Structural Design of Micro Heat Pipe Array Temperature Difference Power Generation System

Wei Wang; Li Wan

doi:10.54691/f5qrqt16

Authors

Wei Wang
Li Wan

DOI:

https://doi.org/10.54691/f5qrqt16

Keywords:

Microheat Pipe Array; Semiconductor; High Heat Flux Density; Thermoelectric Power Generation.

Abstract

The article applies both semiconductor thermoelectric power generation technology and micro heat pipe array heat dissipation technology to the utilization of waste heat from high heat flux density devices, achieving waste heat recovery and power generation from high heat flux density devices. High heat flux density devices have high heat flux density, micro heat pipe arrays have good heat dissipation ability, while semiconductor thermoelectric power generation technology requires high heat flux density to ensure efficient power generation. This article combines the three organically to achieve efficient waste heat recovery of high heat flux density devices. The experimental results show that the waste heat recovery efficiency of the experimental device is as high as 12%, and the generated electricity can achieve functions such as fan rotation, LED light bulb emission, and incandescent light emission. The entire waste heat power generation system operates with stable performance, no noise, high energy utilization efficiency, and significant energy-saving and emission reduction effects.

Downloads

Download data is not yet available.

References

[1] Zhang Fangli, Yang Qing Research analysis and development overview of miniature heat pipe [J]. Energy conservation, 2019, 38 (5).

[2] Yang Mengcheng, Research on Efficiency of Solar Differential Temperature Power Generation Module Based on Micro-heat Tube Array [D]. Harbin: Northeast China Agricultural University Xue, 2018.

[3] Ji Baoning Research on electric energy conversion and energy matching technology of temperature difference power generation system [D]. Harbin: Harbin Institute of Technology, 2017.

[4] Cheng Fuqiang, Hong Yanji, Zhu Chao Configuration optimization design of bismuth telluride temperature difference power generation module [J]. High voltage technology, 2014, 40 (5): 1599-1604.

[5] Yu Weixiong, Dai Jingmin Temperature control system based on semiconductor refrigeration device [J]. Automation technology and application, 2013 (10): 60-64.

[6] Wang Lishu, Wen Jingchen, Wang Jinfeng, etc Optimization of solar temperature difference power generation system based on micro-heat pipe array [J]. Journal of Agricultural Engineering, 2019, 35 (22): 251-256.