Investigation of Passive Direct Methanol Fuel Cell (DMFC) at the Open Circuit Condition

Xian Qi Cao; Ji Tian Han; Ze Ting Yu; Pei Pei Chen

doi:10.4028/www.scientific.net/AMR.457-458.156

Paper Titles

Optimal Design of Breakout Prediction System of Slab Continuous Casting
p.138

Technology Research and Application of Dynamic Secondary Cooling of Continuous Casting
p.142

SiC Particles Concentration Dependent the Properties of Electroless Ni-P-SiC Coatings
p.146

Modal Analysis of Mast Section of Hoist Based on the Vibration Theory
p.150

Investigation of Passive Direct Methanol Fuel Cell (DMFC) at the Open Circuit Condition
p.156

Implementation of Lance Control in Top-Blown Copper Smelting Process Based on DCS
p.161

Growth and Characterization of Radial pn Junction Gaas Nanowire by MOCVD
p.165

Analysis of Hydrogen Content in Hydride Film by Elastic Recoil Method
p.170

Effect of Electric Current Pulse on Carbide in Hypereutectic High Chromium Cast Iron
p.174

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 457-458Investigation of Passive Direct Methanol Fuel Cell...

Investigation of Passive Direct Methanol Fuel Cell (DMFC) at the Open Circuit Condition

Abstract:

In this work, a transparent passive DMFC was constructed to investigate the transients in open circuit voltage (OCV) and the cell temperature difference, which changed as a consequence of the methanol crossover phenomenon, including anode temperature difference (ATD), cathode temperature difference (CTD) and methanol solution temperature difference (MTD). Experiments were carried out in a passive DMFC with an active membrane area of 9 cm2, at ambient temperature and pressure. Results showed that the OCV of the passive DMFC became relatively stable as the cell temperature difference rose to a relatively stable value about 30 min later. At the middle and high current densities (>2.21 mA cm^-2), the performance increased continuously with increasing the waiting time, but became stable when the waiting time was longer than 30 min. The experimental results indicated that the performance of the passive DMFC could be more objectively characterized by collecting polarization data simultaneously when the cell temperature rises to a relatively stable value. Without the temperature measuring equipment, a waiting time about 30 min would be a good choice for collecting polarization data.

You might also be interested in these eBooks

Advanced Materials and Engineering Materials

View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 457-458)

Pages:

156-160

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.457-458.156

Citation:

Cite this paper

Online since:

January 2012

Authors:

Xian Qi Cao, Ji Tian Han, Ze Ting Yu, Pei Pei Chen

Keywords:

Open Voltage, Passive DMFC, Performance, Temperature Difference, Waiting Time

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] A. Kuver, and W. Vielstich: Journal of Power Sources. Vol. 74 (1998), p.211.

Google Scholar

[2] A.K. Shukla, C.L. Jackson, K. Scott and R.K. Raman: Electrochimica Acta. Vol. 47 (2002), p.3401.

Google Scholar

[3] G. Apanel and E. Johnson: Fuel Cells Bulletin (2004).

Google Scholar

[4] P. Zegers: Journal of Power Sources. Vol. 154 (2006), p.497.

Google Scholar

[5] T.S. Zhao, R. Chen, W.W. Yang and C. Xu: Journal of Power Sources. Vol. 191 (2009), p.185.

Google Scholar

[6] B. Bae, B.K. Kho, T. Lim, I. Oh, S. Hong and H.Y. Ha: Journal of Power Sources. Vol. 158 (2006), p.1256.

Google Scholar

[7] A. Faghri and Z. Guo: Applied Thermal Engineering. Vol. 28 (2008), p.1614.

Google Scholar

[8] R. Chen, T.S. Zhao and J.G. Liu: Journal of Power Sources. Vol. 157 (2009), p.351.

Google Scholar

[9] J.P. Esquivel, N. Sabaté, J. Santander, N. Torres-Herrero, I. Gràcia, P. Ivanov, L. Fonseca and C. Cané: Journal of Power Sources. Vol. 194 (2009), p.391.

DOI: 10.1016/j.jpowsour.2009.04.065

Google Scholar

[10] C.Y. Chen and P. Yang: Journal of Power Sources. Vol. 123 (2003), p.37.

Google Scholar

[11] J.G. Liu, T.S. Zhao, R. Chen and C.W. Wong: Electrochemistry Communications. Vol. 7 (2005), p.288.

Google Scholar

[12] J.J. Martin, W. Qian, H.J. Wang, V. Neburchilov, J.J. Zhang, D.P. Wilkinson and Z.R Chang: Journal of Power Sources. Vol. 164 (2004), p.287.

Google Scholar

[13] M.A. Abdelkareem and N. Nakagawa: Journal of Power Sources. Vol. 162 (2006), p.114.

Google Scholar

[14] H.K. Kim, J.M. Oh, J.H. Kim and H. Chang: Journal of Power Sources. Vol. 162 (2009), p.497.

Google Scholar

[15] B.K. Kho, I.H. Oh, S.A. Hong and H.Y. Ha: Fuel Cells Bulletin (2004).

Google Scholar

[16] Q. Ye and T.S. Zhao: Electrochemical and Solid-State Letters. Vol. 8 (2005), p.211.

Google Scholar