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. 2021 Dec 1;8:37. doi: 10.1186/s40580-021-00289-0

Table 6.

TENG, PENG, TEG and EMG based 3D printed hybrid MEH devices, their output energy capacities and applications

Energy harvesting devices Source of excitation Excitations Materials Output Applications
Hybrid EMG-TENG wrist-wearable device Human wrist-motions 5 Hz ABS, PLA 0.118 mW/cm3 Wearable healthcare monitoring equipment
Hybrid EMG-TENG-PENG 3DAIS device 3D vibration, rotation & human motion 2.5 Hz Acrylic 0.19 µW Inertial sensing
Hybrid EMG-TENG wind-driven nanogenerator Slow speed wind 6 m/s PLA 245 mW Subway tunnel monitoring sensors
Hybrid EMG-TENG device resonating at low frequency Manual vibrations 18 Hz ABS 2.61 mW Vibration study

Hybrid TENG-EMG-PENG

energy harvester

Hybrid step-servo motor 45 rpm (0.75 Hz) ABS 712 μW, 31 mW, 6.4 μW
Solar & electromagnetic Energy harvesting System Solar irradiance 100 mW/cm2 PLA 93 mW Internet-of-Things
3D printed miniature EMG device driven by airflow Wind energy, wind tunnel ABS 0.305 W HVAC (heating, ventilating, and air conditions) ventilation exhaust systems
Hybrid EMG-TENG rotating gyro structured blue EH Blue energy 1.2 to 2.3 Hz White resin 14.9 mW (EMG) 4.1 μW (TENG) Self-powered and self-functional tracking system
Ship-shaped hybridized nanogenerator (SHNG) Blue energy (linear motor) 2 Hz PLA 800 µW (TENG) 9 mW (EMG) Seawater self-desalination and self-powered positioning

The references of the research papers cited in this table are provided in the Additional file 1

EMG electromagnetic generator, TENG triboelectric nanogenerator, PENG piezoelectric nanogenerator, 3DAIS 3D activity inertial sensor, ABS acrylonitrile poly-butadiene styrene, PLA polylactic acid, EH energy harvester