Journal of Textile Research ›› 2019, Vol. 40 ›› Issue (09): 75-82.doi: 10.13475/j.fzxb.20180804308

• Textile Engineering • Previous Articles     Next Articles

Action mechanism of wearing pressure on electrocardiogram monitoring of woven fabric electrodes

DONG Ke, ZHANG Ling, FAN Jiaxuan, LI Mengjie, MEI Lin, XIAO Xueliang()   

  1. Key Laboratory of Eco-Textiles (Jiangnan University), Ministry of Education, Wuxi, Jiangsu 214122, China
  • Received:2018-08-13 Revised:2019-05-06 Online:2019-09-15 Published:2019-09-23
  • Contact: XIAO Xueliang E-mail:xiao_xueliang@jiangnan.edu.cn

RichHTML

1

PDF (PC)

117

Abstract:

In order to explore the effect of wear pressure on the quality of electrocardiogram(ECG) signals collected by textile structure ECG electrodes, four conductive fabric electrodes based on plain and satin structure were developed using silver-plated nylon tow and polyester, the performance of the fabric electrode was evaluated from skin-electrode contact resistance, comfort and the relationship between fabric resistance and wear pressure. The ECG signal acquisition performance of four different fabric electrodes under different wearing pressures(2,5,10 kPa) was also tested. The experimental results show that fabric electrodes with different structures are different in ECG signal acquisition capability and comfort under different wearing pressures. As the wear pressure increases, the surface resistance of the conductive fabric first decreases and then stabilizes, and the ECG signal quality is higher. The pure conductive satin structure fabric has better air permeability and moisture permeability, and the comfort ability is better than that of the plain structure fabric. The plain structure electrode shows better ECG signal quality under comfortable wear pressure (2, 5 kPa).

Key words: fabric electrode, electrocardiogram signal, wearable pressure, comfortability

CLC Number: 

  • TS101.2

Fig.1

SEM images of silver-coated nylon filament. (a) Silver-coated nylon tow; (b) Cross seciton of silver-coated nylon filament; (c) Conductive nylon filament with silver-coated layer"

Tab.1

Specifications of conductive woven fabrics"

织物
编号		 组织结构 组成 经向密度/
(根·(10 cm)-1)		 纬向密度
(根·(10 cm)-1)
经纱 纬纱
PCN 平纹 镀银锦纶丝 涤纶 394 315
PCC 平纹 镀银锦纶丝 镀银锦纶丝 394 315
SCN 五枚三飞经面缎纹 镀银锦纶丝 涤纶 394 315
SCC 五枚三飞经面缎纹 镀银锦纶丝 镀银锦纶丝 394 315

Fig.2

Fabric sample"

Fig.3

Principle of skin-electrode impedance measurement"

Fig.4

Test of surface pressure and surface resistance of fabric; (a) Test model diagram;(b) Fabric surface pressure and resistance test"

Fig.5

Wearable ECG acquisition system. (a) Wearable ECG signal monitoring system schematic diagram; (b) Belt wearable ECG collection clothing"

Tab.2

Tested conductive fabric performance"

织物
编号		 透气性/
(mm·
s-1)		 透湿性/
(g·m-2
(24 h)-1)		 织物
方阻/
(Ω·□-1)		 皮肤-电极
界面阻抗/
PCN 623.2 660.4 12.810 0.645
PCC 717.7 990.6 0.122 0.225
SCN 1 834.4 566.0 5.010 0.241
SCC 2 285.0 896.2 0.118 0.110

Fig.6

Relationship between pressure and resistance of conductive fabric samples. (a) Semi-conductive fabrics;(b) Pure conductive fabrics"

Fig.7

ECG signals collected by fabric electrodes prepared from conductive fabrics"

[1] 周旺, 贾天震, 陈贤祥, 等. 可穿戴医疗健康监护现状与展望[J]. 中国医疗设备, 2017,32(6):1-5.
ZHOU Wang, JIA Tianzhen, CHEN Xianxiang, et al. Current status and prospects of wearable medical health monitoring[J]. China Medical Equipment, 2017,32(6):1-5.
[2] 肖学良, 董科, 何文涛, 等. 可穿戴电子服装中织物电极的研究进展[J]. 服装学报, 2017,2(1):1-6.
XIAO Xueliang, DONG Ke, HE Wentao, et al. Research progress of fabric electrodes in wearable electronic clothing[J]. Journal of Clothing Research, 2017,2(1):1-6.
[3] LIU Z, LIU X X. Progress on fabric electrodes used in biological signal acquisition[J]. Journal of Minerals and Materials Characterization and Engineering, 2015,3(3):204-214.
doi: 10.4236/jmmce.2015.33023
[4] 严妮妮. 心电监测服装的可穿戴性能研究[D]. 西安:西安工程大学, 2015: 1-104.
YAN Nini. Research on wearable performance of ECG monitoring clothing[D]. Xi'an: Xi'an Polytechnic University, 2015: 1-104.
[5] REINEL C, PÉREZ J, ANDRADE C. Electrical performance of PEDOT:PSS-based textile electrodes for wearable ECG monitoring: a comparative study[J]. Biomedical Engineering Online, 2018,17(1):1-38.
doi: 10.1186/s12938-017-0432-x pmid: 29310661
[6] 许鹏俊. 用于体表心电监测的纺织结构电极与皮肤之间机械作用分析及动态噪音研究[D]. 上海:东华大学, 2012: 3-21.
XU Pengjun. Mechanical analysis and dynamic noise between textile structure electrodes and skin for surface ECG monitoring[D]. Shanghai: Donghua University, 2012: 3-21.
[7] 贾高鹏, 曾春梅, 樊理山. 电极压力变化对针织物电阻的影响[J]. 纺织导报, 2014(12):90-92.
JIA Gaopeng, ZENG Chunmei, FAN Lishan. The effect of electrode pressure change on the resistance of knitted fabrics[J]. China Textile Leader, 2014(12):90-92.
[8] ALI A, BAHETI V, MILITKY J, et al. Utility of silver-coated fabrics as electrodes in electrotherapy applica-tions[J]. Journal of Applied Polymer Science, 2018,135(23):46357-46367.
doi: 10.1002/app.46357
[9] 张红霞, 陆艳, 田伟, 等. 镀银纤维含量对织物抗菌性能的影响[J]. 纺织学报, 2011,32(9):38-41.
ZHANG Hongxia, LU Yan, TIAN Wei, et al. Effects of silver-plated fiber content on antibacterial properties of fabrics[J]. Journal of Textile Research, 2011,32(9):38-41.
[10] 邱茂伟, 王府梅. 机织物透气性能的预测研究[J]. 纺织学报, 2005,26(4):73-75.
QIU Maowei, WANG Fumei. Prediction of venting properties of woven fabrics[J]. Journal of Textile Research, 2005,26(4):73-75.
[11] 袁会锦, 张辉, 谢光银. 织物结构对纺织结构电极阻抗性能的影响[J]. 纺织学报, 2015,36(9):44-49.
YUAN Huijin, ZHANG Hui, XIE Guangyin. Effect of fabric structure on the impedance properties of textile structure electrodes[J]. Journal of Textile Research, 2015,36(9):44-49.
[12] XIAO X L, HU J, HUA T, et al. Through-thickness air permeability of woven fabric under low pressure compression[J]. Textile Research Journal, 2015,85(16):1732-1742.
doi: 10.1177/0040517515569526
[13] 黄建华, 钱晓明. 织物透湿性测试方法的比较[J]. 纺织学报, 2008,29(8):45-47.
HUANG Jianhua, QIAN Xiaoming. Comparison of test methods for fabric moisture permeability[J]. Journal of Textile Research, 2008,29(8):45-47.
[14] KANNAIAN T, NEELAVENI R, THILAGAVATHI G, et al. Design and development of embroidered textile electrodes for continuous measurement of electrocardiogram signals[J]. Journal of Industrial Textile, 2012,42(3):303-318
doi: 10.1177/1528083712438069
[15] XIAO X L, PIRBHULAL S, DONG K, et al, Performance evaluation of plain weave and honeycomb weave electrodes for human ECG monitoring[J]. Journal of Sensors, 2017(6):1-13.
[16] 李春兰, 武惠敏, 侯鹏, 等. 三导联同步心脏远程监测系统的临床应用[J]. 甘肃医药, 2013,32(2):115-117.
LI Chunlan, WU Huimin, HOU Peng, et al. Clinical application of three-lead synchronous cardiac remote monitoring system[J]. Gansu Medicine, 2013,32(2):115-117.
[1] DONG Ke, LI Siming, WU Guanzheng, HUANG Hongrong, LIN Zhongshi, XIAO Xueliang. Preparation and properties of carbon fiber / polyester electrocardiogram monitoring embroidery electrode [J]. Journal of Textile Research, 2020, 41(01): 56-62.
[2] . Moisture absorption and sweat transport finishing o meta-aramid fabrics [J]. JOURNAL OF TEXTILE RESEARCH, 2018, 39(05): 80-86.
[3] DIAO Caihong;XIAO Changfa;HU Xiaoyu;MA Yanxia. Hydrophilic multi-porous polyacrylonitrile fiber and comfortability of its product [J]. JOURNAL OF TEXTILE RESEARCH, 2010, 31(7): 11-15.
[4] WU Zhiming;WANG Meili. Sectional design of sports bra based on comfortability [J]. JOURNAL OF TEXTILE RESEARCH, 2010, 31(4): 103-108.
[5] SUN Jie;SHAO Feiying;WANG Haibo. Cmfortableness of T/C fabrics finished with γ-poly glutamic acid [J]. JOURNAL OF TEXTILE RESEARCH, 2009, 30(04): 65-68.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
京ICP备14006648号
Copyright 2021 © Editorial office of Journal of Textile Research
Supported by Beijing Magtech Co.Ltd