In-Plane Thermoelectric Generator of Carbon Nanotube Membrane Driven by Thermal Gas Flow

Jiang Lei Lu; Guang Long Wang; Lian Feng Sun; Feng Qi Gao; Jian Hui Chen; Fang Yu; Gang Wang; Hong Pei Wang

doi:10.4028/www.scientific.net/AMM.217-219.226

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 217-219In-Plane Thermoelectric Generator of Carbon...

In-Plane Thermoelectric Generator of Carbon Nanotube Membrane Driven by Thermal Gas Flow

Abstract:

The in-plane thermoelectric generator (TEG) was ingeniously designed when the thermal gas flowed over the carbon nanotube (CNT) membrane at the modest speed of a few meters per second. It was composed of the glass substrate, aurum electrodes and CNT membrane synthesized by a floating catalyst chemical vapor deposition method. In the air under atmospheric pressure, the experimental results showed that the maximal output voltage could reach 1.7 mV. It related not only with the temperature difference between the hot-side and cold-side, but also the temperature gradient of the CNT membrane which was closely dependent on the velocity and temperature of the gas flow. The multi-physical power mechanism was applied to interpret the energy conversion, which included the coupling relation of the fluid dynamics, heat transmission and Seebeck effect. This novel method could effectively enhance the output voltage, extend the applied range of TEG and had a fine prospect.