3D Printed Flexible Strain Sensors: From Printing to Devices and Signals

The revolutionary and pioneering advancements of flexible electronics provide the boundless potential to become one of the leading trends in the exploitation of wearable devices and electronic skin. Working as substantial intermediates for the collection of external mechanical signals, flexible strain sensors that get intensive attention are regarded as indispensable components in flexible integrated electronic systems. Compared with conventional preparation methods including complicated lithography and transfer printing, 3D printing technology is utilized to manufacture various flexible strain sensors owing to the low processing cost, superior fabrication accuracy, and satisfactory production efficiency. Herein, up-to-date flexible strain sensors fabricated via 3D printing are highlighted, focusing on different printing methods based on photocuring and materials extrusion, including Digital Light Processing (DLP), fused deposition modeling (FDM), and direct ink writing (DIW). Sensing mechanisms of 3D printed strain sensors are also discussed. Furthermore, the existing bottlenecks and future prospects are provided for further progressing research.

Automated summary

The revolutionary advancements in flexible electronics offer great potential for wearable devices and electronic skin, with flexible strain sensors serving as essential components in integrated electronic systems. 3D printing technology is preferred for manufacturing flexible strain sensors due to its cost-effectiveness, accuracy, and efficiency. Various printing methods, such as DLP, FDM, and DIW, are discussed in this study, along with the sensing mechanisms of the printed sensors and suggestions for future research directions.