TY - JOUR
T1 - Mechanical properties and energy absorption characteristics of additively manufactured lightweight novel re-entrant plate-based lattice structures
AU - Hassanieh, Sultan Al
AU - Alhantoobi, Ahmed
AU - Khan, Kamran A.
AU - Khan, Muhammad A.
N1 - Funding Information:
Funding: This research was funded by the Abu Dhabi Award for Research Excellence (AARE-2019) under project number 8434000349/AARE19-232.
Funding Information:
Acknowledgments: This publication is based on work supported by the Abu Dhabi Award for Research Excellence (AARE-2019) under project number 8434000349/AARE19-232.
Publisher Copyright:
© 2021 by the authors. Licensee MDPI, Basel, Switzerland.
PY - 2021/11/1
Y1 - 2021/11/1
N2 - In this work, three novel re-entrant plate lattice structures (LSs) have been designed by transforming conventional truss-based lattices into hybrid-plate based lattices, namely, flat-plate modified auxetic (FPMA), vintile (FPV), and tesseract (FPT). Additive manufacturing based on stereolithography (SLA) technology was utilized to fabricate the tensile, compressive, and LS specimens with different relative densities (ρ). The base material’s mechanical properties obtained through mechanical testing were used in a finite element-based numerical homogenization analysis to study the elastic anisotropy of the LSs. Both the FPV and FPMA showed anisotropic behavior; however, the FPT showed cubic symmetry. The universal anisotropic index was found highest for FPV and lowest for FPMA, and it followed the power-law dependence of ρ. The quasi-static compressive response of the LSs was investigated. The Gibson–Ashby power law (≈ρn) analysis revealed that the FPMA’s Young’s modulus was the highest with a mixed bending–stretching behavior (≈ρ1.30 ), the FPV showed a bending-dominated behavior (≈ρ3.59 ), and the FPT showed a stretching-dominated behavior (≈ρ1.15 ). Excellent mechanical properties along with superior energy absorption capabilities were observed, with the FPT showing a specific energy absorption of 4.5 J/g, surpassing most reported lattices while having a far lower density.
AB - In this work, three novel re-entrant plate lattice structures (LSs) have been designed by transforming conventional truss-based lattices into hybrid-plate based lattices, namely, flat-plate modified auxetic (FPMA), vintile (FPV), and tesseract (FPT). Additive manufacturing based on stereolithography (SLA) technology was utilized to fabricate the tensile, compressive, and LS specimens with different relative densities (ρ). The base material’s mechanical properties obtained through mechanical testing were used in a finite element-based numerical homogenization analysis to study the elastic anisotropy of the LSs. Both the FPV and FPMA showed anisotropic behavior; however, the FPT showed cubic symmetry. The universal anisotropic index was found highest for FPV and lowest for FPMA, and it followed the power-law dependence of ρ. The quasi-static compressive response of the LSs was investigated. The Gibson–Ashby power law (≈ρn) analysis revealed that the FPMA’s Young’s modulus was the highest with a mixed bending–stretching behavior (≈ρ1.30 ), the FPV showed a bending-dominated behavior (≈ρ3.59 ), and the FPT showed a stretching-dominated behavior (≈ρ1.15 ). Excellent mechanical properties along with superior energy absorption capabilities were observed, with the FPT showing a specific energy absorption of 4.5 J/g, surpassing most reported lattices while having a far lower density.
KW - Additive manufacturing
KW - Compression response
KW - Energy absorption
KW - Plate lattice
KW - Resin
KW - Stereolithography (SLA)
UR - http://www.scopus.com/inward/record.url?scp=85119299267&partnerID=8YFLogxK
U2 - 10.3390/polym13223882
DO - 10.3390/polym13223882
M3 - Article
AN - SCOPUS:85119299267
SN - 2073-4360
VL - 13
JO - Polymers
JF - Polymers
IS - 22
M1 - 3882
ER -
