He Yu, Shiliang Zhang, Yunlu Lian, Mingxiang Liu, Mingyuan Wang, Jiamin Jiang, Chong Yang, Shengwang Jia, Maoyi Wu, Yulong Liao, Jun Gou, Yadong Jiang, Jun Wang, Guangming Tao
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Through a co-designed architecture comprising a spectrally selective passive cooling structure and intricate hierarchical sensing construction, the monolithic integrated CET demonstrates superior sensitivity (6.67 × 10<sup>3</sup> kPa<sup>−1</sup>), remarkable stability, and excellent wearable properties, such as flexibility, lightweightness, and thermal comfort, while achieving maximum temperature reduction of 21 °C. In contrast to the limitations faced by existing devices that offer low signal quality during overheating, CET presents accurately stable performance output even in rugged external environments. 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引用次数: 0
摘要
摘要 在炎热的室外环境中监测健康状况的软性可穿戴电子设备非常受欢迎,因为它们能有效地保护个人免受与全球气候变化相关的热相关疾病的侵袭。然而,传统的可穿戴设备在暴露于室外太阳辐射时存在局限性,包括电气性能降低、寿命缩短和皮肤灼伤的风险。在这项工作中,我们引入了一种被称为冷却电子织物(CET)的新方法,它能确保在强烈的外部条件下可靠、准确地跟踪不间断的生理信号,同时保持设备始终处于低温状态。通过由光谱选择性被动冷却结构和错综复杂的分层传感结构组成的共同设计架构,单片集成式 CET 显示出卓越的灵敏度(6.67 × 103 kPa-1)、显著的稳定性和出色的可穿戴特性,如灵活性、轻便性和热舒适性,同时实现最高 21 °C的降温。与现有设备在过热时信号质量低的局限性相比,CET 即使在恶劣的外部环境中也能提供精确稳定的性能输出。这项研究提出了一种创新方法,可为户外应用量身定制的下一代纺织电子产品提供有效的热管理。
Electronic Textile with Passive Thermal Management for Outdoor Health Monitoring
Soft and wearable electronics for monitoring health in hot outdoor environments are highly desirable due to their effectiveness in safeguarding individuals against escalating heat-related illnesses associated with global climate change. However, traditional wearable devices have limitations when exposed to outdoor solar radiation, including reduced electrical performance, shortened lifespan, and the risk of skin burns. In this work, we introduce a novel approach known as the cooling E-textile (CET), which ensures reliable and accurate tracking of uninterrupted physiological signals in intense external conditions while maintaining the device at a consistently cool temperature. Through a co-designed architecture comprising a spectrally selective passive cooling structure and intricate hierarchical sensing construction, the monolithic integrated CET demonstrates superior sensitivity (6.67 × 103 kPa−1), remarkable stability, and excellent wearable properties, such as flexibility, lightweightness, and thermal comfort, while achieving maximum temperature reduction of 21 °C. In contrast to the limitations faced by existing devices that offer low signal quality during overheating, CET presents accurately stable performance output even in rugged external environments. This work presents an innovative method for effective thermal management in next-generation textile electronics tailored for outdoor applications.
期刊介绍:
Advanced Fiber Materials is a hybrid, peer-reviewed, international and interdisciplinary research journal which aims to publish the most important papers in fibers and fiber-related devices as well as their applications.Indexed by SCIE, EI, Scopus et al.
Publishing on fiber or fiber-related materials, technology, engineering and application.
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