Insights into the mechanical properties of several triply periodic minimal surface lattice structures made by polymer additive manufacturing

Three-dimensional lattices have applications across a range of fields including structural lightweighting, impact absorption and biomedicine. In this work, lattices based on triply periodic minimal surfaces were produced by polymer additive manufacturing and examined with a combination of experiment...

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Bibliographic Details
Published in:Polymer (Guilford) Vol. 152; pp. 62 - 71
Main Authors: Maskery, I., Sturm, L., Aremu, A.O., Panesar, A., Williams, C.B., Tuck, C.J., Wildman, R.D., Ashcroft, I.A., Hague, R.J.M.
Format: Journal Article
Language:English
Published: Kidlington Elsevier Ltd 12.09.2018
Elsevier BV
Subjects:
Additive manufacturing
Biomedical materials
Cellular solid
Computer applications
Deformation
Deformation mechanisms
Diamonds
Finite element method
Laser sintering
Lattice
Lattice theory
Lattices (mathematics)
Mechanical properties
Minimal surfaces
Modulus of elasticity
Polymers
Selective laser sintering
Triply periodic minimal surface
Selective laser sintering
Cellular solid
Additive manufacturing
Lattice
Triply periodic minimal surface
ISSN:0032-3861, 1873-2291
Online Access:Get full text
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Summary:Three-dimensional lattices have applications across a range of fields including structural lightweighting, impact absorption and biomedicine. In this work, lattices based on triply periodic minimal surfaces were produced by polymer additive manufacturing and examined with a combination of experimental and computational methods. This investigation elucidates their deformation mechanisms and provides numerical parameters crucial in establishing relationships between their geometries and mechanical performance. Three types of lattice were examined, with one, known as the primitive lattice, being found to have a relative elastic modulus over twice as large as those of the other two. The deformation process of the primitive lattice was also considerably different from those of the other two, exhibiting strut stretching and buckling, while the gyroid and diamond lattices deformed in a bending dominated manner. Finite element predictions of the stress distributions in the lattices under compressive loading agreed with experimental observations. These results can be used to create better informed lattice designs for a range of mechanical and biomedical applications. [Display omitted] •Manufactured and tested lattice structures based on triply periodic minimal surfaces.•Lattices with equivalent masses deform differently depending on their cell geometry.•High stiffness seen for the structure which showed buckling and low failure strain.•Determined Gibson-Ashby factors enabling the design of optimised latticed components.
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ISSN:0032-3861
1873-2291
DOI:10.1016/j.polymer.2017.11.049