Bending‐Free Lattices as Underlying Optimal Isotropic Microstructures of the Least‐Compliant 2D Elastic Bodies

Czarnecki, S.; Łukasiak, Tomasz

doi:10.1002/pssb.202100344

Cited by 2 publications

(2 citation statements)

References 82 publications

(143 reference statements)

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“…For instance, the hexagonal (or honeycomb in the plane) gridwork is characterized by a very small shear modulus, if ligaments are slender (see [ 5 , 6 ]). On the other hand, spiral microstructures are characterized by very small bulk modulus, which implies the effective Poisson ratio almost attaining its lower 2D limit equal −1 (see [ 7 , 8 , 9 , 10 , 11 , 12 ]). To encompass such a broad class of composites, it is necessary to admit the largest possible range of the bulk and shear moduli.…”

Section: Introductionmentioning

confidence: 99%

“…The stress-based FEM was already developed in the 1970s (see [ 18 ]) and then extended to elasto-plasticity [ 19 ]. In the present paper, the present authors’ stress-based FE algorithm is proposed, originated in [ 20 ] in the context of Anisotropic Material Design, extended to the elastic IMD setting in [ 3 , 10 , 11 ] and adopted here to the elasto-plastic version of the IMD method. Since the numerical method of solving IMD problems plays an essential role here, it is put forward in detail in Section 5 , while the numerical optimization procedure is explained in Section 6 .…”

Section: Introductionmentioning

confidence: 99%

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The Isotropic Material Design of In-Plane Loaded Elasto-Plastic Plates

Czarnecki

Lewiński

2021

Materials

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This paper puts forward a new version of the Isotropic Material Design method for the optimum design of structures made of an elasto-plastic material within the Hencky-Nadai-Ilyushin theory. This method provides the optimal layouts of the moduli of isotropy to make the overall compliance minimal. Thus, the bulk and shear moduli are the only design variables, both assumed as non-negative fields. The trace of the Hooke tensor represents the unit cost of the design. The yield condition is assumed to be independent of the design variables, to make the design process as simple as possible. By eliminating the design variables, the optimum design problem is reduced to the pair of the two mutually dual Linear Constrained Problems (LCP). The solution to the LCP stress-based problem directly determines the layout of the optimal moduli. A numerical method has been developed to construct approximate solutions, which paves the way for constructing the final layouts of the elastic moduli. Selected illustrative solutions are reported, corresponding to various data concerning the yield limit and the cost of the design. The yield condition introduced in this paper results in bounding the values of the optimal moduli in the places of possible stress concentration, such as reentrant corners.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The Isotropic Material Design of In-Plane Loaded Elasto-Plastic Plates

Czarnecki

Lewiński

2021

Materials

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Auxetic Properties of the Stiffest Elastic Bodies as a Result of Topology Optimization and Microstructures Recovery Based on Homogenization Method

Czarnecki,

Łukasiak

2024

Physica Status Solidi (b)

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Herein, several semianalytical formulae for the optimal distribution of elastic moduli in 2D or 3D domains occupied by nonhomogeneous, least compliant bodies are presented and three different methods for recovering microstructures predicted by the isotropic material design method are proposed, which is a stress‐based variant of topology optimization for isotropic bodies. In all five presented variants of the topology optimization of elastic bodies, the numerical implementation of these formulae requires only the use of any algorithm of searching for the minimum of functional in multidimensions without any constraints, even box constraints on design parameters. For each variant considered, the formulae defining this functional are defined analytically. All results concern the design of composite structures that maximize their stiffness (equivalently minimize their compliance) while satisfying a certain isoperimetric condition introducing the upper limit of the available material resource. The article pays special attention to the fact that the stiffest, heterogeneous isotropic elastic material has almost always auxetic properties. Based on the asymptotic homogenization method and adopted bending‐free lattice model, an algorithm for the numerical recovering of nonhomogeneous isotropic microstructure in the entire domain occupied by the plate is proposed, with a fairly easy‐to‐implement ability to model an auxetic behavior.

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Bending‐Free Lattices as Underlying Optimal Isotropic Microstructures of the Least‐Compliant 2D Elastic Bodies

Cited by 2 publications

References 82 publications

The Isotropic Material Design of In-Plane Loaded Elasto-Plastic Plates

The Isotropic Material Design of In-Plane Loaded Elasto-Plastic Plates

Auxetic Properties of the Stiffest Elastic Bodies as a Result of Topology Optimization and Microstructures Recovery Based on Homogenization Method

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