Materials Reports  2020, Vol. 34 Issue (Z1): 490-497 |
| POLYMERS AND POLYMER MATRIX COMPOSITES |
|
|
|
|
|
| Research Progress of Fibers and Fabrics Based Flexible Wearable Devices |
| MA Xiangyu, XIA Guangbo, QIU Linlin, DONG Lika, DING Mingle, DU Pingfan
|
| College of Textile Science and Engineering, Zhejiang Sci-Tech University, Hangzhou 310018, China |
|
|
|
|
Abstract In recent years, the field of wearable devices has been becoming a research hotspot with the rapid development of intelligent technologies. In practical applications, flexible wearable devices, especially fiber/fabric-based devices, have broader prospects because they provide a new strategy for solving the problems such as poor comfortability, washability, and flexibility. Also, it is a better idea from the point of environmental protection. Therefore, the research is of great realistic significance. This paper introduces several typical flexible wearable devices first, and the advance in flexibility of wearable devices is briefly introduced as well. Then, the preparation methods and classification of fiber/fabric-based devices is overviewed. Finally, their latest applications in wearable fields such as flexible sensors, energy devices, and electrodes are reviewed in detail. In summary, with the integration of materials science, textile technology and microelectronics technology, to fabricate more textile-structured flexible devices through systematic design and integrated molding is an objective requirement and inevitable trend for the further development of wearable products.
|
|
Published: 01 July 2020
|
|
|
| Fund:This work was financially supported by Zhejiang Provincial Natural Science Foundation of China (LY18F050011), Applied Basic Research Project of China National Textile and Apparel Council (J201801), and National Undergraduates' Innovation and Entrepreneurship Training Program (201810338024). |
| About author:: Xiangyu Ma received her B.S. degree in nonwoven materials and engineering from Jiaxing University in 2018. She is currently pursuing her M.S. degree at College of Textile Science and Engineering, Zhejiang Sci-Tech University under the supervision of associate Prof. Pingfan Du. Her research focuses on wearable flexible energy devices with textile structure ; Guangbo Xia is an undergraduate student of College of Textile Science and Engineering, Zhejiang Sci-Tech University. The main research directions are wearable flexible materials and devices, intelligent textiles and so on. He is presiding over one National Undergraduate Training Program for Innovation and Entrepreneurship, participated in one Applied Basic Research Project of China National Textile and Apparel Council ; Pingfan Du, Ph. D., is an associate professor and Master's supervisor of College of Textile Science and Engineering, Zhejiang Sci-Tech University, and he is a Young and Middle-aged Academic Leader in Zhejiang Provincial Colleges and Universities. His research inte-rests mainly focus on wearable flexible energy devices with textile structure, intelligent textiles, functional textiles, and so on. He has presided over more than 10 scientific research projects, such as National Natural Science Foundation of China, Zhejiang Provincial Natural Science Foundation of China and Applied Basic Research Project of China National Textile and Apparel Council, published 40 SCI/EI papers, and obtained 11 authorized invention patents. His doctoral thesis won the third “Wang Shanyuan Outstanding Doctoral Thesis Foundation” award. He was a visiting scholar at North Carolina State University from Jan. 2018 to Jan. 2019. |
|
|
1 Rossi D D, Santa A D, Mazzoldi A. Materials Science and Engineering C,1999,7(1),31.
2 Kuhn H H, Kimbrell W C, Worrell G, et al.In: Annual Technical Conference-ANTEC,1991,pp.760.
3 Oh K W, Park H J, Kim S H. Journal of Applied Polymer Science,2003,88(5),1225.
4 Xue P, Tao X M, Yu T X, et al. Textile Research Journal,2004,74(10),929.
5 封顺天.信息通信技术,2014,8(3),52.
6 李艳.微型电脑应用,2018,34(10),68.
7 卢忠花,王卿璞,鲁海瑞,等.微纳电子技术,2014,51(11),685.
8 李扬.高科技与产业化,2013(10),82.
9 张莉.通讯世界,2015(15),250.
10 http://phone.cnmo.com/news/659471.html.
11 耿怡,安晖,李扬,等.电子科学技术,2014,1(2),238.
12 王栋,卿星,蒋海青,等.纺织学报,2018,39(5),150.
13 White A. USP patent,5423956,1995.
14 李昕.轻纺工业与技术,2013,42(6),51.
15 Liu Q, Wang B, Chen J, et al. Composites Part A: Applied Science & Manufacturing,2017,101,30.
16 Tao Y, Liu Q, Chen J, et al. Environmental Science & Technology,2016,50(14),7889.
17 Wang Y D, Qing X, Zhou Q, et al. Biosensors & Bioelectronics,2017,95,138.
18 Tao X M. Smart fibres, fabrics and clothing, Woodhead Publishing, UK,2001.
19 Paradiso R, Loriga G, Taccini N. IEEE Transactions on Information Technology in Biomedicine,2005,9,337.
20 Pasquale E, Lorussis F, Mazzoldi A, et al. IEEE Sensors Journal,2003,3,460.
21 Meyer J, Arnrich B, Schumm J, et al. Sensors Journal,2010,10(8),1391.
22 王非.多媒体世界,2002(10),32.
23 Zhang H, Tao X M, Wang S Y, et al. Textile Research Journal,2005,75(8),598.
24 Wang D, Sun G, Chiou B S. Macromolecular Materials & Engineering,2010,292(4),407.
25 中国纺织网.化纤与纺织技术,2018,47(4),30.
26 Tao X M. Handbook of smart textiles, Springer, Germany,2015.
27 曾天禹,黄显.科技导报,2017,35(2),19.
28 Zhang M C, Wang C Y, Wang H M, et al. Advanced Functional Mate-rials,2017,27(2),1604795.
29 娄正,沈国震.新材料产业,2017(10),55.
30 Heo J S, Eom J, Kim Y H, et al. Small,2017,14(3),1703034.
31 Gautschi G. Piezoelectric sensors, Springer, Germany,2002.
32 Jonckheere J D, Narbonneau F, Kinet D, et al. In: 30th Annual International IEEE EMBS Conference, Canada,2008,pp.5266.
33 马艳丽,刘茜,刘玮.传感器与微系统,2015,34(4),1.
34 黄文杰,左洪福.航空学报,2013,34(8),1786.
35 Kang T H. Textile-embedded sensors for flexible physiological monitoring. Ph.D. Thesis, Duke University, USA,2006.
36 Qu G X, Cheng J L, Li X D, et al. Advanced Materials,2016,28,3646.
37 Sun H, Xie S, Li Y, et al. Advanced Materials,2016,28,8431.
38 Xin M, Bin S, Shi C, et al. Energy Storage Materials,2019,16,597.
39 Wu C X, Kim T W, Li F S, et al. ACS Nano,2016,10(7),6449.
40 吴云,刘茜.棉纺织技术,2018,46(6),79. |
|
|
|
渝公网安备50019002502923号 © Editorial Office of Materials Reports.
