A Rotary Actuator Using Shape Memory Alloy (SMA) Wires

doi:10.1109/tmech.2013.2290545

Cited by 36 publications

(7 citation statements)

References 24 publications

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“…Because of the SMA's advantage of compact size, high power/force density and corrosion-resistance, [23][24][25] the SMA ISCr trigger won't influence the electrochemical system inside battery and can output sufficient executive power once reach its A f temperature. Besides, in this research, the SMA ISCr trigger only has an area less than 1 cm 2 (7.5 mm × 7.5 mm), which is very small compared with the area of entire jelly-roll.…”

Section: Shape Memory Alloy Battery Internal Short Circuit Triggermentioning

confidence: 99%

“…The SMA also has the advantage of compact size, high power/force density, corrosion-resistance, silence in action, and thus are applied in aerospace engineering, robotic engineering, biomedical engineering, etc. [23][24][25] In this research, an ISCr trigger method is proposed basing on SMA. The proposed SMA ISCr trigger method could trigger different types of ISCr and can be easily implanted into batteries.…”

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confidence: 99%

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Internal Short Circuit Trigger Method for Lithium-Ion Battery Based on Shape Memory Alloy

Zhang

Liu

et al. 2017

J. Electrochem. Soc.

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Internal short circuit (ISCr) is one of the major safety issues of lithium batteries and would lead to thermal runaway of batteries. Repeating ISCr in laboratory requires to create small-scale short circuit inside integrated batteries, which is very hard for existed safety test methods. In this paper, a novel ISCr trigger method based on shape memory effect of shape memory alloy (SMA) is proposed, which is easy to be implanted into batteries while has minor influences on batteries normal performance. The proposed SMA ISCr trigger method is employed to conduct ISCr experiments, including the severest type of ISCr, the Aluminum-Anode ISCr, and the most common type of ISCr, the Cathode-Anode ISCr. The experiments results show that the Aluminum-Anode ISCr leads to explosion while the Cathode-Anode ISCr only leads to mild self-discharging. Compared with the nail penetration test, the proposed SMA ISCr trigger method in the Aluminum-Anode ISCr experiment has 1) better consistency, given that all of the 4 tested batteries have their maximum temperature in the range of 383∼393 • C; 2) better reliability in evaluating battery safety properties, given that all of the 4 tested batteries have the repeatable explosion behavior. The relative ease of inserting this controllable SMA ISCr and the repeatability of the produced data can lead to better modeling and detection techniques of battery internal shorts such as plating and dendrite formation. The lithium battery becomes more and more popular among electronic devices and electric vehicles, due to its high energy density, good power density and long cycle life.

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Section: Shape Memory Alloy Battery Internal Short Circuit Triggermentioning

confidence: 99%

mentioning

confidence: 99%

Internal Short Circuit Trigger Method for Lithium-Ion Battery Based on Shape Memory Alloy

Zhang

Liu

et al. 2017

J. Electrochem. Soc.

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“…A large amount of fibers could be served as candidate materials of fibrous artificial muscles, including artificial polymer fibers (such as nylon fibers and spandex fibers), artificial inorganic fibers (such as shape memory alloy wires − and graphene fibers), − and carbon nanotube fibers. − Besides, composite fibers can further provide artificial muscles with more properties and functions such as the composition of paraffin or silica gel with pure fibers and composition of carbon nanotube fibers with hydrophilic polymer materials . However, these materials are subjected to high cost, difficult synthesis and processing, and potential chemical toxicity to the human body.…”

Section: Introductionmentioning

confidence: 99%

Wet-Driven Bionic Actuators from Wool Artificial Yarn Muscles

Shen

Xue

2023

ACS Appl. Mater. Interfaces

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Nature-similar muscle is one of the ultimate goals of advanced artificial muscle materials. Currently, a variety of chemical and natural materials have been gradually developed for the preparation of artificial muscles. However, due to the scarcity, biological exclusion, and poor flexibility of the abovementioned materials, it is still a challenging process to maximize the imitation of behaviors shown by real muscles and commercial development. Here, this article presents multidimensional wool yarn artificial muscles, and the wet response behavior of fibers is induced in yarn muscles successfully by virtue of weakening the water-repellent effect of wool scales. Wool artificial muscles are cost-effective and widely available and have good biocompatibility. In addition, wool fiber assemblies are structurally stable, soft, and flexible to be processed into artificial muscles with torsional, contractile, and even multilayered structures, enabling various wet-driven behaviors. On the basis of the theoretical model and numerical simulation, we explained and verified the working mechanism employed in wool artificial yarn muscles. Finally, the yarn muscle was integrated into a wool muscle group through the textile technology, followed by the application to robot bionic arms, displaying the great potential of wool artificial yarn muscles in bionic drivers and the intelligent textile industry.

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“…In traditional robots, magnetic motors are normally used to produce rotational motion. In previous works, researchers have developed motors driven by soft actuators (Kornbluh et al, 1998;Anderson et al, 2010Anderson et al, , 2011O'Brien et al, 2010;Hwang and Higuchi, 2014;Ainla et al, 2017). Ainla et al developed a motor based on a pneumatic actuator that functions by feeding air into a flexible structure (Diesel and Brock, 2013;Cacucciolo et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

A Deformable Motor Driven by Dielectric Elastomer Actuators and Flexible Mechanisms

et al. 2019

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Soft robots with dynamic motion could be used in a variety of applications involving the handling of fragile materials. Rotational motors are often used as actuators to provide functions for robots (e.g., vibration, locomotion, and suction). To broaden the applications of soft robots, it will be necessary to develop a rotational motor that does not prevent robots from undergoing deformation. In this study, we developed a deformable motor based on dielectric elastomer actuators (DEAs) that is lightweight, consumes little energy, and does not generate a magnetic field. We tested the new motor in two experiments. First, we showed that internal stress changes in the DEAs were transmitted to the mechanism that rotates the motor. Second, we demonstrated that the deformable motor rotated even when it was deformed by an external force. In particular, the rotational performance did not decrease when an external force was applied to deform the motor into an elliptical shape. Our motor opens the door to applications of rotational motion to soft robots.

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A Rotary Actuator Using Shape Memory Alloy (SMA) Wires

Cited by 36 publications

References 24 publications

Internal Short Circuit Trigger Method for Lithium-Ion Battery Based on Shape Memory Alloy

Internal Short Circuit Trigger Method for Lithium-Ion Battery Based on Shape Memory Alloy

Wet-Driven Bionic Actuators from Wool Artificial Yarn Muscles

A Deformable Motor Driven by Dielectric Elastomer Actuators and Flexible Mechanisms

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