聚偏氟乙烯-三氟乙烯共聚物摩擦纳米发电织物制备及其输出功率提升

doi:10.13475/j.fzxb.20250400801

摘要/Abstract

摘要： 针对基于摩擦纳米发电机(TENG)技术的织物存在输出功率较低、灵活性较差的问题,设计了一种接触分离模式的单电极结构TENG织物与一种微型对针状空气击穿器件,采用静电纺丝技术制备纳米纤维堆叠构成织物,并通过精密定位平台控制2枚钨放电针的间距,构造微米级(20~110 μm)的间隙,使摩擦纳米发电织物工作时在外电路形成空气击穿,提升输出功率,并缩小器件尺寸实现高灵活性。同时探讨放电针间距与角度、外部起电条件和环境湿度对输出功率的影响。结果表明:接入空气击穿器件后的TENG织物最高可产生532 V的开路电压和5.9 μA的短路电流,较接入前电压提升1.75倍,电流提升约2倍;接入负载后的最佳匹配电阻降低为击穿前的十分之一,功率提升约1.4倍,且表现出超5 000次的循环稳定性以及不同环境湿度下的服役稳定性,最终可实现点亮33个串联LED灯珠并驱动电子手表工作。

关键词: 静电纺丝, 柔性电子织物, 摩擦纳米发电机技术, 空气击穿器件, 输出功率, 单电极

Abstract:

Objective Wearable electronics has gained popularity in daily life, yet their energy supply remains a critical challenge. Triboelectric nanogenerator (TENG), which harvest low-frequency human motion energy through contact electrification and electrostatic induction, offer a promising solution as flexible electronic textiles. However, conventional TENG fabrics suffer from high internal resistance and low power output due to limited surface charge density and interfacial impedance mismatch, failing to meet practical device requirements. Addressing these limitations by reducing internal resistance and enhancing power generation efficiency is imperative to advance TENG textiles as viable, high-performance power sources for autonomous wearable systems.

Method In this paper, a miniature pair of needle-like devices is introduced to assist air breakdown in TENG fabrics for enhanced output power. Polyvinylidene fluoride-trifluoroethylene (P(VDF-TrFE)) nanofibers are electrospun as friction materials onto conductive fiber cloth electrodes using electrostatic spinning technology to prepare single-electrode flexible TENG fabrics operating in contact-separation mode. These components are precisely assembled using positioning platforms and 3D printing technology. The air-breaking device featuring a paired needle structure was systematically evaluated for both output performance and wearability when integrated with the triboelectric fabric system.

Results Through precise fabrication of tip discharge gaps (20-110 μm) using a micropositioning system, the resulting breakdown threshold voltages followed Paschen's law with measured values of 70 V (20 μm), 90 V (30 μm), 150 V (50 μm), 230 V (80 μm), and 350 V (110 μm). The integrated air-breakdown devices dramatically improved the triboelectric fabric's performance, elevating the open-circuit voltage by 170% (from 230 V to 390 V), doubling the short-circuit current (0.9 μA to 1.8 μA) and increasing transferred charge by 267% (30 nC to 110 nC), while scalability tests showed area-proportional enhancements with peak outputs reaching 532 V and 5.9 μA. The modified fabric exhibited excellent environmental stability across 40%-80% RH conditions, maintaining doubled current output compared to baseline devices, along with robust cyclic durability demonstrated by a stable 5.2 μA open-circuit current after 5 000 mechanical cycles and the ability to charge a 2 μF capacitor to 20 V within 60 s at 2 Hz operation (20% RH). Power optimization studies revealed a 33% boost in maximum load power (from 45 μW to 60 μW) coupled with a tenfold reduction in optimal load resistance (from 5×10⁸ Ω to 5×10⁷ Ω), enabling practical applications such as powering 33 serially connected LEDs and operating digital watches.

Conclusion This work develops lightweight, flexible TENG textiles with enhanced power output through strategic air breakdown engineering. By integrating micro-engineered needle pairs fabricated via precision positioning and additive manufacturing, submillimeter discharge gaps are created to concentrate electric fields, effectively lowering air ionization thresholds while maintaining compact device dimensions. This approach addresses intrinsic limitations of conventional TENG fabrics—notably high internal resistance and insufficient power density—through optimized charge transport pathways. The modified textiles demonstrate exceptional humidity resilience (40%-80% RH) and operational durability (5 000 cycles), successfully powering wearable electronics. These advancements establish a scalable framework for next-generation energy-autonomous textiles, addressing critical challenges in sustainable power supply for flexible IoT systems.

Key words: electrospinning, flexible E-textile, triboelectric nanogenerator technology, air breakdown device, output power, single-electrode

中图分类号:

TS10

胡新阳, 王宏志. 聚偏氟乙烯-三氟乙烯共聚物摩擦纳米发电织物制备及其输出功率提升[J]. 纺织学报, 2025, 46(12): 92-100.

HU Xinyang, WANG Hongzhi. Preparation of poly(vinylidene fluoride-trifluoride-trifluoroethylene)copolymer-based triboeletric nanogenerator and enhancement of its output power[J]. Journal of Textile Research, 2025, 46(12): 92-100.

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链接本文: http://www.fzxb.org.cn/CN/10.13475/j.fzxb.20250400801

http://www.fzxb.org.cn/CN/Y2025/V46/I12/92

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