材料科学
执行机构
软机器人
复合数
纺纱
纱线
弹性体
机器人学
人工肌肉
稳健性(进化)
复合材料
智能材料
机械工程
计算机科学
机器人
人工智能
工程类
基因
化学
生物化学
作者
Kaiyue Qi,Xiaocui Zhang,Junhua Zhang,Ling Xu,Anjing Wei,Qufu Weı,Dingsheng Wu
标识
DOI:10.1021/acsami.5c07674
摘要
Fiber-based actuators, including liquid crystal elastomer (LCE) fibers, have the capacity to convert external stimuli into mechanical motion, which lends them promising applications in soft robotics and wearable systems. However, conventional LCE fibers have been found to exhibit poor mechanical robustness and a single pattern of stimulus response. In this study, we have facily fabricated a LCE composite yarn actuator that exhibits both enhanced mechanical strength and the capacity for multistimulus response properties. This has been achieved by combining dry spinning with textile twisting technologies. The actuator demonstrates a uniform radial size of the fiber (360 ± 10 μm) and exhibits remarkable breaking strength (199.2 MPa), rapid stable response deformation (35% within 6.5s), and good stability during long-term use and solves the creep problem inherent in the traditional LCE fibers. As a proof of concept, a novel smart fabric has been developed through the integration of an actuator substrate based on textile processing technology. This smart fabric demonstrates a multifaceted response to thermal, optical, and electrical stimuli along with precise manipulation capabilities and sustained stability. The actuator's performance demonstrates considerable promise for implementation in soft robotics, advanced wearable technologies, and next-generation flexible electronic systems.
科研通智能强力驱动
Strongly Powered by AbleSci AI