Transport phenomena and performance of a plate methanol steam micro-reformer with serpentine flow field design

A numerical investigation of the transport phenomena and performance of a plate methanol steam micro-reformer with serpentine flow field as a function of wall temperature, fuel ratio and Reynolds number are presented. The fuel Reynolds number and H 2O/CH 3OH molar ratio (S/C) that influence the tran...

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Bibliographic Details
Published in:Applied energy 2010-10, Vol.87 (10), p.3137-3147
Main Authors: Hsueh, Ching-Yi, Chu, Hsin-Sen, Yan, Wei-Mon, Chen, Chiun-Hsun
Format: Article
Language:English
Subjects:
Alternative fuels. Production and utilization
Applied sciences
Energy
Exact sciences and technology
Fuels
Hydrogen
Micro-reformer
Micro-reformer Serpentine flow field Three-dimensional model Transport phenomena
Serpentine flow field
Three-dimensional model
Transport phenomena
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Summary:A numerical investigation of the transport phenomena and performance of a plate methanol steam micro-reformer with serpentine flow field as a function of wall temperature, fuel ratio and Reynolds number are presented. The fuel Reynolds number and H 2O/CH 3OH molar ratio (S/C) that influence the transport phenomena and methanol conversion are explored in detail. In addition, the effects of various wall temperatures on the plates that heat the channel are also investigated. The predictions show that conduction through the wall plays a significant effect on the temperature distribution and must be considered in the modeling. The predictions also indicate that a higher wall temperature enhances the chemical reaction rate which, in turn, significantly increases the methanol conversion. The methanol conversion is also improved by decreasing the Reynolds number or increasing the S/C molar ratio. When the serpentine flow field of the channel is heated either through top plate ( Y = 1) or the bottom plate ( Y = 0), we observe a higher degree of methanol conversion for the case with top plate heating. This is due to the stronger chemical reaction for the case with top plate heating.
ISSN:0306-2619
1872-9118
DOI:10.1016/j.apenergy.2010.02.027