Triboelectric Nanogenerator-Based Vibration Energy Harvester Using Bio-Inspired Microparticles and Mechanical Motion Amplification

In this work, the novel design of a sliding mode TriboElectric Nano Generator (TENG)-which can utilize vibration amplitude of a few hundred microns to generate useful electric power-is proposed for the first time. Innovative design features include motion modification to amplify relative displacement of the TENG electrodes and use of biological material-based micron-sized powder at one of the electrodes to increase power output. The sliding mode TENG is designed and fabricated with use of polyurethane foam charged with the biological material micropowder and PolyTetraFluoroEthylene (PTFE) strips as the electrodes. Experimentations on the prototype within frequency range of 0.5-6 Hz ensured peak power density of 0.262 mW/m(2), corresponding to the TENG electrode size. Further numerical simulation is performed with the theoretical model to investigate the influence of various design parameters on the electric power generated by the TENG. Lastly, application of the proposed TENG is demonstrated in a wearable device as an in-shoe sensor. Conceptual arrangement of the proposed in-shoe sensor is presented, and numerical simulations are performed to demonstrate that the real size application can deliver peak power density of 0.747 mW/m(2) and TENG; the voltage will accurately represent foot vertical force for various foot force patterns.

Automated summary

In this paper, a novel design of sliding mode TriboElectric Nano Generator (TENG) is proposed for the first time, which can generate useful electric power using vibration amplitude of a few hundred microns. The design includes motion modification to amplify relative displacement of the TENG electrodes and the use of biological material-based micron-sized powder to increase power output. Experimental and numerical simulation results demonstrate the feasibility and efficiency of the proposed TENG design. Additionally, the application of the TENG in a wearable device as an in-shoe sensor is demonstrated, showing its potential for various foot force patterns.