A novel pathway for efficient characterisation of additively manufactured thermoplastic elastomers

A novel pathway for efficient characterisation of additively manufactured thermoplastic elastomers

Thermoplastic elastomers (TPE) are commonly used to fabricate structures for application in repeatable, energy absorption environments. The emergence of additive manufacturing (AM) means scope now exists to design and build complex TPE components that can mechanically outperform traditionally manufa...

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Main Authors: Rhosslyn Adams, Shwe P. Soe, Rafael Santiago, Michael Robinson, Benjamin Hanna, Graham McShane, Marcílio Alves, Roy Burek, Peter Theobald
Format: Article
Language:English
Published: Elsevier 2019-10-01
Series:Materials & Design
Online Access:http://www.sciencedirect.com/science/article/pii/S0264127519303557
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spelling doaj-fd70525e1b4e432594f3af0aff5c4f982020-11-24T21:56:05ZengElsevierMaterials & Design0264-12752019-10-01180A novel pathway for efficient characterisation of additively manufactured thermoplastic elastomersRhosslyn Adams0Shwe P. Soe1Rafael Santiago2Michael Robinson3Benjamin Hanna4Graham McShane5Marcílio Alves6Roy Burek7Peter Theobald8Cardiff School of Engineering, Cardiff University, UKCardiff School of Engineering, Cardiff University, UKCentre of Engineering, Modelling and Applied Social Science (CECS), Federal University of ABC (UFABC), BrazilCardiff School of Engineering, Cardiff University, UKCardiff School of Engineering, Cardiff University, UKDepartment of Engineering, Trumpington Street, Cambridge University, UKDepartment of Mechatronics and Mechanical Systems Engineering, Group of Solid Mechanics and Structural Impact, University of São Paulo (USP), BrazilCardiff School of Engineering, Cardiff University, UK; Charles Owen, Royal Works, Croesfoel Industrial Park, Wrexham, UKCardiff School of Engineering, Cardiff University, UK; Corresponding author.Thermoplastic elastomers (TPE) are commonly used to fabricate structures for application in repeatable, energy absorption environments. The emergence of additive manufacturing (AM) means scope now exists to design and build complex TPE components that can mechanically outperform traditionally manufactured equivalents. The ability to efficiently characterize these new TPE AM materials is, however, a barrier preventing wider industrial uptake. This study aims to establish a novel pathway for efficiently characterizing materials used in transient, dynamic applications, to ultimately enable accurate finite element (FE) simulation. A laser sintered TPE powder was characterised by performing low, intermediate and high rate uniaxial tension tests, plus planar and equibiaxial loading states. These data demonstrated significantly different behaviour across strain rates and deformation modes, necessitating fit of an augmented hyperelastic and linear viscoelastic model. FE software was then used to calibrate material model coefficients, with their validity evaluated by comparing the simulated and experimental behaviour of the material in isolated (uniaxial tensile) and mixed modal (lattice-based impact) deformation states. Close correlation demonstrated this novel approach efficiently generated valid material model coefficients, removing a barrier to industry adopting these materials. This creates opportunity to exploit these new technologies for the design optimization and fabrication of high-performance components. Keywords: Thermoplastic elastomer, Polymer characterisation, Hyperelastic, Viscoelastic, High strain-rate FEA analysis, Laser sinteringhttp://www.sciencedirect.com/science/article/pii/S0264127519303557
collection DOAJ
language English
format Article
sources DOAJ
author Rhosslyn Adams
Shwe P. Soe
Rafael Santiago
Michael Robinson
Benjamin Hanna
Graham McShane
Marcílio Alves
Roy Burek
Peter Theobald
spellingShingle Rhosslyn Adams
Shwe P. Soe
Rafael Santiago
Michael Robinson
Benjamin Hanna
Graham McShane
Marcílio Alves
Roy Burek
Peter Theobald
A novel pathway for efficient characterisation of additively manufactured thermoplastic elastomers
Materials & Design
author_facet Rhosslyn Adams
Shwe P. Soe
Rafael Santiago
Michael Robinson
Benjamin Hanna
Graham McShane
Marcílio Alves
Roy Burek
Peter Theobald
author_sort Rhosslyn Adams
title A novel pathway for efficient characterisation of additively manufactured thermoplastic elastomers
title_short A novel pathway for efficient characterisation of additively manufactured thermoplastic elastomers
title_full A novel pathway for efficient characterisation of additively manufactured thermoplastic elastomers
title_fullStr A novel pathway for efficient characterisation of additively manufactured thermoplastic elastomers
title_full_unstemmed A novel pathway for efficient characterisation of additively manufactured thermoplastic elastomers
title_sort novel pathway for efficient characterisation of additively manufactured thermoplastic elastomers
publisher Elsevier
series Materials & Design
issn 0264-1275
publishDate 2019-10-01
description Thermoplastic elastomers (TPE) are commonly used to fabricate structures for application in repeatable, energy absorption environments. The emergence of additive manufacturing (AM) means scope now exists to design and build complex TPE components that can mechanically outperform traditionally manufactured equivalents. The ability to efficiently characterize these new TPE AM materials is, however, a barrier preventing wider industrial uptake. This study aims to establish a novel pathway for efficiently characterizing materials used in transient, dynamic applications, to ultimately enable accurate finite element (FE) simulation. A laser sintered TPE powder was characterised by performing low, intermediate and high rate uniaxial tension tests, plus planar and equibiaxial loading states. These data demonstrated significantly different behaviour across strain rates and deformation modes, necessitating fit of an augmented hyperelastic and linear viscoelastic model. FE software was then used to calibrate material model coefficients, with their validity evaluated by comparing the simulated and experimental behaviour of the material in isolated (uniaxial tensile) and mixed modal (lattice-based impact) deformation states. Close correlation demonstrated this novel approach efficiently generated valid material model coefficients, removing a barrier to industry adopting these materials. This creates opportunity to exploit these new technologies for the design optimization and fabrication of high-performance components. Keywords: Thermoplastic elastomer, Polymer characterisation, Hyperelastic, Viscoelastic, High strain-rate FEA analysis, Laser sintering
url http://www.sciencedirect.com/science/article/pii/S0264127519303557
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