A Compact 2-DOF Cross-Scale Piezoelectric Robotic Manipulator With Adjustable Force for Biological Delicate Puncture
Xiang Gao, Jie Deng, Weiyi Wang, Qingbing Chang, Jianhua Sun, Junkao Liu, Shijing Zhang, Yingxiang Liu
Abstract
Robotic micromanipulation technology plays a fundamental supporting role in biomedical engineering field. However, it is still a challenge for robotic manipulators to meet the puncture performance requirements for complex cells and curved vessels with different sizes, because they are difficult to achieve a comprehensive characteristic of multi-DOF, long stroke, high displacement resolution, large puncture force, and high force resolution for limitations of structures, driving elements, and actuation methods. To addresses this challenge, this article proposes the conceptual design of a piezoelectric robotic manipulator (PERM) driven by a single piezoelectric actuator. A configuration design idea and a new actuation method are elaborated to achieve 2-DOF cross-scale manipulation and adjustable puncture force. Theoretical analyses and simulations are carried out to investigate the influence of key structural parameters on displacement response and puncture force, as well as to determine the parameters. A prototype is fabricated, a dedicated handheld controller is developed, and a robotic micropuncture system is constructed to conduct characteristic testing and application research. Experimental results reveal that the manipulator achieves linear and rotary strokes of 38.5 mm and 360°, displacement resolutions of 48 nm and 0.38 <italic xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">μ</i>rad, a puncture force range from 1.70 to 301.34 mN, and a force resolution of 0.13 mN. Additionally, the manipulator successfully performs delicate puncture of silicone capillaries with different sizes and a curved silicone capillary under collaborative manipulation of the piezoelectric platform. This article exhibits a high-performance PERM and verifies its feasibility in micropuncture of tiny and complex-shaped organisms.