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Enhancing electrical output and thermal adaptivity in an interlocked core-sheath triboelectric yarn/fabric for intelligent fire-rescue systems

Zhiyong Peng, Chong Gao, Yingcun Liu, Can Ge, Haoran Gong, Ze Chen, Yuan Qin, Keshuai Liu, Duo Xu, Jian Fang, Weilin Xu

2024Chemical Engineering Journal14 citationsDOIOpen Access PDF

Abstract

Self-powered flexible electronic textiles designed for fire-rescue functions, especially in high-temperature environments, have attracted considerable attention. However, their practical applications are hindered by limited electrical output and poor thermal adaptability. In this study, we develop an interlocked core-sheath triboelectric yarn (ICSTY) employing a well-established braiding process, which comprises an inner layer of braided conductive yarn and an outer layer of loop-piled polyimide yarn. This unique structural design resulted in the ICSTY exhibiting an enhanced electrical output performance of 16.3 V per length of 15 cm and excellent thermal adaptability across a wide temperature range of 25–250 °C. The woven ICSTY fabric demonstrates outstanding thermal insulation and biomechanical energy harvesting compared with existing firefighting uniforms. Furthermore, it can be seamlessly integrated into a self-powered fire-rescue system for motion monitoring, location acquisition, and escape warnings for trapped firefighters. This exceptional ICSTY holds the potential to significantly impact the future development of intelligent firefighting uniforms.

Topics & Concepts

Triboelectric effectYarnCore (optical fiber)ThermalMaterials scienceAutomotive engineeringComputer scienceMechanical engineeringComposite materialEngineeringPhysicsMeteorologyAdvanced Sensor and Energy Harvesting MaterialsTactile and Sensory InteractionsInteractive and Immersive Displays
Enhancing electrical output and thermal adaptivity in an interlocked core-sheath triboelectric yarn/fabric for intelligent fire-rescue systems | Litcius