Rational Design of Pentamode Metamaterials by Topology Optimization

Luo, Z; Li, Z

Rational Design of Pentamode Metamaterials by Topology Optimization

Luo, Z

Li, Z

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Publisher:: IAAM
Publication Type:: Conference Proceeding
Citation:: Article ID 2020-0818 (2020), 2020, 1, (1)
Issue Date:: 2020-11-02

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Field	Value	Language
dc.contributor.author	Luo, Z https://orcid.org/0000-0002-6953-3986
dc.contributor.author	Li, Z
dc.date	2020-06-23
dc.date.accessioned	2021-05-19T06:20:27Z
dc.date.available	2021-05-19T06:20:27Z
dc.date.issued	2020-11-02
dc.identifier.citation	Article ID 2020-0818 (2020), 2020, 1, (1)
dc.identifier.uri	http://hdl.handle.net/10453/148972
dc.description.abstract	Pentamode metamaterials (PMMs)[1,2], categorized as a new class of three-dimensional solid mechanical metamaterials, refer to artificially engineered lattice materials exhibiting a vanishing shear modulus, mimicking the behaviour of fluids but are solid, and hard to compress yet easy to deform. Here ‘penta’ denotes five, referring to only one non-zero but five vanishing eigenvalues in the elasticity tensor of isotropic materials. The extraordinary elastic properties of PMMs are dominantly determined by the geometries (i.e. shapes and topologies) of rationally designed microstructures, instead of the composition of their base materials. Compared to most up-to-date design methods based on conventional rigid-body double-cone concept related to diamond lattice, this lecture is more focused an innovative computational design methodology using topology optimization to uncover new micro architectures with novel geometries over a range of effective properties and relative densities. The overall elastic deformation of the microstructure is utilised to achieve the pentamode properties, rather than making use of the highly localised point-point deformation gained from rigid-body links (tiny tips). The design problem is then formulated to make the microstructure have a large but realistically attainable ratio of effective bulk modulus compared to the shear modulus, corresponding to the isotropic microstructure with the effective Poisson’s ratio approaching to 0.5. The larger of the ratio, the better of the PMM solids to simulate liquids. The whole microstructure is discretised with a high-resolution finite element mesh, in order to capture the fine geometric features of the ultralight microstructure in the space. The SIMP-topology optimisation method [3] is firstly applied to find the topologically optimised pentaomode microstructure, and then based on the skeleton of the topological design the size optimisation approach is further used to investigate the impact of the size dimensions to the pentomode properties. The SLM (selective laser melting) technique [4] is used for rapid prototyping fabrication of the optimised microstructures with metal materials. Several numerical cases are used to demonstrate the effectiveness of the proposed optimisation method for creating novel pentamode materials. The computation is conducted using UTS ARCLab high-performance computing clusters. It can be found that the effective Position’s ratio of the microstructure gradually close to 0.5 and the ratio of effective bulk modulus with respect to the shear modulus is getting larger, along with the reduce of the size dimension of the beam of the microstructure, although the manufacturing is becoming more difficult.
dc.language	en
dc.publisher	IAAM
dc.relation	http://purl.org/au-research/grants/arc/DP160102491
dc.relation.ispartof	Article ID 2020-0818 (2020)
dc.relation.ispartof	Advanced Materials Lecture Series
dc.relation.isbasedon	10.5185/vpoam.2020.0818
dc.rights	info:eu-repo/semantics/openAccess
dc.title	Rational Design of Pentamode Metamaterials by Topology Optimization
dc.type	Conference Proceeding
utslib.citation.volume	1
utslib.location.activity	Sweden
pubs.organisational-group	/University of Technology Sydney
pubs.organisational-group	/University of Technology Sydney/Faculty of Engineering and Information Technology
pubs.organisational-group	/University of Technology Sydney/Faculty of Engineering and Information Technology/School of Mechanical and Mechatronic Engineering
utslib.copyright.status	open_access	*
pubs.consider-herdc	true
dc.date.updated	2021-05-19T06:20:26Z
pubs.finish-date	2020-06-23
pubs.issue	1
pubs.place-of-publication	Sweden
pubs.publication-status	Published online
pubs.start-date	2020-06-23
pubs.volume	1
utslib.citation.issue	1
dc.location	Sweden

Abstract:

Pentamode metamaterials (PMMs)[1,2], categorized as a new class of three-dimensional solid mechanical metamaterials, refer to artificially engineered lattice materials exhibiting a vanishing shear modulus, mimicking the behaviour of fluids but are solid, and hard to compress yet easy to deform. Here ‘penta’ denotes five, referring to only one non-zero but five vanishing eigenvalues in the elasticity tensor of isotropic materials. The extraordinary elastic properties of PMMs are dominantly determined by the geometries (i.e. shapes and topologies) of rationally designed microstructures, instead of the composition of their base materials. Compared to most up-to-date design methods based on conventional rigid-body double-cone concept related to diamond lattice, this lecture is more focused an innovative computational design methodology using topology optimization to uncover new micro architectures with novel geometries over a range of effective properties and relative densities. The overall elastic deformation of the microstructure is utilised to achieve the pentamode properties, rather than making use of the highly localised point-point deformation gained from rigid-body links (tiny tips). The design problem is then formulated to make the microstructure have a large but realistically attainable ratio of effective bulk modulus compared to the shear modulus, corresponding to the isotropic microstructure with the effective Poisson’s ratio approaching to 0.5. The larger of the ratio, the better of the PMM solids to simulate liquids. The whole microstructure is discretised with a high-resolution finite element mesh, in order to capture the fine geometric features of the ultralight microstructure in the space. The SIMP-topology optimisation method [3] is firstly applied to find the topologically optimised pentaomode microstructure, and then based on the skeleton of the topological design the size optimisation approach is further used to investigate the impact of the size dimensions to the pentomode properties. The SLM (selective laser melting) technique [4] is used for rapid prototyping fabrication of the optimised microstructures with metal materials. Several numerical cases are used to demonstrate the effectiveness of the proposed optimisation method for creating novel pentamode materials. The computation is conducted using UTS ARCLab high-performance computing clusters. It can be found that the effective Position’s ratio of the microstructure gradually close to 0.5 and the ratio of effective bulk modulus with respect to the shear modulus is getting larger, along with the reduce of the size dimension of the beam of the microstructure, although the manufacturing is becoming more difficult.

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http://hdl.handle.net/10453/148972