Bespoke extensional elasticity through helical lattice systems

Dixon, Maximillian D. X.; O’Donnell, Matthew P.; Pirrera, Alberto; Chenchiah, Isaac V.

doi:10.1098/rspa.2019.0547

Cited by 8 publications

(9 citation statements)

References 31 publications

(59 reference statements)

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“…The energy profile of such elements can be tuned by tailoring their characteristic properties and can even match a target energy profile with an arbitrary level of accuracy (Dixon et al, 2019). However for computational ease we choose l p = l 0 +1…”

Section: One-dimensional Bistable Elementsmentioning

confidence: 99%

“…Furthermore, the helical lattice can be tuned to exploit external fields, such as thermal effects (O'Donnell et al, 2019; McHale et al, 2020a), to modulate the effective stiffness and stability landscape. The potential of helical lattices to obtain truly bespoke elastic responses was considered by Dixon et al (2019). By exploiting the helical lattice as a structural base-unit for nonlinear systems of coupled lattices, an algorithmic tuning process that can match, to an arbitrary precision, any energetic function up to a constant was developed (Dixon et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

“…The potential of helical lattices to obtain truly bespoke elastic responses was considered by Dixon et al (2019). By exploiting the helical lattice as a structural base-unit for nonlinear systems of coupled lattices, an algorithmic tuning process that can match, to an arbitrary precision, any energetic function up to a constant was developed (Dixon et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

“…Emergent behavior is not restricted to the helical lattice alone and there exists a range of non-linear units from which emergent behavior is observed as system complexity is increased, such as cylindrical ribbons (Lachenal et al, 2012;Aza et al, 2019;Carey et al, 2019) and snapping arches (Hunt and Dodwell, 2019). This paper seeks to extend the design concepts explored in Dixon et al (2019) beyond their current one-dimensional nature through an exploration of hierarchical space-filling lattices. In doing so, we take one step closer toward the design of truly bespoke (meta-)materials.…”

Section: Introductionmentioning

confidence: 99%

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Exploring Adaptive Behavior of Non-linear Hexagonal Frameworks

et al. 2020

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Non-linear structural responses offer a rich design space that can be integrated into the development of novel (meta)-materials to enable transformative capabilities. By exploiting robust, repeatable, non-linear elasticity the (meta)-material's performance can be tailored to significantly exceed what has been demonstrated through traditional linear design paradigms. Embracing geometric non-linearity offers the designer the potential for truly bespoke large-range elastic behavior. Herein we explore the behavior of bistable elements that can be arranged into a space-filling triangular lattice, constructed in a hierarchical manner. We develop an analysis of the system that can be readily extended to more complex hierarchies, such as the hexagonal arrangement considered herein, whilst retaining physical insight. Specifically, we present the geometric restrictions of lattice elements that govern the existence of stable stress-free states and subsequently characterize the transitions between such states by searching for the minimum energetic transition pathway. Through our approach, we explore how hierarchical multi-stable systems can be analyzed, thus contributing to the development of truly bespoke adaptive (meta-)materials.

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Section: One-dimensional Bistable Elementsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Exploring Adaptive Behavior of Non-linear Hexagonal Frameworks

et al. 2020

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“…Refs. [12][13][14][15]. Through careful tailoring of structural form and the composites' anisotropic stiffness, bespoke nonlinear responses can be readily achieved.…”

Section: Introductionmentioning

confidence: 99%

Visualising Compliance of Composite Shell Mechanisms

Stacey

O’Donnell

Schenk

et al. 2020

Volume 10: 44th Mechanisms and Robotics Conference (MR)

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In the design of isotropic compliant shell-based mechanisms a desired response of an end-effector is commonly achieved through careful selection of shell geometry and material. However, for applications such as the design of medical support devices the shell must conform to a highly constrained set of permissible geometries, limiting tailorability. One solution to this design challenge is to exploit anisotropic material behaviour. Advanced composite materials may be elastically tailored by varying the fibre orientation, but at the cost of increased design complexity. Herein we present an approach for capturing the effects of material anisotropy on compliant shell mechanisms by providing the designer with a method for visualising their response in a physically intuitive manner. We extend the mechanism characterisation technique of Lip-kin and Patterson [1] using eigen-decomposition, and visualise the compliance vectors for structures with material anisotropy. We characterise the behaviour of cantilevered “tape-spring” shell geometries with varying enclosed angles using nonlinear finite element analysis. For small enclosed angles we observe significant reorienting of the compliance vectors due to stiffness anisotropy; as the enclosed angle is increased, geometry dominates the response. However, in an intermediate region both geometric and stiffness effects interact, highlighting the potential richness of the design space.

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A variable-topology morphing composite cylindrical lattice

Carey

McHale

2021

Composite Structures

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Bespoke extensional elasticity through helical lattice systems

Cited by 8 publications

References 31 publications

Exploring Adaptive Behavior of Non-linear Hexagonal Frameworks

Exploring Adaptive Behavior of Non-linear Hexagonal Frameworks

Visualising Compliance of Composite Shell Mechanisms

A variable-topology morphing composite cylindrical lattice

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