Wearable fiber‐shaped electronic devices have drawn abundant attention in scientific research fields, and tremendous efforts are dedicated to the development of various fiber‐shaped devices that possess sufficient flexibility. However, most studies suffer from persistent limitations in fabrication cost, efficiency, the preparation procedure, and scalability that impede their practical application in flexible and wearable fields. In this study, a simple, low‐cost 3D printing method capable of high manufacturing efficiency, scalability, and complexity capability to fabricate a fiber‐shaped integrated device that combines printed fiber‐shaped temperature sensors (FTSs) with printed fiber‐shaped asymmetric supercapacitors (FASCs) is developed. The FASCs device can provide stable output power to FTSs. Moreover, the temperature responsivity of the integrated device is 1.95% °C⁻¹.

中文翻译：

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通过不对称超级电容器和温度传感器的混合，用于全光纤集成电子设备的3D打印光纤电极

可穿戴式纤维状电子设备在科学研究领域引起了广泛的关注，并且为开发各种具有足够灵活性的纤维状设备付出了巨大的努力。但是，大多数研究都受到制造成本，效率，制备程序和可扩展性方面的持续限制，这阻碍了它们在柔性和可穿戴领域的实际应用。在这项研究中，一种简单，低成本的3D打印方法具有较高的制造效率，可扩展性和复杂性，能够制造将打印的光纤形状温度传感器（FTS）与打印的光纤形状不对称超级电容器相结合的光纤形状的集成设备。 （FASC）已开发。FASCs设备可以为FTS提供稳定的输出功率。而且，^-1。