Unobstructive and safe-to-wear watt-level wireless charger

IF 12.3 1区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC npj Flexible Electronics Pub Date : 2024-11-08 DOI:10.1038/s41528-024-00363-7
Sangjun Kim, Jonathan Wells, Sarnab Bhattacharya, Hamsi Nathan, Jiaming He, Isabella Tubilla, Heeyong Huh, Pooja Kakani, Ali Farshkaran, Praveenkum Pasupathy, Jianshi Zhou, Emily Porter, Nathan Lazarus, Nanshu Lu
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Abstract

A wearable microgrid that centralizes and distributes harvested energy across different body regions can optimize power utilization and reduce overall battery weight. This setup underscores the importance of developing cable-free wireless power transfer (WPT) systems for mobile and portable devices to eliminate the risks posed by wired connections, especially in dynamic and hazardous environments. We introduce a thin, stretchable, and safe hand band capable of watt-level wireless charging through the widely adopted Qi protocol operating at 130 kHz. The implementation of non-adhesive fabric encapsulation serves to protect the 50-μm-thin spiral copper antenna from mechanical strain, ensuring an overall hand band stretchability of 50%. We also create a stretchable “Ferrofabric”, characterized by a magnetic permeability of 11.3 and a tensile modulus of 75.3 kPa, that provides magnetic shielding for the antenna without compromising wearability. The “Ferrofabric” improves the coil inductance but induces core loss in AC application. By fully understanding and managing loss mechanisms such as the skin effect, proximity effect, core loss, and joule heating, we achieve a wireless charging efficiency of 71% and power delivery of 3.81 W in the kHz frequency range. Our WPT hand band is unobstructive to hand motion and can charge a handheld smartphone as fast as a desktop charger or power a battery-free chest-laminated e-tattoo sensor, with well-managed thermal and electromagnetic safety. Through a holistic electromagnetic, structural, and thermal design, our device culminates in a safe, rugged, and versatile solution for wearable WPT systems.

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无障碍、可安全佩戴的瓦特级无线充电器
可穿戴微电网可将采集到的能量集中并分配到身体的不同区域,从而优化电能利用率并减轻电池总重量。这种设置强调了为移动和便携设备开发无线缆无线电力传输(WPT)系统的重要性,以消除有线连接带来的风险,尤其是在动态和危险环境中。我们介绍了一种轻薄、可拉伸且安全的手带,它能够通过广泛采用的工作频率为 130 kHz 的 Qi 协议进行瓦特级无线充电。采用非粘性织物封装可保护 50 微米薄的螺旋铜天线免受机械应变的影响,确保手环整体可拉伸 50%。我们还创造了一种可拉伸的 "Ferrofabric",其磁导率为 11.3,拉伸模量为 75.3 kPa,可为天线提供磁屏蔽,同时不影响佩戴性。Ferrofabric "提高了线圈电感,但在交流应用中会导致磁芯损耗。通过充分了解和管理损耗机制,如趋肤效应、邻近效应、磁芯损耗和焦耳热,我们实现了 71% 的无线充电效率和千赫频率范围内 3.81 W 的功率输出。我们的 WPT 手带不妨碍手部运动,可以像台式充电器一样快速地为手持智能手机充电,或为无电池的胸前贴片电子纹身传感器供电,同时具有良好的热管理和电磁安全性。通过全面的电磁、结构和热设计,我们的设备最终成为安全、坚固和多功能的可穿戴 WPT 系统解决方案。
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来源期刊
CiteScore
17.10
自引率
4.80%
发文量
91
审稿时长
6 weeks
期刊介绍: npj Flexible Electronics is an online-only and open access journal, which publishes high-quality papers related to flexible electronic systems, including plastic electronics and emerging materials, new device design and fabrication technologies, and applications.
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