TY - JOUR
T1 - Bending behavior of octet-truss lattice structures
T2 - Modelling options, numerical characterization and experimental validation
AU - Korshunova, N.
AU - Alaimo, G.
AU - Hosseini, S. B.
AU - Carraturo, M.
AU - Reali, A.
AU - Niiranen, J.
AU - Auricchio, F.
AU - Rank, E.
AU - Kollmannsberger, S.
N1 - Publisher Copyright:
© 2021 The Author(s)
PY - 2021/7
Y1 - 2021/7
N2 - Selective Laser Melting (SLM) technology has undergone significant development in the past years providing unique flexibility for the fabrication of complex metamaterials such as octet-truss lattices. However, the microstructure can exhibit significant variations due to the high complexity of the manufacturing process. Consequently, the mechanical behavior, in particular, linear elastic response, of these lattices is strongly dependent on the process-induced defects, raising the importance on the incorporation of as-manufactured geometries into the computational structural analysis. This, in turn, challenges the traditional mesh-conforming methods making the computational costs prohibitively large. In the present work, an immersed image-to-analysis framework is applied to efficiently evaluate the bending behavior of AM lattices. To this end, we employ the Finite Cell Method (FCM) to perform a three-dimensional numerical analysis of the three-point bending test of a lattice structure and compare the as-designed to as-manufactured effective properties. Furthermore, we undertake a comprehensive study on the applicability of dimensionally reduced beam models to the prediction of the bending behavior of lattice beams and validate classical and strain gradient beam theories applied in combination with the FCM. The numerical findings suggest that the octet-truss lattices exhibit size effects, thus, requiring a flexible framework to incorporate high-order continuum theories.
AB - Selective Laser Melting (SLM) technology has undergone significant development in the past years providing unique flexibility for the fabrication of complex metamaterials such as octet-truss lattices. However, the microstructure can exhibit significant variations due to the high complexity of the manufacturing process. Consequently, the mechanical behavior, in particular, linear elastic response, of these lattices is strongly dependent on the process-induced defects, raising the importance on the incorporation of as-manufactured geometries into the computational structural analysis. This, in turn, challenges the traditional mesh-conforming methods making the computational costs prohibitively large. In the present work, an immersed image-to-analysis framework is applied to efficiently evaluate the bending behavior of AM lattices. To this end, we employ the Finite Cell Method (FCM) to perform a three-dimensional numerical analysis of the three-point bending test of a lattice structure and compare the as-designed to as-manufactured effective properties. Furthermore, we undertake a comprehensive study on the applicability of dimensionally reduced beam models to the prediction of the bending behavior of lattice beams and validate classical and strain gradient beam theories applied in combination with the FCM. The numerical findings suggest that the octet-truss lattices exhibit size effects, thus, requiring a flexible framework to incorporate high-order continuum theories.
KW - Additive manufacturing
KW - Beam theories
KW - Computed tomography
KW - Finite Cell Method
KW - Finite Element Method
KW - Metamaterials
KW - Octet-truss lattice
KW - Strain gradient elasticity
UR - http://www.scopus.com/inward/record.url?scp=85104984729&partnerID=8YFLogxK
U2 - 10.1016/j.matdes.2021.109693
DO - 10.1016/j.matdes.2021.109693
M3 - Article
AN - SCOPUS:85104984729
SN - 0264-1275
VL - 205
JO - Materials and Design
JF - Materials and Design
M1 - 109693
ER -