Variable stiffness wires based on magnetorheological liquid metals
Variable stiffness wires based on magnetorheological liquid metals
Magnetorheological fluid (MRF) has shown its great potential in the development of large mechanical devices, such as dampers, shock absorbers, rotary brakes, clutches, and prosthetic joints. Recently, more research focus has been invested on using MRF to develop soft, stretchable, and miniaturized devices with variable stiffness for realizing functionalities that cannot be achieved using solid smart materials. Here, based on liquid metal magnetoactive slurries (LMMS), a variable stiffness wire with excellent electrical conductivity is demonstrated. Without exposure to a magnetic field, the LMMS wire has an extremely low stiffness, and can be easily stretched while maintaining an excellent electrical conductivity. When applying a magnetic field, the wire becomes much stiffer and can retain its shape even under a load. The combination of properties of flexibility, high electrical conductivity, and variable stiffness of the wire is harnessed to make a flexible gripper that can grasp objects of various shapes. Moreover, by using gallium instead of its liquid metal alloys, the tunable stiffness range of the LMMS wire is significantly enhanced and can be controlled using both external magnetic fields and temperature-induced phase change. The presented LMMS wire has the potential to be applied in flexible electronics, soft robotics and so on.
Liquid metal, magnetorheological fluid (MRF), soft robotics, stretchable electronics, various stiffness
232-243
Zhou, Xiangbo
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Shu, Jian
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Jin, Hu
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Ren, Hongtai
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Ma, Gang
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Gong, Ning
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Ge, Du an
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Shi, Juan
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Tang, Shi Yang
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Yun, Guolin
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Lu, Hongda
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Dong, Shuai
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Li, Xiangpeng
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Zhang, Shiwu
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Li, Weihua
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2022
Zhou, Xiangbo
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Shu, Jian
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Jin, Hu
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Ren, Hongtai
608a31ca-90db-4a32-8c19-9614ef821be2
Ma, Gang
e1fadc67-6db8-4dfc-9ff3-3e246f081faf
Gong, Ning
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Ge, Du an
29790261-acbb-43c8-a225-dc1ed03e6f9d
Shi, Juan
26d9a852-1614-49d9-ae7d-d22f95ee3ea6
Tang, Shi Yang
1d0f15c6-2a3e-4bad-a3d8-fc267db93ed4
Yun, Guolin
240c3dc9-c224-41c0-8740-de165d1eb90b
Lu, Hongda
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Dong, Shuai
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Li, Xiangpeng
73f32905-ad7c-4ce3-93a4-78237b98f4fb
Zhang, Shiwu
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Li, Weihua
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Zhou, Xiangbo, Shu, Jian, Jin, Hu, Ren, Hongtai, Ma, Gang, Gong, Ning, Ge, Du an, Shi, Juan, Tang, Shi Yang, Yun, Guolin, Lu, Hongda, Dong, Shuai, Li, Xiangpeng, Zhang, Shiwu and Li, Weihua
(2022)
Variable stiffness wires based on magnetorheological liquid metals.
International Journal of Smart and Nano Materials, 13 (2), .
(doi:10.1080/19475411.2022.2065703).
Abstract
Magnetorheological fluid (MRF) has shown its great potential in the development of large mechanical devices, such as dampers, shock absorbers, rotary brakes, clutches, and prosthetic joints. Recently, more research focus has been invested on using MRF to develop soft, stretchable, and miniaturized devices with variable stiffness for realizing functionalities that cannot be achieved using solid smart materials. Here, based on liquid metal magnetoactive slurries (LMMS), a variable stiffness wire with excellent electrical conductivity is demonstrated. Without exposure to a magnetic field, the LMMS wire has an extremely low stiffness, and can be easily stretched while maintaining an excellent electrical conductivity. When applying a magnetic field, the wire becomes much stiffer and can retain its shape even under a load. The combination of properties of flexibility, high electrical conductivity, and variable stiffness of the wire is harnessed to make a flexible gripper that can grasp objects of various shapes. Moreover, by using gallium instead of its liquid metal alloys, the tunable stiffness range of the LMMS wire is significantly enhanced and can be controlled using both external magnetic fields and temperature-induced phase change. The presented LMMS wire has the potential to be applied in flexible electronics, soft robotics and so on.
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Published date: 2022
Additional Information:
Funding Information:
This research was partially supported by the National Natural Science Foundation of China (nos. 51975550, U1713206, and 51828503). The authors also thank Engineering Practice Center and Engineering Science Experimental Teaching Center, University of Science and Technology of China, for supporting in 3D printing serves.
Publisher Copyright:
© 2022 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group.
Keywords:
Liquid metal, magnetorheological fluid (MRF), soft robotics, stretchable electronics, various stiffness
Identifiers
Local EPrints ID: 481771
URI: http://eprints.soton.ac.uk/id/eprint/481771
ISSN: 1947-5411
PURE UUID: eb8be192-8d3f-4e78-a8fc-a7e7da8e731d
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Date deposited: 07 Sep 2023 16:36
Last modified: 06 Jun 2024 02:18
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Contributors
Author:
Xiangbo Zhou
Author:
Jian Shu
Author:
Hu Jin
Author:
Hongtai Ren
Author:
Gang Ma
Author:
Ning Gong
Author:
Du an Ge
Author:
Juan Shi
Author:
Shi Yang Tang
Author:
Guolin Yun
Author:
Hongda Lu
Author:
Shuai Dong
Author:
Xiangpeng Li
Author:
Shiwu Zhang
Author:
Weihua Li
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