The mechanics and physics of twisted and coiled polymer actuators

TL;DR

This paper develops an analytical model combining microstructure and rod theory to predict the shape and contraction behavior of nylon twisted and coiled polymer actuators, aiding design and understanding.

Contribution

It introduces a novel integrated microstructure-rod model that accurately predicts TCPA equilibrium shapes and contraction mechanisms, advancing the understanding of nylon TCPAs.

Findings

Model accurately predicts TCPA shape and stiffness.

Quantifies the effect of stored energy on actuation performance.

Validated with experiments on nylon fibers.

Abstract

Twisted and coiled polymer actuators (TCPAs) generate large contractile mechanical work mimicking natural muscles, which makes them suitable for robotics and health-assistive devices. Understanding the mechanism of nylon TCPA remains challenging due to the interplay between their intricate geometry, chirality, residual stresses, and material microstructure. This study integrates a material microstructure model with rod theory to analytically predict the equilibrium helical shape of the nylon TCPA after fabrication and to explain the observed contraction mechanism upon stimulation. The first ingredient of the model is to treat nylon as a two-phase thermomechanical microstructure system capable of storing strain energy and exchanging it among the two phases. This is validated by characterizing the torsional actuation response of twisted and annealed nylon fibers. The second ingredient of the model is to use the classic Kirchhoff Rod Theory and add a necessary term that couples the bending and twisting energy. Validation with experiments shows that the model captures the equilibrium and longitudinal stiffness of the TCPA in both active and passive states, and the stimulated contraction under external load. Importantly, the model quantifies the influence of the stored energy level on the actuation performance. These concepts can be extended to other types of TCPAs and could enable new material design.