Approximation of the Mechanical Response of Large Lattice Domains Using Homogenization and Design of Experiments

Abstract: Lattice-based workpieces contain patterned repetition of individuals of a basic topology (Schwarz, ortho-walls, gyroid, etc.) with each individual having distinct geometric grading. In the context of the design, analysis and manufacturing of lattice workpieces, the problem of rapidly assessing the mechanical behavior of large domains is relevant for pre-evaluation of designs. In this realm, two approaches can be identified: (1) numerical simulations which usually bring accuracy but limit the size of the domain… Show more

“…Several studies [8][9][10] have experimentally and/or numerically explored the structural response of metal-or polymer-based strut-and surface-based lattices, however only a few scrutinized FGLs [2,11,12]. To-date, finite element analyses of these structures have primarily focused on their elastic behaviour, despite lattice materials and FGLs offering great advantages over monolithic materials in terms of specific energy absorption [5], which is considerably high during their plastic response.…”

“…The authors observed a good agreement of the FEN model with the experimental data. Besides the explicit geometric models, the homogenisation approach [12,[15][16][17][18][19] served as a computationally efficient alternative to determine the equivalent effective properties of a heterogeneous lattice. In [17,19], it was coupled with the modified Hill yield criterion and showed good agreement for variable density and surface-based lattices.…”

Predictions of the Elastic–Plastic Compressive Response of Functionally Graded Polymeric Composite Lattices Manufactured by Three-Dimensional Printing

“…Several studies [8][9][10] have experimentally and/or numerically explored the structural response of metal-or polymer-based strut-and surface-based lattices, however only a few scrutinized FGLs [2,11,12]. To-date, finite element analyses of these structures have primarily focused on their elastic behaviour, despite lattice materials and FGLs offering great advantages over monolithic materials in terms of specific energy absorption [5], which is considerably high during their plastic response.…”

“…The authors observed a good agreement of the FEN model with the experimental data. Besides the explicit geometric models, the homogenisation approach [12,[15][16][17][18][19] served as a computationally efficient alternative to determine the equivalent effective properties of a heterogeneous lattice. In [17,19], it was coupled with the modified Hill yield criterion and showed good agreement for variable density and surface-based lattices.…”

Predictions of the Elastic–Plastic Compressive Response of Functionally Graded Polymeric Composite Lattices Manufactured by Three-Dimensional Printing