Effect of fiber curvature on gas diffusion layer two-phase dynamics of a proton exchange membrane fuel cell

The dynamics of two-phase flow within the cathode of a proton exchange membrane fuel cell, particularly in Gas Diffusion Layers (GDLs) with varying fiber curvatures, remain underexplored. Using a periodic surface model, we stochastically reconstruct three GDL types with different fiber curvatures, incorporating vital parameters derived from a physical GDL. Considering the randomness in reconstruction, the structure generation process is iterated four times for each GDL type, enabling an ensemble average analysis. Pore network models are adopted to reveal disparities in these GDL porous structures. The subsequent two-phase simulations are conducted to explore liquid transport through these GDLs and interfaces to assembled gas channels. Time-varying GDL total, local water saturation, and capillary pressure are investigated. Results show stochastic reconstructions exhibit similar frequency peak ranges in pore and throat diameters, and coordination numbers, but diverge from the physical GDL. Bigger fiber curvature tends to enhance pore network connectivity by increasing smaller pores, leading to heightened water saturation and capillary pressure. Straight-fiber GDLs, compared to curved-fiber GDLs, show greater potential proximity to the physical GDL in terms of overall water saturation and capillary pressure but are also accompanied by increased uncertainty. Despite similar layer porosity, water saturation in the same layer of all samples differs increasingly from the inlet to the outlet. Water breakthrough and detachment near the GDL can induce significant water saturation instability at the GDL and gas channel interface. Detached droplets in gas channels connected with straight-fiber GDLs exhibit larger sizes and slower movement than those in channels assembled with curved-fiber GDLs. These findings can be utilized in future GDL design and optimization.

[1]  M. Gorji-Bandpy,et al.  Numerical simulation of the motion and interaction of bubble pair rising in a quiescent liquid , 2023, Applied Ocean Research.

[2]  Jiqing Chen,et al.  Numerical effect of random poral microstructures in stacking gas diffusion layers on water transport capability , 2023, Journal of Power Sources.

[3]  A. Latz,et al.  Lattice Boltzmann simulation of liquid water transport in gas diffusion layers of proton exchange membrane fuel cells: Impact of gas diffusion layer and microporous layer degradation on effective transport properties , 2023, Journal of Power Sources.

[4]  A. Kannan,et al.  Gas diffusion layers for PEM fuel cells: Materials, properties and manufacturing – A review , 2022, International Journal of Hydrogen Energy.

[5]  K. Min,et al.  Effects of porosity gradient and average pore size in the in-plane direction and disposition of perforations in the gas diffusion layer on the performance of proton exchange membrane fuel cells , 2022, Journal of Power Sources.

[6]  R. An,et al.  Three-dimensional simulation of silted-up dam-break flow striking a rigid structure , 2022, Ocean Engineering.

[7]  Sheng Xu,et al.  Study on ice-melting performance of gradient gas diffusion layer in proton exchange membrane fuel cell , 2022, International Journal of Hydrogen Energy.

[8]  Zhiheng Huang,et al.  Proton exchange membranes for high temperature proton exchange membrane fuel cells: Challenges and perspectives , 2022, Journal of Power Sources.

[9]  K. Jiao,et al.  Investigations on heat and mass transfer in gas diffusion layers of PEMFC with a gas–liquid-solid coupled model , 2022, Applied Energy.

[10]  P. García-Salaberri,et al.  Modeling the interplay between water capillary transport and species diffusion in gas diffusion layers of proton exchange fuel cells using a hybrid computational fluid dynamics formulation , 2022, Journal of Power Sources.

[11]  Sichuan Xu,et al.  Lattice Boltzmann method modeling and experimental study on liquid water characteristics in the gas diffusion layer of proton exchange membrane fuel cells , 2022, International Journal of Hydrogen Energy.

[12]  P. Ming,et al.  Compressive stress and its impact on the gas diffusion layer: A review , 2022, International Journal of Hydrogen Energy.

[13]  Jiqing Chen,et al.  A review of proton exchange membrane fuel cell water management: Membrane electrode assembly , 2022, Journal of Power Sources.

[14]  K. Jiao,et al.  Transport properties of gas diffusion layer of proton exchange membrane fuel cells: Effects of compression , 2021 .

[15]  P. Sui,et al.  Microstructure reconstruction of the gas diffusion layer and analyses of the anisotropic transport properties , 2021 .

[16]  P. Sui,et al.  Pore-scale modeling of gas diffusion layers: Effects of compression on transport properties , 2021, Journal of Power Sources.

[17]  F. Marone,et al.  Temperature dependent water transport mechanism in gas diffusion layers revealed by subsecond operando X-ray tomographic microscopy , 2021, Journal of Power Sources.

[18]  D. Jacobson,et al.  The interactive effect of heat and mass transport on water condensation in the gas diffusion layer of a proton exchange membrane fuel cell , 2020 .

[19]  Johan Roenby,et al.  Validation of volume-of-fluid OpenFOAM® isoAdvector solvers using single bubble benchmarks , 2020 .

[20]  P. Okonkwo,et al.  A review of gas diffusion layer properties and water management in proton exchange membrane fuel cell system , 2020, International Journal of Energy Research.

[21]  M. Nikoo,et al.  Experimental study and numerical verification of silted-up dam break , 2020 .

[22]  K. Jiao,et al.  Vapor condensation in reconstructed gas diffusion layers of proton exchange membrane fuel cell , 2020, International Journal of Energy Research.

[23]  S. Holmes,et al.  Two-phase flow dynamics in a gas diffusion layer - gas channel - microporous layer system , 2020, Journal of Power Sources.

[24]  D. Brett,et al.  Pore Network Modelling of Capillary Transport and Relative Diffusivity in Gas Diffusion Layers with Patterned Wettability , 2020, Journal of The Electrochemical Society.

[25]  Zuo-yu Sun,et al.  Review on water management methods for proton exchange membrane fuel cells , 2020 .

[26]  M. Blunt,et al.  Droplet and Percolation Network Interactions in a Fuel Cell Gas Diffusion Layer , 2020, Journal of The Electrochemical Society.

[27]  Thomas M. M. Heenan,et al.  Mass transport in polymer electrolyte membrane water electrolyser liquid-gas diffusion layers: A combined neutron imaging and X-ray computed tomography study , 2020 .

[28]  K. Jiao,et al.  Water transport in the gas diffusion layer of proton exchange membrane fuel cell under vibration conditions , 2020, International Journal of Energy Research.

[29]  K. Jiao,et al.  Two-phase flow in compressed gas diffusion layer: Finite element and volume of fluid modeling , 2019, Journal of Power Sources.

[30]  Mehrez Agnaou,et al.  PoreSpy: A Python Toolkit for Quantitative Analysis of Porous Media Images , 2019, J. Open Source Softw..

[31]  N. Djilali,et al.  Woven gas diffusion layers for polymer electrolyte membrane fuel cells: Liquid water transport and conductivity trade-offs , 2018, Journal of Power Sources.

[32]  F. Büchi,et al.  Modeling and synchrotron imaging of droplet detachment in gas channels of polymer electrolyte fuel cells , 2018, Journal of Power Sources.

[33]  A. Bazylak,et al.  Liquid water saturation and oxygen transport resistance in polymer electrolyte membrane fuel cell gas diffusion layers , 2018, Electrochimica Acta.

[34]  Q. Cai,et al.  Three-dimensional lattice-Boltzmann model for liquid water transport and oxygen diffusion in cathode of polymer electrolyte membrane fuel cell with electrochemical reaction , 2018 .

[35]  Werner Lehnert,et al.  Interface Resolving Two-phase Flow Simulations in Gas Channels Relevant for Polymer Electrolyte Fuel Cells Using the Volume of Fluid Approach , 2018 .

[36]  Tequila A. L. Harris,et al.  Modeling of gas diffusion layers with curved fibers using a genetic algorithm , 2017 .

[37]  Satoshi Sakaida,et al.  Large scale simulation of liquid water transport in a gas diffusion layer of polymer electrolyte membrane fuel cells using the lattice Boltzmann method , 2017 .

[38]  Jeff T. Gostick,et al.  Versatile and efficient pore network extraction method using marker-based watershed segmentation. , 2017, Physical review. E.

[39]  A. Bazylak,et al.  Stochastic modeling of polymer electrolyte membrane fuel cell gas diffusion layers – Part 1: Physical characterization , 2017 .

[40]  A. Bazylak,et al.  Investigating the effects of gas diffusion layer substrate thickness on polymer electrolyte membrane fuel cell performance via synchrotron X-ray radiography , 2017 .

[41]  J. Pauchet,et al.  Pore network modelling of condensation in gas diffusion layers of proton exchange membrane fuel cells , 2016 .

[42]  Liam G. Connolly,et al.  Gas-diffusion-layer structural properties under compression via X-ray tomography , 2016 .

[43]  V. Joekar‐Niasar,et al.  Effects of intermediate wettability on entry capillary pressure in angular pores. , 2016, Journal of colloid and interface science.

[44]  Alan Burns,et al.  OpenPNM: A Pore Network Modeling Package , 2016, Computing in Science & Engineering.

[45]  D. Jeon,et al.  Effect of compression on water transport in gas diffusion layer of polymer electrolyte membrane fuel cell using lattice Boltzmann method , 2015 .

[46]  E. Roohi,et al.  Investigation of Different Droplet Formation Regimes in a T-junction Microchannel Using the VOF Technique in OpenFOAM , 2015 .

[47]  Yan Wang,et al.  Generalized periodic surface model and its application in designing fibrous porous media , 2015 .

[48]  Volker Schmidt,et al.  Three-dimensional study of compressed gas diffusion layers using synchrotron X-ray imaging , 2014 .

[49]  M. Mench,et al.  Oxygen transport resistance correlated to liquid water saturation in the gas diffusion layer of PEM fuel cells , 2014 .

[50]  I. Manke,et al.  Stochastic 3D modeling of non-woven materials with wet-proofing agent , 2013 .

[51]  Z. Fishman,et al.  Heterogeneous Through-Plane Porosity Distributions for Treated PEMFC GDLs I. PTFE Effect , 2011 .

[52]  Marco Stampanoni,et al.  Investigation of liquid water in gas diffusion layers of polymer electrolyte fuel cells using X-ray tomographic microscopy , 2011 .

[53]  Michael M. Daino,et al.  Water management studies in PEM fuel cells, part III: Dynamic breakthrough and intermittent drainage characteristics from GDLs with and without MPLs , 2010 .

[54]  David A. Harrington,et al.  Characterisation of proton exchange membrane fuel cell (PEMFC) failures via electrochemical impedance spectroscopy , 2006 .

[55]  P. Sui,et al.  Solid Mechanics Simulation of Reconstructed Gas Diffusion Layers for PEMFCs , 2019, Journal of The Electrochemical Society.

[56]  S. Litster,et al.  Micro-Scale Analysis of Liquid Water Breakthrough inside Gas Diffusion Layer for PEMFC Using X-ray Computed Tomography and Lattice Boltzmann Method , 2017 .

[57]  Stefan Turek,et al.  Proposal for quantitative benchmark computations of bubble dynamics , 2007 .

[58]  C. W. Hirt,et al.  Volume of fluid (VOF) method for the dynamics of free boundaries , 1981 .