Mechanical performance of additively manufactured lightweight cellular solids: Influence of cell pattern and relative density on the printing time and compression behavior
Other authors
Publication date
2022-03ISSN
1873-4197
Abstract
A comprehensive investigation is presented on the Fused Filament Fabrication (FFF) technology’s possibilities to create cellular solids with a broad spectrum of specific stiffness and strength, modifying cell geometry and size, while addressing manufacturing matters such as inherent defects and built time. Thirteen typologies of two-dimensional cellular patterns with different relative densities are examined. Results have allowed conclusions to be drawn regarding the influence of cell type and infill density on mechanical performance. Intra-layer and inter-layer inherent defects identified after manufacturing highlight the importance of optimizing filament trajectories. A reliable comparison of the elastic properties of the cellular patterns as a function of their density is presented. An experimentally validated numerical model is provided for predicting the compression stiffness of the different cell patterns with an average deviation below 5%. The model can reproduce the behavior in the elastic range based on tensile specimen properties and a Normal Stiffness Factor to account for the phenomenon of elastic asymmetry of the FFF printed samples. The wide range of results achieved is experimental confirmation of the potential of FFF cellular solids. Lastly, this investigation provides analytical, numerical, and empirical validated evidence to further design-for-additive manufacturing strategies with cellular solids for designing advanced lightweight structures.
Document Type
Article
Document version
Published version
Language
English
Subject (CDU)
66 - Chemical technology. Chemical and related industries
Keywords
Cellular structures
Additive manufacturing
Fused filament fabrication
Cell pattern
Relative density
Mechanical performance
Impressió 3D
Fabricació additiva
Pages
p.16
Publisher
Elsevier
Is part of
Materials & Design Volume 2022, 215, 110474
Grant agreement number
info:eu-repo/grantAgreement/MCIU/PN I+D/RTI2018-099754-A-I00
info:eu-repo/grantAgreement/ACCIÓ/Llavor/COMRDI16-1-0010
This item appears in the following Collection(s)
Rights
© L'autor/a
Except where otherwise noted, this item's license is described as http://creativecommons.org/licenses/by-nc-nd/4.0/