Design space and manufacturing of programmable 4D printed continuous flax fibre polylactic acid composite hygromorphs

The work describes the exploration of the design space by fabrication, modelling and testing of bio-based and humidity-triggered 4D printed shape-changing biocomposites. The aim is to broaden the under-standing of the control actuation via printing path tailoring and unlock new potential applications for biomaterials and autonomous actuator design. The composites are made with continuous flax yarns and polylactic acid matrix filaments and exhibit moisture-induced actuation. The actuation capability is first demonstrated by printing a calla lily flower-inspired configuration subjected to 98% relative humidity. This structure did not however achieve the anticlastic double curvature and large actuation targeted. To resolve these issues, cross-ply composite architectures with bent filaments deposited in one layer have then been developed. The amplitude for curvature control ranges obtained were 1.9*10-3mm-1 and 7.9*10-3mm-1 depending on the position on the specimen. Other cross-ply hygro-morphs solutions are also proposed, with the orientation of their passive layers ([0 degrees]2) tilted by a degrees (stacking sequence: [-a; a, 90 degrees]). The largest actuation curvature was obtained when a=40 degrees, which increased by 0.0072 mm -1 when compared to a = 0 degrees. The hygromorphs presented in this work are mod-elled using in an in-house filament scale finite element model able to capture the complexity of the printed hygromorphs architectures. (c) 2022 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY license (http:// creativecommons.org/licenses/by/4.0/).

Automated summary

This work explores the design space of bio-based and humidity-triggered 4D printed shape-changing biocomposites through fabrication, modelling, and testing. The aim is to enhance the understanding of control actuation through printing path tailoring and unlock new applications for biomaterials and autonomous actuator design. The composites, made of flax yarns and polylactic acid matrix filaments, demonstrate moisture-induced actuation. Different composite architectures, including cross-ply configurations, are developed to achieve the desired actuation curvature. A finite element model is used to capture the complexity of the printed hygromorphs.