Publications논문

More Powerful Twistron Carbon Nanotube Yarn Mechanical Energy Harvesters
2023-01-06 14:18:35 조회수390
Zhong Wang1, Tae Jin Mun2, Fernando M. Machado3, Ji Hwan Moon2, Shaoli Fang1, Ali E. Aliev1, Mengmeng Zhang1, Wenting Cai1, Jiuke Mu1, Jae Sang Hyeon2, Jong Woo Park2, Patrick Conlin1, Kyeongjae Cho1, Enlai Gao1, Gang Wan1, Chi Huynh1, Anvar A. Zakhidov1, Seon Jeong Kim2*, Ray H. Baughman2* 1)Alan G. MacDiarmid NanoTech Institute, University of Texas at Dallas 2)Center for Self-Powered Actuation, Department of Biomedical Engineering, Hanyang University 3)Technology Development Center, Federal University of Pelotas 원문 링크 : https://doi.org/10.1002/adma.202201826

Abstract

Stretching a coiled carbon nanotube (CNT) yarn can provide large, reversible electrochemical capacitance changes, which convert mechanical energy to electricity. Here, it is shown that the performance of these “twistron” harvesters can be increased by optimizing the alignment of precursor CNT forests, plastically stretching the precursor twisted yarn, applying much higher tensile loads during precoiling twist than for coiling, using electrothermal pulse annealing under tension, and incorporating reduced graphene oxide nanoplates. The peak output power for a 1 and a 30 Hz sinusoidal deformation are 0.73 and 3.19 kW kg−1, respectively, which are 24- and 13-fold that of previous twistron harvesters at these respective frequencies. This performance at 30 Hz is over 12-fold that of other prior-art mechanical energy harvesters for frequencies between 0.1 and 600 Hz. The maximum energy conversion efficiency is 7.2-fold that for previous twistrons. Twistron anode and cathode yarn arrays are stretched 180° out-of-phase by locating them in the negative and positive compressibility directions of hinged wine-rack frames, thereby doubling the output voltage and reducing the input mechanical energy. 

 
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