Tomás Zegard scite author profile

Topology optimization is a technique that allows for increasingly efficient designs with minimal a priori decisions. Because of the complexity and intricacy of the solutions obtained, topology optimization was often constrained to research and theoretical studies. Additive manufacturing, a rapidly evolving field, fills the gap between topology optimization and application. Additive manufacturing has minimal limitations on the shape and complexity of the design, and is currently evolving towards new materials, higher precision and larger build sizes. Two topology optimization methods are addressed: the ground structure method and density-based topology optimization. The results obtained from these topology optimization methods require some degree of post-processing before they can be manufactured. A simple procedure is described by which output suitable for additive manufacturing can be generated. In this process, some inherent issues of the optimization technique may be magnified resulting in an unfeasible or bad product. In addition, this work aims to address some of these issues and propose methodologies by which they may be alleviated. The proposed framework has applications in a number Electronic supplementary material The online version of this article (of fields, with specific examples given from the fields of health, architecture and engineering. In addition, the generated output allows for simple communication, editing, and combination of the results into more complex designs. For the specific case of three-dimensional density-based topology optimization, a tool suitable for result inspection and generation of additive manufacturing output is also provided.

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GRAND — Ground structure based topology optimization for arbitrary 2D domains using MATLAB

Zegard

Paulino

2014

Struct Multidisc Optim

126

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GRAND3 — Ground structure based topology optimization for arbitrary 3D domains using MATLAB

Zegard

Paulino

2015

Struct Multidisc Optim

106

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Toward GPU accelerated topology optimization on unstructured meshes

Zegard

Paulino

2013

Struct Multidisc Optim

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Unraveling tensegrity tessellations for metamaterials with tunable stiffness and bandgaps

Liu

Zegard

Pratapa

et al. 2019

Journal of the Mechanics and Physics of Solids

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Tensegrity structures resemble biological tissues: a structural system that holds an internal balance of prestress. Owing to the presence of prestress, biological tissues can dramatically change their properties, making tensegrity a promising platform for tunable and functional metamaterials. However, tensegrity metamaterials require harmony between form and force in an infinitely-periodic scale, which makes the design of such systems challenging. In order to explore the full potential of tensegrity metamaterials, a systematic design approach is required. In this work, we propose an automated design framework that provides access to unlimited tensegrity metamaterial designs. The framework generates tensegrity metamaterials by tessellating blocks with designated geometries that are aware of the system periodicity. We show that tensegrity metamaterials offer tunable effective elastic moduli, Poisson's ratio, and phononic bandgaps by properly changing their prestress levels, which provide a new dimension of programmability beyond geometry.

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Tomás Zegard

Bridging topology optimization and additive manufacturing

GRAND — Ground structure based topology optimization for arbitrary 2D domains using MATLAB

GRAND3 — Ground structure based topology optimization for arbitrary 3D domains using MATLAB

Toward GPU accelerated topology optimization on unstructured meshes

Unraveling tensegrity tessellations for metamaterials with tunable stiffness and bandgaps

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