Energy harvesting model of moving water inside a tubular system and its application of a stick-type compact triboelectric nanogenerator
作者: Dongwhi Choi , Sangmin Lee , Sang Min Park , Handong Cho , Woonbong Hwang
DOI: 10.1007/S12274-015-0756-4
关键词: Nanogenerator 、 Energy harvesting 、 Mechanical engineering 、 Nanotechnology 、 Electricity 、 Contact electrification 、 Mechanical energy 、 Materials science 、 Voltage 、 Swing 、 Triboelectric effect
摘要: As the first invention to efficiently harvest electricity from ambient mechanical energy by using contact electrification, triboelectric nanogenerator has elicited worldwide attention because of its cost-effectiveness and sustainability. This study exploits a superhydrophobic nanostructured aluminum tube estimate electrical output for solid-water electrification inside tubular system. The linearly proportional relationship short-circuit current open-circuit voltage detaching speed water was determined theoretical harvesting model experimentation. A pioneering stick-type interacting nanogenerator, called SWING stick, developed through generated when device is shaken hand. various kinds environment also measured demonstrate concept stick as compact nanogenerator. Several sticks were connected show feasibility portable source direct power. can provide guideline design parameters attain desired output; therefore, this significantly increase applicability water-driven
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