The paper presents a novel approach to manufacturing nitinol living hinges using femtosecond laser micromachining. Nitinol is a smart material with unique properties, including superelasticity and shape memory, that make it attractive for use in microrobotic applications. However, nitinol is notoriously difficult to machine, and traditional methods often result in heat-affected zones that degrade the material's desirable properties.
The authors first establish the optimal laser cutting parameters, using a fluence of 4.1 J/cm^2 and 5 passes to achieve a 5 μm ablation depth, by characterizing the nitinol material response to different laser power levels and number of passes. They then model the behavior of the fabricated hinges using both an analytical approach and a finite element method, and validate the models by comparing them to experimental torque measurements for rectangular and elliptic notch hinge designs.
The authors demonstrate the usefulness of these nitinol hinges by manufacturing a prototype miniature robotic wing mechanism, which they actuate using a piezoelectric actuator. The wing mechanism achieves a peak-to-peak stroke amplitude of 50°, surpassing the elastic range of traditional Kapton flexures.
The paper concludes by discussing potential improvements to the manufacturing process, such as laser polishing to reduce surface roughness and extend hinge lifetime, as well as the possibility of creating monolithic 2-DOF flexures to further enhance the capabilities of millimeter-scale robotic devices.
다른 언어로
소스 콘텐츠 기반
arxiv.org
더 깊은 질문