Your search keyword '"magnetic robots"' showing total 1 results

1. Remote Modular Electronics for Wireless Magnetic Devices

Author

Mustafa Boyvat, Metin Sitti, Sitti, Metin (ORCID 0000-0001-8249-3854 & YÖK ID 297104), Boyvat, Mustafa, School of Medicine, College of Engineering, and Department of Mechanical Engineering

Subjects

Computer science, General Chemical Engineering, Science, General Physics and Astronomy, Medicine (miscellaneous), magnetic robots, wireless power transfer, Biochemistry, Genetics and Molecular Biology (miscellaneous), Physical Phenomena, Magnetics, modular devices, Computer Science::Networking and Internet Architecture, Wireless, Torque, General Materials Science, Electronics, Wireless power transfer, Research Articles, Electronic circuit, business.industry, reconfigurable devices, General Engineering, Electrical engineering, Control reconfiguration, Equipment Design, Robotics, Modular design, Chemistry, Nanoscience, Nanotechnology, Materials science, Robot, wireless devices, business, Wireless Technology, Research Article

Abstract

Small-scale wireless magnetic robots and devices offer an effective solution to operations in hard-to-reach and high-risk enclosed places, such as inside the human body, nuclear plants, and vehicle infrastructure. In order to obtain functionalities beyond the capability of magnetic forces and torques exerted on magnetic materials used in these robotic devices, electronics need to be also integrated into them. However, their capabilities and power sources are still very limited compared to their larger-scale counterparts due to their much smaller sizes. Here, groups of milli/centimeter-scale wireless magnetic modules are shown to enable on-site electronic circuit construction and operation of highly demanding wireless electrical devices with no batteries, that is, with wireless power. Moreover, the mobility of the modular components brings remote modification and reconfiguration capabilities. When these small-scale robotic modules are remotely assembled into specific geometries, they can achieve, if not impossible, challenging electrical tasks for individual modules. Using such a method, several wireless and battery-free robotic devices are demonstrated using milli/centimeter-scale robotic modules, such as a wireless circuit to power light-emitting diodes with lower external fields, a device to actuate relatively high force-output shape memory alloy actuators, and a wireless force sensor, all of which can be modified on-site., Advanced Science, 8 (17), ISSN:2198-3844

Published

2021