Additively manufactured structures can be tailor-made to optimally distribute mechanical loads while remaining light-weight. To efficiently analyze the locally unique mechanical behavior of structures made from a large number of small lattice cells, a strategy which employs neural networks and deep learning to predict the maximum stresses in the realm of linear elasto-plasticity of a detail-level finite-element model is presented. The strategy is demonstrated on a single lattice cell specimen. Good agreements between experimental, finite element and neural network results are found at a significant reduction in computation time
Constitutive modeling of nonlinear materials is a computationally complex and time-intensive process...
Herein, we propose a new lattice generation strategy that is computationally cheaper and produces hi...
The drive to reduce material usage and improve properties of structures has led to additive manufa...
Cellular structures are lightweight-engineered materials that have gained much attention with the de...
Extensive amount of research on additively manufactured (AM) lattice structures has been made to dev...
Lattice cell structures (LCS) are being investigated for applications in sandwich composites. To obt...
This paper investigates the structure-property relations of thin-walled lattices under dynamic longi...
Abstract We propose a deep neural network (DNN) as a fast surrogate model for local stress calculati...
In mechanics and engineering, the Finite Element Method (FEM) represents the predominant numerical s...
Mechanical metamaterials such as open- and closed-cell lattice structures, foams, composites, and so...
In the current work, the mechanical response of multiscale cellular materials with hollow variable-s...
Abstract Developing accurate yet fast computational tools to simulate complex physical phenomena is ...
A sequential nonlinear multiscale method for the simulation of elastic metamaterials subject to larg...
Metamaterials are a group of materials with artificial engineered structures that exhibits customize...
In a concurrent (FE2) multiscale modeling is an increasingly popular approach for modeling complex m...
Constitutive modeling of nonlinear materials is a computationally complex and time-intensive process...
Herein, we propose a new lattice generation strategy that is computationally cheaper and produces hi...
The drive to reduce material usage and improve properties of structures has led to additive manufa...
Cellular structures are lightweight-engineered materials that have gained much attention with the de...
Extensive amount of research on additively manufactured (AM) lattice structures has been made to dev...
Lattice cell structures (LCS) are being investigated for applications in sandwich composites. To obt...
This paper investigates the structure-property relations of thin-walled lattices under dynamic longi...
Abstract We propose a deep neural network (DNN) as a fast surrogate model for local stress calculati...
In mechanics and engineering, the Finite Element Method (FEM) represents the predominant numerical s...
Mechanical metamaterials such as open- and closed-cell lattice structures, foams, composites, and so...
In the current work, the mechanical response of multiscale cellular materials with hollow variable-s...
Abstract Developing accurate yet fast computational tools to simulate complex physical phenomena is ...
A sequential nonlinear multiscale method for the simulation of elastic metamaterials subject to larg...
Metamaterials are a group of materials with artificial engineered structures that exhibits customize...
In a concurrent (FE2) multiscale modeling is an increasingly popular approach for modeling complex m...
Constitutive modeling of nonlinear materials is a computationally complex and time-intensive process...
Herein, we propose a new lattice generation strategy that is computationally cheaper and produces hi...
The drive to reduce material usage and improve properties of structures has led to additive manufa...