Textile Triboelectric Nanogenerators Simultaneously Harvesting Multiple “High-Entropy” Kinetic Energies
Xuechao Gang, Zi Hao Guo, Zifeng Cong, Jing Wang, Caiyun Chang, Chongxiang Pan, Xiong Pu, Zhong Lin Wang
Abstract
Distributed renewable kinetic energies are ubiquitous but with irregular amplitudes and frequencies, which, as one category of “high-entropy” energies, are crucial for next-generation self-powered electronics. Herein, we present a flexible waterproof dual-mode textile triboelectric nanogenerator (TENG), which can simultaneously scavenge multiple “high-entropy” kinetic energies, including human motions, raindrops, and winds. A freestanding-mode textile TENG (F-TENG) and a contact-separation-mode textile TENG (CS-TENG) are integrated together. The structure parameters of the textile TENG are optimized to improve the output performances. The raindrop can generate a voltage of up to ∼4.3 V and a current of about ∼6 μA, while human motion can generate a voltage of over 120 V and a peak power density of ∼500 mW m–2. The scavenged electrical energies can be stored in capacitors for powering small electronics. Therefore, we demonstrated a facile preparation of a TENG-based energy textile that is highly promising for kinetic energy harvesting and self-powered electronics.