Litcius/Paper detail

A Normal-Stressed Electromagnetic-Driven Stiffness-Tunable Nanopositioner

Xiangyuan Wang, Linlin Li, Yixuan Meng, Lingwen Tan, Weiwei Huang, Zhiwei Zhu, Fang Jiao, Limin Zhu

2024IEEE Transactions on Industrial Electronics21 citationsDOI

Abstract

High-bandwidth and long-range nanoprecision motion is crucially required by many advanced instruments and robotic systems, which rely on the nanopositioners. However, traditional nanopositioners suffer from their fixed stiffness and can only obtain fixed performance, leading to narrow applications. Here, a novel nanopositioner called normal-stressed electromagnetic-driven stiffness-tunable nanopositioner (EDSTN) is presented, which consists of three parts: A normal-stressed electromagnetic actuator to generate the actuation force, a high-stiffness compliant mechanism for guiding the fast precision motion, and a tunable negative stiffness electromagnetic spring to control the overall effective stiffness. The EDSTN realizes a stiffness tuning ratio of 3.24×, enabling an in situ, fast, and continuous performance tuning to meet the changing requirements. It holds promising prospects in constructing highly flexible precision devices, and the implementation of atomic force microscopy measurements on different samples validates its effectiveness. This work provides a new direction to develop versatile nanopositioners.

Topics & Concepts

StiffnessMaterials scienceControl theory (sociology)AcousticsPhysicsComputer scienceComposite materialControl (management)Artificial intelligencePiezoelectric Actuators and ControlForce Microscopy Techniques and ApplicationsAdvanced Surface Polishing Techniques