Three-dimensional multiphase flow computational fluid dynamics models for proton exchange membrane fuel cell: A theoretical development

被引：28

作者：

Kone J.-P. ^{[1
]}

Zhang X. ^{[2
]}

Yan Y. ^{[3
]}

Hu G. ^{[4
]}

Ahmadi G. ^{[5
]}

机构：

[1] International Doctoral Innovation Centre, The University of Nottingham Ningbo China, Ningbo

[2] Research Center of Fluids and Thermal Engineering, The University of Nottingham Ningbo China, Ningbo

[3] Fluids & Thermal Engineering Research Group, The University of Nottingham, Nottingham

[4] School of Mechanical and Automotive Engineering, Zhejiang University of Science and Technology, Hangzhou

[5] Department of Mechanical and Aeronautical Engineering, Clarkson University, Potsdam

来源：

Journal of Computational Multiphase Flows | 2017年 / 9卷 / 01期

关键词：

Computational fluid dynamics; Modelling; Multiphase flow; Numerical; Proton exchange membrane fuel cell; Review;

D O I：

10.1177/1757482X17692341

中图分类号：

学科分类号：

摘要：

A review of published three-dimensional, computational fluid dynamics models for proton exchange membrane fuel cells that accounts for multiphase flow is presented. The models can be categorized as models for transport phenomena, geometry or operating condition effects, and thermal effects. The influences of heat and water management on the fuel cell performance have been repeatedly addressed, and these still remain two central issues in proton exchange membrane fuel cell technology. The strengths and weaknesses of the models, the modelling assumptions, and the model validation are discussed. The salient numerical features of the models are examined, and an overview of the most commonly used computational fluid dynamic codes for the numerical modelling of proton exchange membrane fuel cells is given. Comprehensive three-dimensional multiphase flow computational fluid dynamic models accounting for the major transport phenomena inside a complete cell have been developed. However, it has been noted that more res arch is required to develop models that include among other things, the detailed composition and structure of the catalyst layers, the effects of water droplets movement in the gas flow channels, the consideration of phase change in both the anode and the cathode sides of the fuel cell, and dissolved water transport. © The Author(s) 2017.

引用

页码：3 / 25

页数：22

共 67 条

[11]

Berning T., Djilali N., A 3D, multiphase, multicomponent model of the cathode and anode of a PEM fuel cell, J Electrochem Soc, 150, pp. A1589-A1598, (2003)

[12]

Mazumder S., Cole J.V., Rigorous 3-dmathematicalmodeling of PEM fuel cells - II. Model predictions with liquid water transport, J Electrochem Soc, 150, pp. A1510-A1517, (2003)

[13]

Coppo M., Siegel N.P., Von Spakovsky M.R., On the influence of temperature on PEM fuel cell operation, J Power Sources, 159, pp. 560-569, (2006)

[14]

Matamoros L., Bruggemann D., Simulation of the water and heat management in proton exchange membrane fuel cells, J Power Sources, 161, pp. 203-213, (2006)

[15]

Al-Baghdadi M., Al-Janabi H., Modeling optimizes PEM fuel cell performance using three-dimensional multi-phase computational fluid dynamics model, Energy Convers Manage, 48, pp. 3102-3119, (2007)

[16]

Schwarz D.H., Djilali N., 3D modeling of catalyst layers in PEM fuel cells, J Electrochem Soc, 154, pp. B1167-B1178, (2007)

[17]

Shimpalee S., Spuckler D., Van Zee J.W., Prediction of transient response for a 25-cm(2) PEM fuel cell, J Power Sources, 167, pp. 130-138, (2007)

[18]

Jang J.H., Et al., Three-dimensional numerical study on cell performance and transport phenomena of PEM fuel cells with conventional flow fields, Int J Hydrogen Energy, 33, pp. 156-164, (2008)

[19]

Ren G.P., Et al., Transport mechanisms and performance simulation of a PEM fuel cell, Int J Energy Res, 32, pp. 514-530, (2008)

[20]

Wang Y., Modeling of two-phase transport in the diffusion media of polymer electrolyte fuel cells, J Power Sources, 185, pp. 261-271, (2008)

← 1 2 3 4 5 6 7 →