinning approach inspired by traditional composite manufacturing methods to create cross-layer pins for part reinforcement. Our z-pins aim to reinforce the weaker interfaces between 3D printed layers, by facilitating stronger layer adhesion and by obstructing crack propagation through the planar structure of traditional 3D prints. This adaptation of the pin reinforcement concept for 3D printing is implemented on a consumer-grade Fused Filament Fabrication machine without the need for additional hardware. The fabrication machine is a standard linear 3-axis gantry design with off-the-shelf components. We create a custom workflow for editing the part mesh and toolpath plan that is inserted in the workflow between open-source slicing of the part file and part fabrication by the machine. This reads and edits the g-code instructions to insert the z-pin reinforcements into the existing deposition plan. A total of thirty-six tensile and flexural test specimens were fabricated using Polylactic Acid filament (PLA). The depth of the reinforcement pins, pin spacing, infill percentage, and the orientation of the build are perturbed to evaluate the effectiveness of the method. Tests were conducted on a calibrated Instron ElectroPuls E10000 using standard rectilinear test sample geometries. Test results show pinned tensile components exhibited up to a 25% increase in failure stress and a 300% increase in toughness when compared to the non-pinned control samples for the traditionally weak direction. Flexural strength was not significantly altered on a per-mass normalised comparison. The increase in strength is attributed to increased bonding across layers due to the added pins and abatement of delamination cracks propagating along layer boundaries. Abatement of delamination as a failure mode changes the material rupture mode to more of a desired ductile fracture of the polymer at the z-pin sites and delamination elsewhere in the plane. The results of this work provide a pathway to optimisation of material extrusion properties for anisotropic and isotropic designs by adjusting the quantity and location of z-pin reinforcements.
dc.language	en
dc.publisher	ASME
dc.relation.ispartof	ASME International Mechanical Engineering Congress and Exposition, Proceedings (IMECE)
dc.relation.ispartof	International Mechanical Engineering Congress and Exposition
dc.relation.isbasedon	10.1115/IMECE2021-67743
dc.rights	info:eu-repo/semantics/closedAccess
dc.title	Increased Strength of 3D Printed Parts With Z-Pin Approach
dc.type	Conference Proceeding
utslib.citation.volume	2A-2021
utslib.location.activity	Virtual, Online
pubs.organisational-group	/University of Technology Sydney
pubs.organisational-group	/University of Technology Sydney/Faculty of Engineering and Information Technology
pubs.organisational-group	/University of Technology Sydney/Faculty of Engineering and Information Technology/School of Mechanical and Mechatronic Engineering
utslib.copyright.status	closed_access	*
pubs.consider-herdc	false
dc.date.updated	2022-06-10T06:30:16Z
pubs.finish-date	2021-11-05
pubs.place-of-publication	USA
pubs.publication-status	Published
pubs.start-date	2021-11-01
pubs.volume	2A-2021
dc.location	USA

Abstract:

Current extrusion-based 3D printing technologies adopt a layer-by-layer material deposition approach which is equivalent to stacking layers of material. This traditional 2.5D deposition plan is limited to depositing discrete, cross-sectional layers of the model. Such stacked layers are well known to induce anisotropic material behavior subject to part orientation during fabrication. Parts are loaded in their build direction (perpendicularly to layers), have up to a 50% decrease in tensile strength, and a significant 95% decrease in toughness when compared to x-y plane loading. In this work, we adopt a z-pinning approach inspired by traditional composite manufacturing methods to create cross-layer pins for part reinforcement. Our z-pins aim to reinforce the weaker interfaces between 3D printed layers, by facilitating stronger layer adhesion and by obstructing crack propagation through the planar structure of traditional 3D prints. This adaptation of the pin reinforcement concept for 3D printing is implemented on a consumer-grade Fused Filament Fabrication machine without the need for additional hardware. The fabrication machine is a standard linear 3-axis gantry design with off-the-shelf components. We create a custom workflow for editing the part mesh and toolpath plan that is inserted in the workflow between open-source slicing of the part file and part fabrication by the machine. This reads and edits the g-code instructions to insert the z-pin reinforcements into the existing deposition plan. A total of thirty-six tensile and flexural test specimens were fabricated using Polylactic Acid filament (PLA). The depth of the reinforcement pins, pin spacing, infill percentage, and the orientation of the build are perturbed to evaluate the effectiveness of the method. Tests were conducted on a calibrated Instron ElectroPuls E10000 using standard rectilinear test sample geometries. Test results show pinned tensile components exhibited up to a 25% increase in failure stress and a 300% increase in toughness when compared to the non-pinned control samples for the traditionally weak direction. Flexural strength was not significantly altered on a per-mass normalised comparison. The increase in strength is attributed to increased bonding across layers due to the added pins and abatement of delamination cracks propagating along layer boundaries. Abatement of delamination as a failure mode changes the material rupture mode to more of a desired ductile fracture of the polymer at the z-pin sites and delamination elsewhere in the plane. The results of this work provide a pathway to optimisation of material extrusion properties for anisotropic and isotropic designs by adjusting the quantity and location of z-pin reinforcements.

Please use this identifier to cite or link to this item:

http://hdl.handle.net/10453/158068