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2. Thermal Stress in Full-Size Solid Oxide Fuel Cell Stacks by Multi-Physics Modeling

Author

Xueping Zhang, Mingtao Wu, Liusheng Xiao, Hao Wang, Yingqi Liu, Dingrong Ou, and Jinliang Yuan

Subjects
SOFC stacks, thermal stress, computational fluid dynamics, multi-physics coupling modeling, failure probability analysis method, Technology
Abstract

Mechanical failures in the operating stacks of solid oxide fuel cells (SOFCs) are frequently related to thermal stresses generated by a temperature gradient and its variation. In this study, a computational fluid dynamics (CFD) model is developed and further applied in full-size SOFC stacks, which are fully coupled and implemented for analysis of heat flow electrochemical phenomena, aiming to predict thermal stress distribution. The primary object of the present investigation is to explore features and characteristics of the thermal stress influenced by electrochemical reactions and various transport processes within the stacks. It is revealed that the volume ratio of the higher thermal stress region differs nearly 30% for different stack flow configurations; the highest probability of potential failure appears in the cell cathodes; the more cells applied in the stack, the greater the difference in the predicted temperature/thermal stress between the cells; the counter-flow stack performs the best in terms of output power, but the predicted thermal stress is also higher; the cross-flow stack exhibits the lowest thermal stress and a lower output power; and although the temperature and thermal stress distributions are similar, the differences between the unit cells are bigger in the longer stacks than those predicted for shorter stacks. The findings from this study may provide a useful guide for assessing the thermal behavior and impact on SOFC performance.

Published
2024
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3. Numerical Study of H2 Production and Thermal Stress for Solid Oxide Electrolysis Cells with Various Ribs/Channels

Author

Yingqi Liu, Liusheng Xiao, Hao Wang, Dingrong Ou, and Jinliang Yuan

Subjects
solid oxide electrolysis cell, inter-connector rib/channel width ratio, gradient channels, electro-thermo-mechanical coupled model, thermal stress, computational fluid dynamics (CFD), Technology
Abstract

A fully coupled electro-thermo-mechanical CFD model is developed and applied to illuminate the crucial factors influencing the overall performance of a solid oxide electrolysis cell (SOEC), particularly the configuration and geometry parameters of its inter-connector (IC), comprising ribs and channels. Expanding on a selected width ratio of 4:3, the gradient ribs/channels are further investigated to assess electrochemical and thermo-mechanical performance. It is elucidated that, while maintaining constant maximum temperature and thermal stress levels, employing a non-regular geometry IC with gradient channels may yield a 30% enhancement in hydrogen production. These nuanced explorations illuminate the complex interplay between IC configuration, thermal stresses, and electrolysis efficiency within SOECs.

Published
2024
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4. Performance and Thermal Stress Evaluation of Full-Scale SOEC Stack Using Multi-Physics Modeling Method

Author

Hao Wang, Liusheng Xiao, Yingqi Liu, Xueping Zhang, Ruidong Zhou, Fangzheng Liu, and Jinliang Yuan

Subjects
full-scale solid oxide electrolysis cell (SOEC) stack, thermal stress, multi-physics coupling modeling method, failure probability, computational fluid dynamics (CFD) model, Technology
Abstract

A three-dimensional computational fluid dynamics (CFD) method coupled with multi-physics phenomena is developed and applied for a 10-cell full-scale SOEC stack in this study. Effects of gas flow patterns, operating temperature, and manifold configurations are simulated and analyzed for stack performance and thermal stress. It is demonstrated the hydrogen production and thermal stress obtained in cross-flow mode stack are about 8% and 36 MPa higher compared to that in other flow cases. Furthermore, it is found the temperature gradient is the predominant factor affecting the thermal stress distribution and failure probability. Lastly, a stack arrangement with 2-inlet and 1-outlet is proposed and analyzed to enhance gas distribution uniformity within the cell channels. The findings of this study hold significance as a reference for investigating the impact on the SOEC stack performance and thermal stress distribution.

Published
2023
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5. Numerical Analysis of Thermal Stress for a Stack of Planar Solid Oxide Fuel Cells

Author

Jianmin Zheng, Liusheng Xiao, Mingtao Wu, Shaocheng Lang, Zhonggang Zhang, Ming Chen, and Jinliang Yuan

Subjects
thermal stress, SOFC stack, flow arrangement, CFD, modeling, Technology
Abstract

In this work, a 3D multi-physics coupled model was developed to analyze the temperature and thermal stress distribution in a planar solid oxide fuel cell (SOFC) stack, and then the effects of different flow channels (co-flow, counter-flow and cross-flow) and electrolyte thickness were investigated. The simulation results indicate that the generated power is higher while the thermal stress is lower in the co-flow mode than those in the cross-flow mode. In the cross-flow mode, a gas inlet and outlet arrangement is proposed to increase current density by about 10%. The generated power of the stack increases with a thin electrolyte layer, but the temperature and its gradient of the stack also increase with increase of heat generation. The thermal stress for two typical sealing materials is also studied. The predicted results can be used for design and optimization of the stack structure to achieve lower stress and longer life.

Published
2022
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12. Simulation and Analysis of Thermal Stress and Sintering Warpage of Planar Solid Oxide Fuel Cells

Author

Xin Zhao, Zaihong Sun, Liusheng Xiao, Mingtao Wu, Minfang Han, Jianmin Zheng, Jinliang Yuan, Jihao Zhang, and Shaocheng Lang

Subjects
chemistry.chemical_compound, Planar, Materials science, chemistry, Oxide, Sintering, Fuel cells, Composite material
Abstract

Solid oxide fuel cell (SOFC) is one of the new energy conversion technologies producing electricity and heat from fuel and oxidant through an electrochemical reaction. The high operating temperature has many advantages including high efficiency, flexible fuel adaptability and low emissions. However, it has also some drawbacks, e.g., thermal expansion mismatches among the involved materials, particularly when the temperature reaches around 1400 oC during the sintering process, which may cause non-uniform distribution of thermal stress and even further deformation and warpage observed in the cell manufacturing steps. A three-dimensional CFD (computational fluid dynamics) simulation model is developed to study the thermal stress distributed in the sintered function layers of the anode-supported planar SOFC unit cells (10×10 cm2) using a finite element method. Five layers are included, i.e., cathode and its separation layer (GDC/LSCF, 70 µm), anode support and active layers (Ni/YSZ, 550µm), and electrolyte layer (YSZ, 30 µm) between them. In terms of the thermal stress and deformation, the predicted results are presented and discussed for the sintered unit cells with different angels located around the four cornels. It is found that the maximum thermal stress occurs at the interface between the electrode and electrolyte; the magnitude and distribution of thermal stress at the interfaces are closely related to the material thermal properties; the maximum deformation about 13 mm in the thickness direction is predicted for the 90-angel shaped cornels at the sintering temperature 1400 oC, which is bigger than that for the case with the circular shaped cornels; the deformation magnitude depends not only on the maximum thermal stress, but also the difference between the maximum and minimum thermal stress. The findings and predicted results may be applied for optimization of design and sintering conditions for SOFC unit cells. Acknowledgements This work is supported by the National Key Research and Development Project of China (2018YFB1502204, 2018YFB1502203, 2018YFB1502205), the Ningbo major special projects of the Plan “Science and Technology Innovation 2025” (2018B10048). Figure 1

Published
2021
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15. Synchrotron X‐ray Radiography and Tomography of Vanadium Redox Flow Batteries—Cell Design, Electrolyte Flow Geometry, and Gas Bubble Formation

Author

Liusheng Xiao, Kieran F. Fahy, László Eifert, Kangjun Duan, Aimy Bazylak, Nico Bevilacqua, Kerstin Köble, Roswitha Zeis, Pang-Chieh Sui, and Min Li

Subjects
Technology, DDC 540 / Chemistry & allied sciences, Materials science, Hydrogen, General Chemical Engineering, Vanadium, chemistry.chemical_element, 02 engineering and technology, Electrolyte, 010402 general chemistry, Röntgenbild, 01 natural sciences, law.invention, carbon electrodes, law, Electrodes, Carbon, flow geometries, R��ntgenbild, Environmental Chemistry, ddc:530, General Materials Science, synchrotron X-ray imaging, Full Paper, DDC 530 / Physics, Full Papers, 021001 nanoscience & nanotechnology, Synchrotron, 0104 chemical sciences, Flowgraphs, General Energy, chemistry, Chemical engineering, ddc:540, Electrode, Wetting, Cyclic voltammetry, 0210 nano-technology, Saturation (chemistry), ddc:600, electrolyte distribution, vanadium redox flow cell
Abstract

Now you see (through) me: A modular vanadium redox flow cell is used to examine electrolyte distributions in carbon electrodes by synchrotron X���ray imaging. The impact of three different flow geometries on the flow dynamics is studied, and electrochemical characterizations are concurrently performed with X���ray imaging to visualize the hydrogen evolution. The unique capabilities of this cell design and experiments are outlined. The wetting behavior and affinity to side reactions of carbon���based electrodes in vanadium redox flow batteries (VRFBs) are highly dependent on the physical and chemical surface structures of the material, as well as on the cell design itself. To investigate these properties, a new cell design was proposed to facilitate synchrotron X���ray imaging. Three different flow geometries were studied to understand the impact on the flow dynamics, and the formation of hydrogen bubbles. By electrolyte injection experiments, it was shown that the maximum saturation of carbon felt was achieved by a flat flow field after the first injection and by a serpentine flow field after continuous flow. Furthermore, the average saturation of the carbon felt was correlated to the cyclic voltammetry current response, and the hydrogen gas evolution was visualized in 3D by X���ray tomography. The capabilities of this cell design and experiments were outlined, which are essential for the evaluation and optimization of cell components of VRFBs., publishedVersion

Published
2020
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18. Solid Mechanics Simulation of Reconstructed Gas Diffusion Layers for PEMFCs

Author

Heng Zhang, Pang-Chieh Sui, Roswitha Zeis, Liusheng Xiao, and Maji Luo

Subjects
Materials science, Renewable Energy, Sustainability and the Environment, Solid mechanics, Materials Chemistry, Electrochemistry, Gaseous diffusion, Mechanics, Condensed Matter Physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials
Published
2019
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20. Experimental validation of pore-scale models for gas diffusion layers

Author

Liusheng Xiao, Lijun Zhu, Christian Clökler, Alex Grünzweig, Florian Wilhelm, Joachim Scholta, Roswitha Zeis, Zu-Guo Shen, Maji Luo, and Pang-Chieh Sui

Subjects
Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, Electrical and Electronic Engineering, Physical and Theoretical Chemistry
Published
2022
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21. Effects of Flow Channel Arrangement and Electrolyte Thickness on Thermal Stress for Planar Solid Oxide Fuel Cell Stacks

Author

Jinliang Yuan, Liusheng Xiao, Ming Chen, and Jianmin Zheng

Subjects
Temperature gradient, Materials science, Stack (abstract data type), Operating temperature, law, Solid oxide fuel cell, Electrolyte, Composite material, Layer (electronics), Cathode, Anode, law.invention
Abstract

Typical operating temperature for solid oxide fuel cells (SOFC) is between 700~800°C. A large temperature gradient and thermal stress caused by internal losses and electrochemical reactions may cause SOFC stack performance degradation and even structural damage, which has become a hindrance to its applications. In this study, a three-dimensional multiphysics CFD (computational fluid dynamics) model is developed and applied for a planar SOFC stack to study the temperature and thermal stress distribution, as well as effects of structure and design parameters, including the flow channel arrangement (e.g., co- and count-flow) and thickness of the electrolyte layer. The stack is composed of three-unit cells, metallic interconnect layers, sealing and anode/cathode current collectors. The simulation results reveal that the temperature difference in the counter-flow mode is smaller and the thermal stress is lower than those in the co-flow mode. The overall performance of the stack is better when the electrolyte layer thickness becomes smaller, but the stack temperature and the temperature gradient become higher. In addition, a large temperature gradient due to the thin electrolyte layer leads to a significant increase of the thermal stress in the electrolyte. The findings and research method from this study can be applied to optimize the design of the stack structures, by consideration of the maximum thermal stress and its distribution. Acknowledgements This work is supported by the National Key Research and Development Project of China (2018YFB1502204), the Ningbo major special projects of the Plan “Science and Technology Innovation 2025” (2018B10048). References 1. M. Peksen, Progress in Energy and Combustion Science, 2015; 48: 1-20. 2. K. Eichhorn Colombo, V. Kharton, F. Berto, et al., Computers and Chemical Engineering,2020; 140: 106972. 3. P. Pianko-Oprych, T. Zinko, et al., Journal of Power Sources, 2015; 300: 10-23. 4. J. Robinson, L. Brown, R. Jervis, et al., Journal of Power Sources, 2015; 288: 473-481. 5. L. Chang, H. Liu, Y. Shiu, et. al., Journal of Power Sources, 2010; 195: 1895-1904. 6. A. Selimovic, M. Kemm, T. Torison, et. al., Journal of Power Sources, 2005; 145: 463-469. 7. M. Xu, T. Li, M. Yang, et. al., Science Bulletin, 2016; 61: 1333-1336. 8. C. Lin, L. Huang, L. Chiang, Y. Chyou, Journal of Power Sources, 2009; 192: 515-524. 9. M. Peksen, International Journal of Hydrogen Energy, 2013; 38: 553-561. 10. X. Fang, Z. Lin, Applied Energy, 2018; 229: 63-68. 11. D. Cui, M. Cheng, Journal of Power Sources, 2009; 192: 400-407. 12. Q. Li, Z. Xu, M. Cheng, et al., Modern Physics Letters B, 2020; 34(15): 23. 13. W. Zhang, D. Yan, J. Duan, et al. International Journal of Hydrogen Energy, 2013, 38(35): 15371-15378. 14. Y. Zhang, W. Jiang, S. Tu, et al., International Journal of Hydrogen Energy, 2018, 43(9): 4492-4504. Figure 1

Published
2021
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22. Pore-scale modeling of gas diffusion layers: Effects of compression on transport properties

Author

Aimy Bazylak, Lijun Zhu, Heng Zhang, Xin Gao, Liusheng Xiao, and Pang-Chieh Sui

Subjects
Materials science, Renewable Energy, Sustainability and the Environment, Lattice Boltzmann methods, Energy Engineering and Power Technology, Proton exchange membrane fuel cell, 02 engineering and technology, Mechanics, 010402 general chemistry, 021001 nanoscience & nanotechnology, Compression (physics), Thermal diffusivity, 01 natural sciences, 0104 chemical sciences, Compression ratio, Solid mechanics, Gaseous diffusion, Electrical and Electronic Engineering, Physical and Theoretical Chemistry, 0210 nano-technology, Anisotropy
Abstract

A pore-scale simulation approach combining the pore-scale model (PSM) and lattice Boltzmann method (LBM) is developed for a gas diffusion layer (GDL) of a proton exchange membrane fuel cell. The effects of mechanical compression on the transport process of gas species, electric current, heat, and liquid water are studied. A solid mechanics model of the GDL is first numerically reconstructed using a stochastic algorithm. The reconstructed model is then compressed using the explicit dynamics method to generate deformed structures at various compression ratios. PSM simulations are subsequently employed to evaluate the transport properties, and LBM is used to simulate the intrusion process of liquid water and compute the permeability. Simulation results show that electric and thermal conductivities increase with compression ratio, whereas gas diffusivity and water permeability decrease with compression ratio. The in-plane transport properties are found to be greater than the through-plane properties. The anisotropy is evident for electric and thermal conductivities and decreases with increasing compression ratio. The PSM results are substituted into a macroscopic fuel cell model to examine the impact of compression on cell performance. It is found that the local current density becomes more diffusion-limited when the compression ratio is increased.

Published
2021
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23. Multiphase and Pore Scale Modeling on Catalyst Layer of High-Temperature Polymer Electrolyte Membrane Fuel Cell

Author

Henning Markötter, Liusheng Xiao, Lijun Zhu, Min Li, Kangjun Duan, László Eifert, Ruiming Zhang, Pang-Chieh Sui, Roswitha Zeis, Nico Bevilacqua, and Ingo Manke

Subjects
chemistry.chemical_classification, Materials science, Renewable Energy, Sustainability and the Environment, Pore scale, Electrolyte, Polymer, Condensed Matter Physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Catalysis, Membrane, Chemical engineering, chemistry, Materials Chemistry, Electrochemistry, Fuel cells, Layer (electronics)
Abstract

Phosphoric acid as the electrolyte in high-temperature polymer electrolyte membrane fuel cell plays an essential role in its performance and lifetime. Maldistribution of phosphoric acid in the catalyst layer (CL) may result in performance degradation. In the present study, pore-scale simulations were carried out to investigate phosphoric acid’s multiphase flow in a cathode CL. A reconstructed CL model was built using focused ion beam-SEM images, where distributions of pore, carbon support, binder, and catalyst particles can be identified. The multi-relaxation time lattice Boltzmann method was employed to simulate phosphoric acid invading and leaching from the membrane into the CL during the membrane electrode assembly fabrication process. The predicted redistribution of phosphoric acid indicates that phosphoric acid of low viscosity or low wettability is prone to leaching into the CL. The effective transport properties and the active electrochemical active surface area (ECSA) were computed using a pore-scale model. They were subsequently used in a macroscopic model to evaluate the cell performance. A parametric study shows that cell performance first increases with increasing phosphoric acid content due to the increase of ECSA. However, further increasing phosphoric acid content results in performance degradation due to mass transfer limitation caused by acid flooding.

Published
2021
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24. Mesoscopic modeling and characterization of the porous electrodes for vanadium redox flow batteries

Author

Min Li, Wengliang Leng, Kangjun Duan, Pang-Chieh Sui, Nico Bevilacqua, Lijun Zhu, Liusheng Xiao, and Roswitha Zeis

Subjects
Materials science, Renewable Energy, Sustainability and the Environment, 020209 energy, Energy Engineering and Power Technology, Vanadium, chemistry.chemical_element, 02 engineering and technology, Electrolyte, 021001 nanoscience & nanotechnology, Microstructure, Thermal diffusivity, chemistry, Electrode, 0202 electrical engineering, electronic engineering, information engineering, Gaseous diffusion, Electrical and Electronic Engineering, Composite material, 0210 nano-technology, Porosity, Porous medium
Abstract

Porous electrodes are commonly used in electrochemical devices such as fuel cells and vanadium redox flow batteries (VRFBs). The performance of these electrodes depends on their transport properties including diffusivity, permeability and electric/thermal conductivities, and further on their surface properties if two-phase flow occurs at high current conditions. This paper reports a pore-scale investigation on the transport processes involved in a carbon felt for VRFB applications. The microstructure of a carbon felt over a range of compression ratios is first reconstructed from micro-computed tomography. Pore-scale model simulation, which solves the coupled transport of electrolyte in porous materials, is employed to compute the effective transport properties of the reconstructed model. The permeability and diffusivity of the carbon felt are found to decrease with increasing compression ratio. Transport of liquid water within the reconstructed carbon felt is studied based on the multiple-relaxation-time lattice Boltzmann method and the simulation result indicates that compression on the electrode causes a large drop in porosity and flow resistance increases accordingly. Furthermore, the reconstructed model is converted to a finite-element model and then solid mechanics simulations are performed to gain insight to the stress distribution of the microstructure under compression. These effective transport properties are used in a two-dimensional macroscopic model to demonstrate the mesoscopic-macroscopic approach. Compression on a porous electrode is found to contribute notably on the increase of vanadium concentrations and pressure drops, which can be beneficial to the performance of VRFB. The methodology developed from this research is readily applicable to other porous electrodes such as the gas diffusion layers for fuel cells.

Published
2020
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25. Flow Geometry of the Electrolyte and Gas Bubble Formation in Redox Flow Batteries - a Synchrotron Imaging Study

Author

Liusheng Xiao, Kieran F. Fahy, Nico Bevilacqua, Min Li, Aimy Bazylak, Kangjun Duan, Kerstin Köble, László Eifert, Pang-Chieh Sui, and Roswitha Zeis

Subjects
Gas bubble, Materials science, Flow (mathematics), Chemical physics, law, Imaging study, Electrolyte, Redox, Synchrotron, law.invention
Abstract

Two major limitations of Vanadium Redox Flow Batteries (VRFBs) are (1) The transport losses of getting the electrolyte into the electrode and to the reaction sites with minimum resistance and (2) Lack of access to all reaction sites due to relatively low saturation levels of the electrolyte.1,2 Although the porous carbon electrodes have high porosity, a large pressure may be required to pump the electrolyte through the electrode during operation. A key factor that influences the saturation and pumping pressure is the design of flow fields.3 Also, the presence of hydrogen bubbles can affect the saturation of the carbon electrode, which is formed as a parasitic side product of the V3+ reduction reaction at the anode in VRFBs.4 This affects the efficiency and stability of the VRFB cells. Besides mixed potentials, the Hydrogen bubbles could also damage the pore structure of the electrode and create an inaccessible surface area where otherwise the reaction would occur. To investigate the formation of gas bubbles inside the small pores of the carbon electrode, as well as the influence of flow geometry, we present a novel vanadium redox flow full-cell (Fig. 1(a)) that facilitates synchrotron X-ray imaging. 5 Three different flow geometries, i.e., serpentine, interdigitated, and flow-through, were tested as shown in Fig. 1(b). During the experiment, the electrolyte was injected into the cell using a peristaltic pump. Radiography was conducted during the injection process to track the flow of the electrolyte through the electrode and to calculate the average saturation for each flow geometry. Further experiments include the potential-dependent changes of the saturation and the 3D-visualization of the hydrogen bubble formation during constant potential measurements via tomography (Fig. 1(c)). This setup offers great flexibility in designing experiments for redox flow batteries, allowing the investigation of various electrode materials with different compression ratios and flow geometries under potential control. In the future, the measurements will help us develop theoretical models for a better understanding of the multiphase and interfacial flow phenomena within the porous electrode. These experiments are essential for the evaluation and optimization of electrode materials and manifolds currently being used in VRFBs. References N. Bevilacqua et al., J. Power Sources, 439, 227071 (2019) https://www.sciencedirect.com/science/article/pii/S037877531931064X. R. Banerjee, N. Bevilacqua, L. Eifert, and R. Zeis, J. Energy Storage, 21, 163–171 (2019) https://www.sciencedirect.com/science/article/pii/S2352152X18305851. R. M. Darling and M. L. Perry, J. Electrochem. Soc., 161, A1381–A1387 (2014) http://jes.ecsdl.org/lookup/doi/10.1149/2.0941409jes. L. Eifert, Z. Jusys, R. J. Behm, and R. Zeis, Carbon N. Y., 158, 580–587 (2020) https://www.sciencedirect.com/science/article/abs/pii/S0008622319311546. L. Eifert et al., ChemSusChem, cssc.202000541 (2020) https://onlinelibrary.wiley.com/doi/abs/10.1002/cssc.202000541. Figure 1

Published
2020
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26. Pore-Scale Characterization and Simulation of Porous Electrode Material for Vanadium Redox Flow Battery: Effects of Compression on Transport Properties

Author

Maji Luo, Liusheng Xiao, Kangjun Duan, Pang-Chieh Sui, Lijun Zhu, Nico Bevilacqua, Roswitha Zeis, and László Eifert

Subjects
Materials science, Renewable Energy, Sustainability and the Environment, Pore scale, Vanadium, chemistry.chemical_element, Condensed Matter Physics, Compression (physics), Flow battery, Redox, Finite element method, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Characterization (materials science), Porous electrode, chemistry, Materials Chemistry, Electrochemistry, Composite material
Published
2020
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27. Cover Feature: Synchrotron X‐ray Radiography and Tomography of Vanadium Redox Flow Batteries—Cell Design, Electrolyte Flow Geometry, and Gas Bubble Formation (ChemSusChem 12/2020)

Author

Min Li, Kerstin Köble, Pang-Chieh Sui, Kieran F. Fahy, László Eifert, Aimy Bazylak, Nico Bevilacqua, Kangjun Duan, Roswitha Zeis, and Liusheng Xiao

Subjects
Gas bubble, X ray radiography, Materials science, General Chemical Engineering, Vanadium, chemistry.chemical_element, Electrolyte, Redox, Synchrotron, law.invention, General Energy, chemistry, Flow (mathematics), Chemical engineering, law, Environmental Chemistry, General Materials Science, Tomography
Published
2020
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29. Stochastically Modeled Gas Diffusion Layers: Effects of Binder and Polytetrafluoroethylene on Effective Gas Diffusivity.

Author

Lijun Zhu, Wangfan Yang, Liusheng Xiao, Heng Zhang, Xin Gao, and Pang-Chieh Sui

Subjects
THERMAL diffusivity, DIFFUSION, PROTON exchange membrane fuel cells, POLYTEF
Abstract

An improved stochastic reconstruction method for a gas diffusion layer (GDL) of proton exchange membrane fuel cell is developed to promote the accuracy in evaluating effective gas diffusivity. Carbon fibers are generated using stochastic algorithm within a representative element volume. Structural characteristics, porosity distribution and fiber orientation distribution are set as constraints in reconstructing the microstructure. Morphological opening of image processing with structuring element is employed to add binder and polytetrafluoroethylene (PTFE), with disk and sphere binder configurations. Pore-scale simulations are subsequently carried out to compute the anisotropic, effective gas diffusivities of these reconstructed GDLs. Simulation results show that the reconstructed GDL with binder and PTFE produces significant decrease of the effective gas diffusivity. The diskshape binder appears to match the real GDL geometry visually, and the predicted effective gas diffusivity is also in good agreement with the reported experimental data in the literature. This demonstrates the importance of binder and PTFE in GDL reconstruction. Moreover, the correlations of the effective diffusivities in the through-plane and in-plane directions as functions of porosity and volume fraction of binder and PTFE are determined for the reconstructed GDLs. [ABSTRACT FROM AUTHOR]

Published
2021
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30. Coupled stress–strain and transport in proton exchange membrane fuel cell with metallic bipolar plates

Author

Po-Ya Abel Chuang, Liusheng Xiao, Ned Djilali, Heng Zhang, and Pang-Chieh Sui

Subjects
Materials science, 020209 energy, Mechanical Engineering, Contact resistance, Stress–strain curve, Proton exchange membrane fuel cell, 02 engineering and technology, Building and Construction, Management, Monitoring, Policy and Law, Compression (physics), Coolant, General Energy, 020401 chemical engineering, Stack (abstract data type), Mass transfer, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, 0204 chemical engineering, Composite material
Abstract

Metallic bipolar plates (BPPs) for proton-exchange membrane fuel cells (PEMFCs) are desirable in automotive applications because they (i) offer good mechanical properties and manufacturability, (ii) reduce costs compared with graphite-based BPPs, and (iii) allow flexible flow-channel designs that increase power density. In this study, the relatively unexplored couplings between the mechanical and electrochemical effects due to stack compression were analyzed using a model that accounts for the transport, electrochemical reaction, heat transfer, and stress mechanics. The present model is aimed to be employed into simulation tools for PEMFC design and application. Both the tilt angle and flow-channel width of the BPPs were found to affect the stress distribution in the gas-diffusion layer (GDL) and BPP, as well as the contact resistance. The coolant pressure affected the stress distribution in the BPP, particularly at the welded joint between two adjacent plates. Stack compression not only increased the mass-transfer resistance of the GDL, particularly under the rib region, but also resulted in improved heat transfer, which reduced the PEMFC temperature and improved the uniform temperature distribution. Although the impacts of compression on the heat and mass transfer became more pronounced at higher current densities, the combined effect with the reduced membrane temperature and contact resistance between the GDL and BPP resulted in improved PEMFC performance. Applying the model to investigate a range of mechano-electrochemical conditions revealed that higher stress–strain concentrations resulted in a more nonuniform current–density distribution at the interface between the microporous layer and catalyst layer.

Published
2019
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31. Pore-Scale Characterization and Simulation of Porous Electrode Material for Vanadium Redox Flow Battery: Effects of Compression on Transport Properties.

Author

Liusheng Xiao, Maji Luo, Lijun Zhu, Duan, Kangjun, Bevilacqua, Nico, Eifert, László, Zeis, Roswitha, and Pang-Chieh Sui

Subjects
POROUS materials, POROUS electrodes, VANADIUM redox battery, SOLID mechanics, COMPUTED tomography, THERMAL diffusivity
Abstract

In this study, X-ray computed tomography (XCT) and pore-scale simulation were employed to investigate the mechanical deformation of a porous electrode material for a vanadium redox flow battery during compression and to quantify its impact on the effective transport properties of the electrode. Pore-scale simulations using the finite element method (FEM), pore-scale modeling (PSM), and lattice Boltzmann method (LBM) were adopted to obtain the deformed geometry and to compute the effective diffusivity, conductivity, and permeability. The structure of a carbon felt was first scanned and reconstructed by XCT; using the results, a 3D model was generated and meshed for solid mechanics simulations. In the FEM simulation, the displacement of the microstructure at different compression ratios (CRs) was investigated considering the contact, friction, extrusion, and bending interactions between the carbon fibers. The relationship between the CR and transport properties was quantified using in-house PSM and LBM codes. The results reveal that the carbon felt is highly anisotropic. When compressed, the displacement of the carbon fibers changes significantly in the through-plane and in-plane directions. The effective diffusivities and permeability of the felt decrease with increasing CR, and its electrical conductivity increases with increasing CR. The present study demonstrates a workflow that combines experimental characterization and solid mechanics simulation to produce deformed solid mechanics models, which can be subsequently employed for mesoscopic simulations in order to obtain effective transport properties. This approach will enable computational investigations into general porous electrode materials, and more importantly, it can be employed to design new materials that can be engineered for optimal performance. [ABSTRACT FROM AUTHOR]

Published
2020
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32. Modeling the Mechano-Chemical Coupling in a Compressed PEMFC MEA with Metallic Bipolar Plates

Author

Heng Zhang, Liusheng Xiao, Pang-Chieh Sui, and Ned Djilali

Abstract

Metallic bipolar plates are desirable for the automotive applications of PEMFCs because they offer excellent mechanical properties over the graphite-based bipolar plates. The flow channel configuration using metallic bipolar plates also enhances a stack’s power density. Modeling and simulation of the mechanical behavior of metallic bipolar plates under compression and the impact of mechanical stress-strain on the transport/electrochemical reactions in the membrane electrode assembly (MEA) are reported in this paper. A two-dimensional MEA model with metallic bipolar plates is developed. A two-stage approach with one-way coupling is employed to study the effects of mechanical stress-strain on transport/electrochemistry, namely, solid mechanics of the model is first solved, followed by the solution of coupled heat and mass transport over the deformed geometry obtained from the solid mechanics solution. The transport equations solved include the conservation of mass, species/charged species, and energy. Transport properties such as the porosity, permeability and contact resistance of the MEA components are either obtained from published works or expressed as functions of strain in the model, which are derived from numerical reconstruction of the materials. Furthermore, membrane degradation reactions are modeled as a function of stress to gain insight to the mechano-chemical coupling in the MEA. The comprehensive model was solved using Multiphysics COMSOL software v.5.3. Figure 1 shows the model with typical distributions of von Mises stress over the computational domain (note different scales of stress in the bipolar plates and the MEA), which are obtained by solving solid mechanics of the model. The stress and strain information of the solid mechanics solution as well as the deformed geometry are subsequently passed to the coupled heat and mass transport solution procedure to compute the distributions of species, potentials, and temperature. The present model establishes a platform to numerically investigate the interplay between mechanical responses and transport/electrochemistry in the MEA. Figure 1

Published
2018
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33. Solid Mechanics Simulation of Reconstructed Gas Diffusion Layers for PEMFCs.

Author

Liusheng Xiao, Maji Luo, Heng Zhang, Zeis, Roswitha, and Pang-Chieh Sui

Subjects
PROTON exchange membrane fuel cells, SOLID mechanics, MICROSTRUCTURE
Abstract

This paper reports on the development of a novel approach to investigate the stress and strain distributions at the fiber's scale of PEMFC gas diffusion layers (GDLs). The present method includes stochastic reconstruction and finite element solution procedure. The microstructure of a GDL was randomly generated and meshed, upon which solid mechanics simulations were performed. Stress and strain distributions in three dimensions were obtained by considering dynamic contact, frictional motion and extruding deformation of the fibers. A sensitivity analysis on the present model showed that frictional coefficient between fibers has more influence on the model results than the mechanical properties of the fiber. Our simulation results show that under compression, the fiber's displacement in the through-plane direction is significantly more than the in-plane direction. Fibers intruding into the gas channel were also observed. For the case with 20% compression ratio, the computed stress is mostly below 100 kPa with a maximum in excess of 1,000 kPa. Simulation results, which include stress and displacement distributions under compression, are in qualitative agreement with actual observations in the literature. The present methodology can be extended to most porous electrodes that involve material deformation to allow accurate evaluation of their transport properties and performance. [ABSTRACT FROM AUTHOR]

Published
2019
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