Abstract
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.
Highlights
Greater design freedom is attainable via the emergence of Thermoplastic elastomers (TPE) Laser sintering (LS) powders [13,14,15], enabling creation of high-performance components including for use in repeated, energy absorbing applications [16]
This study aims to establish a novel pathway for the efficient characterisation of TPE additive manufacturing (AM) materials, generating valid material model coefficients that will allow accurate finite element (FE) simulations within a transient, dynamic loading environment
Coupons were strained to failure, with true stress calculated from the effective change in specimen cross-sectional area measured via digital image correlation (DIC)
Summary
Thermoplastic elastomers (TPEs) can undergo large regimes of elastically recoverable strain and exhibit negligible creep [1], demonstrating their functional value when compared to other polymers and especially those used in repeated, energy-absorbing applications. TPE components are typically fabricated via extrusion or injection moulding, requiring high capital investment and yet affording limited design freedom. Polyamide [10,11] and polypropylene [12] are commonly used polymeric powders, though the inability of the sintered material to undergo large deformation regimes inherently limits final part functionality. Greater design freedom is attainable via the emergence of TPE LS powders [13,14,15], enabling creation of high-performance components including for use in repeated, energy absorbing (i.e. high strain rate) applications [16]
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