磁电式柔性传感器研究进展

doi:10.13475/j.fzxb.20251205302

Abstract

Abstract:

Significance Serving as a foundational element of the perception layer in the Internet of Things (IoT), flexible sensors have attracted widespread attention by virtue of their excellent flexibility, environmental adaptability, and scene compatibility. They have shown broad application prospects in fields such as medical diagnosis, intelligent control, and energy collection. Furthermore, the integration of electronic technology has opened up unique paths for the performance breakthroughs and function expansion of flexible sensors. However, current flexible sensors still face technical bottlenecks in structural design, performance stability, and large-scale production and application. In order address these challenges and further promote the development of flexible sensors, this paper systematically reviews the research progress of flexible magnetoelectric sensors based on the magnetoelectric effect, providing references for subsequent related application research.

Progress This review focuses on three types of flexible magneto-electric sensors based on Faraday's law of electromagnetic induction, the Hall effect, and the magnetoelastic effect. It systematically elaborates on the three types of sensors' working mechanisms, material selection, preparation processes, and application methods. For sensors based on Faraday's law, the research focuses on blending magnetic particles with polymers and constructing flexible magnetic components and conductive coils through processes such as spinning, weaving, sewing, or printing, thereby enabling energy collection and self-powered sensing for the sensors. Sensors based on the Hall effect are typically fabricated using techniques such as magnetron sputtering and lithography on flexible film substrates, have high sensitivity and stability, and have been applied in wearable devices, human-computer interaction, medical implantation, and other fields. Sensors based on the magnetoelastic effect are usually constructed by blending magnetic particles with elastomers and combining liquid metals, silver-coated yarns, and other flexible conductive materials, have high sensitivity, stretchability, and durability, and are suitable for health monitoring and self-powered biomechanical sensing. The structural design of these flexible magneto-electric sensors has a significant impact on their performance. The influence of different construction methods on the comprehensive performance of the sensors are also extensively explored and discussed.

Conclusion and Prospect Through integrating self-powering operation, sensitive signal detection, and flexible physical forms, flexible magnetoelectric sensors are finding increasingly widespread applications. Future development could focus on designs that coordinate multiple transduction mechanisms, designing cost-effective, efficient and scalable production processes, and further deepening the integration of flexible sensors with smart textiles. These efforts would enhance comfort in wearable use and promote the application of flexible electronics in health monitoring, smart textiles, and the IoT.

Key words: flexible sensor, electromagnetic induction, smart textiles, wearable electronics, self-powered

CLC Number:

TS 101.8

FENG Xiaoli, GONG Junyao, XIA Liangjun, XU Weilin. Research progress in magnetoelectric flexible sensors[J].Journal of Textile Research, 2026, 47(03): 107-117.

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Figures/Tables 5

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References 65

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磁性部分类别(基材-填料)	导电部分	形式	性能				应用	文献
磁性部分类别(基材-填料)	导电部分	形式	电压	电流	灵敏范围	响应时间	应用	文献
Ecoflex-磁铁	铜线圈	块	139 mV	60 mA	0.7~30 kPa	20 ms	智能鞋、智能穿戴	[26]
Ecoflex-NdFeB	铜线圈	块	67.5 μV	无	1.18~764 kPa	16 ms	压敏阵列、智能停车系统	[27]
Ecoflex-NdFeB	导电金属线	纤维	9.1 μV	3.9 μA	无	112 ms	动作传感、智能穿戴	[28]
Ecoflex-NdFeB	碳布	中空柱状体	2.2 mV	无	8.2 kPa	64 ms	磁电压力传感器、自供电	[29]
Ecoflex-NdFeB	SNP打印线圈	海葵形软体机器人	7.3 μV	无	无	40~42 ms	水下监测	[30]
PDMS-NdFeB	液态金属	同轴纤维	0.52 V	14.1 mA	100 kPa	<0.1 s	生物医学设备或软机器	[31]
PDMS-Fe纳米线	Pt、Au线圈	膜+微纤	206.47 μV	约3.12 nA	无	无	能量收集、智能穿戴	[32]
灯心草- TPU-NdFeB	铜线圈	织物	3 V	15 mA	无	无	能量收集、运动及医疗监测	[39]
聚合物条带- NdFeB	铜线圈	织物	14.3 V	31.2 mA	无	50 ms	服装发电机	[40]
间隔织物- Ecoflex-NdFeB	铜线圈	薄膜	319 μV	约100 μA	无	无	智能驾驶、健康监测	[43]
Ecoflex-NdFeB	铜线圈	纤维	90 μV	无	1.11~8.89 kPa	无	人机交互、手势识别	[41]
TPU-NdFeB	导电铜线	纱线	43.9 μV	17.9 μA	无	0.63 s	能量收集、智能穿戴	[42]
Ecoflex-NdFeB	镀银锦纶	织物	4.6 V	15 mA	0.05~6.52 kPa	无	健康监测、远程医疗	[44]

基材	导电部分	形式	灵敏度	应用	文献
PI薄膜、PEEK薄膜	铋膜	薄膜	4 V/T	可穿戴器件、医疗植入、机电磁通量监测	[50]
PI薄膜	石墨烯、镍	薄膜	79 V/(A·T)	可穿戴器件、医疗植入、电子皮肤	[51]
Ecoflex	NdFeB	薄膜	无	仿生皮肤、人机交互	[52]
PI薄膜	Cr/Au	薄膜	4.41 V/(A·T)	生物医学监测、磁场检测、无线远程监测	[53]
PI薄膜	Au	薄膜	1.12 V/(A·T)	可穿戴器件、磁场检测	[54]

磁性部分类别(基材-填料)	导电部分类别	形式	性能					应用		文献
磁性部分类别(基材-填料)	导电部分类别	形式	灵敏度	电压	电流	压力灵敏范围	响应时间	应用		文献
Ecoflex-NdFeB	液态金属芯层纤维	薄膜	无	无	约45 μA	3.5 Pa~ 2 000 kPa	3 ms	健康监测、工厂生产监测	[58]
Ecoflex-NdFeB	Ag涂覆羊毛纱线	薄膜	2.78 nA/kPa	约330 μV	约120 μA	约40 kPa	0.12 s	肌肉康复检测装置	[59]
Ecoflex-NdFeB	导电铜线	薄膜	无	2.84 V	97.17 mA	无	无	物联网设备、局部热疗等	[61]
硅胶-NdFeB	液态金属线圈	薄膜	无	1.38 V	4.77 mA	无	无	个性化医疗、物联网健康监测等	[55]
Ecoflex-NdFeB	铜箔线圈	薄膜	10.65 nA/kPa	无	45.18 nA	8~108 kPa	≤80 ms	运动医疗监测、远程医疗等	[62]
Ecoflex-NdFeB	铜线圈	球	0.95 kPa	约50 mV	约20 mA	0.95~5.67 kPa	50 ms	帕金森病诊断、健康监测等	[63]
Ecoflex-NdFeB	导电纱线	笔	无	无	1.33±0.4 a.u.	20~110 kPa	无	帕金森病诊断、运动评估等	[64]

传感器类型	传感方式	主要结构形式	灵敏度	响应速度级别	信号强度级别	形变能力	能耗	制备复杂程度	典型应用	参考文献
法拉第电磁感应型	动态磁场、形变	膜、块、织物	通过线圈匝数调控	s~ms	(nV~mV)/ (μA~mA) 级别	取决于材料和结构	可自供电传感	一般	运动监测、设备检测	[26,28,31,40,42,65]
霍尔效应型	静态/ 动态磁场	膜	依赖材料	μs~ns	(μV~mV)/mA 级别	通常不具备拉伸形变能力	需要外接电源	较高	电子罗盘、磁场成像	[52-54,59,61,63,65]
磁致弹性效应型	力、形变、磁场	膜、块、织物	由磁导率决定	s~ms	(μV~ mV)/mA级别	取决于磁性体和导电体材料	可自供电传感	中等	电子皮肤、压力检测	[59,62,63,65]

Research progress in magnetoelectric flexible sensors

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