Small-scale magnetic actuators with optimal six degrees-of-freedom
Magnetic miniature robots (MMRs) are small-scale, untethered actuators which can be controlled by magnetic fields. As these actuators can non-invasively access highly confined and enclosed spaces; they have great potential to revolutionize numerous applications in robotics, materials science, and bi...
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sg-ntu-dr.10356-1558412022-03-23T07:51:02Z Small-scale magnetic actuators with optimal six degrees-of-freedom Xu, Changyu Yang, Zilin Lum, Guo Zhan School of Mechanical and Aerospace Engineering Engineering::Mechanical engineering Actuators Locomotion Magnetic miniature robots (MMRs) are small-scale, untethered actuators which can be controlled by magnetic fields. As these actuators can non-invasively access highly confined and enclosed spaces; they have great potential to revolutionize numerous applications in robotics, materials science, and biomedicine. While the creation of MMRs with six-degrees-of-freedom (six-DOF) represents a major advancement for this class of actuators, these robots are not widely adopted due to two critical limitations: i) under precise orientation control, these MMRs have slow sixth-DOF angular velocities (4 degree s-1 ) and it is difficult to apply desired magnetic forces on them; ii) such MMRs cannot perform soft-bodied functionalities. Here a fabrication method that can magnetize optimal MMRs to produce 51-297-fold larger sixth-DOF torque than existing small-scale, magnetic actuators is introduced. A universal actuation method that is applicable for rigid and soft MMRs with six-DOF is also proposed. Under precise orientation control, the optimal MMRs can execute full six-DOF motions reliably and achieve sixth-DOF angular velocities of 173 degree s-1 . The soft MMRs can display unprecedented functionalities; the six-DOF jellyfish-like robot can swim across barriers impassable by existing similar devices and the six-DOF gripper is 20-folds quicker than its five-DOF predecessor in completing a complicated, small-scale assembly. Nanyang Technological University Submitted/Accepted version G.Z.L. was funded by the start-up grant awarded by Nanyang Technological University. 2022-03-23T07:51:02Z 2022-03-23T07:51:02Z 2021 Journal Article Xu, C., Yang, Z. & Lum, G. Z. (2021). Small-scale magnetic actuators with optimal six degrees-of-freedom. Advanced Materials, 33(23), 2100170-. https://dx.doi.org/10.1002/adma.202100170 0935-9648 https://hdl.handle.net/10356/155841 10.1002/adma.202100170 33938046 2-s2.0-85104970026 23 33 2100170 en Advanced Materials This is the peer reviewed version of the following article: Xu, C., Yang, Z. & Lum, G. Z. (2021). Small-scale magnetic actuators with optimal six degrees-of-freedom. Advanced Materials, 33(23), 2100170-, which has been published in final form at https://doi.org/10.1002/adma.202100170. This article may be used for non-commercial purposes in accordance with Wiley Terms and Conditions for Use of Self-Archived Versions. application/pdf |
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Engineering::Mechanical engineering Actuators Locomotion Xu, Changyu Yang, Zilin Lum, Guo Zhan Small-scale magnetic actuators with optimal six degrees-of-freedom |
| description |
Magnetic miniature robots (MMRs) are small-scale, untethered actuators which can be controlled by magnetic fields. As these actuators can non-invasively access highly confined and enclosed spaces; they have great potential to revolutionize numerous applications in robotics, materials science, and biomedicine. While the creation of MMRs with six-degrees-of-freedom (six-DOF) represents a major advancement for this class of actuators, these robots are not widely adopted due to two critical limitations: i) under precise orientation control, these MMRs have slow sixth-DOF angular velocities (4 degree s-1 ) and it is difficult to apply desired magnetic forces on them; ii) such MMRs cannot perform soft-bodied functionalities. Here a fabrication method that can magnetize optimal MMRs to produce 51-297-fold larger sixth-DOF torque than existing small-scale, magnetic actuators is introduced. A universal actuation method that is applicable for rigid and soft MMRs with six-DOF is also proposed. Under precise orientation control, the optimal MMRs can execute full six-DOF motions reliably and achieve sixth-DOF angular velocities of 173 degree s-1 . The soft MMRs can display unprecedented functionalities; the six-DOF jellyfish-like robot can swim across barriers impassable by existing similar devices and the six-DOF gripper is 20-folds quicker than its five-DOF predecessor in completing a complicated, small-scale assembly. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Xu, Changyu Yang, Zilin Lum, Guo Zhan |
| format |
Article |
| author |
Xu, Changyu Yang, Zilin Lum, Guo Zhan |
| author_sort |
Xu, Changyu |
| title |
Small-scale magnetic actuators with optimal six degrees-of-freedom |
| title_short |
Small-scale magnetic actuators with optimal six degrees-of-freedom |
| title_full |
Small-scale magnetic actuators with optimal six degrees-of-freedom |
| title_fullStr |
Small-scale magnetic actuators with optimal six degrees-of-freedom |
| title_full_unstemmed |
Small-scale magnetic actuators with optimal six degrees-of-freedom |
| title_sort |
small-scale magnetic actuators with optimal six degrees-of-freedom |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/155841 |
| _version_ |
1728433410113798144 |