Tailorable activation of thermoresponsive composite structures incorporating wavy heaters via hybrid manufacturing

The activation method of thermoresponsive materials greatly affects the practical use of smart structures composed thereof. Despite extensive research that relies on methods using high ambient temperatures or planar heaters, the efficient and tailorable activation of relatively thick thermoresponsive composite structures remains challenging. Herein, we present a concept of embedding a wavy heater into a thermoresponsive material matrix to form a composite structure with parametrically designed thermal activation behavior, through a facile manufacturing approach combining 3D-printing and laser-cutting. We develop a numerical model to predict the transient heat transfer for varying wavy shapes of heater, and experimentally validate the numerical results. The exploration of the design space using the numerical model shows a reduction of up to 82% in heating time using the wavy design compared with the flat design. Finally, we demonstrate experimentally the stiffness tuning in thermoresponsive composite structures. This work paves the way for large-scale thermoresponsive composite structures with applications in aerospace and architecture.

Automated summary

The activation method of thermoresponsive materials plays a crucial role in the practical use of smart structures. This study proposes embedding a wavy heater into a thermoresponsive material matrix to create a composite structure with parametrically designed thermal activation behavior. A numerical model is developed to predict heat transfer and experimental validation is conducted. The results show that the wavy design reduces heating time by up to 82% compared to a flat design. Additionally, the stiffness tuning of thermoresponsive composite structures is demonstrated. This work facilitates the application of large-scale thermoresponsive composite structures in aerospace and architecture.