Solid Oxide Fuel Cell Anode Porosity and Tortuosity Effect on the Exergy Efficiency

IF 4.3 3区工程技术 Q2 ENERGY & FUELS

International Journal of Energy Research Pub Date : 2024-10-16 DOI:10.1155/2024/4928675

Khalid Zouhri, Mohamed Mohamed, Kayla Nulph, Parker Laubie, Luke Snyder

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Abstract

Improving the efficiency of solid oxide fuel cells (SOFCs) is critical for advancing clean energy solutions on a global scale. One major challenge in enhancing SOFC efficiency is reducing anode diffusion polarization, which can significantly hinder performance. This study addresses this issue by investigating the effects of anode tortuosity and porosity on the exergy efficiency of SOFCs. The novelty of this research lies in its comprehensive numerical model, which uniquely incorporates detailed material properties and their impact on SOFC performance—specifically focusing on anode tortuosity and porosity. Using advanced Multiphysics software, we developed a model that solves mass, electron transfer, and energy equations discretized via the finite differences method. The study meticulously examines how variations in these parameters influence SOFC efficiency, providing new insights into optimal anode design. Our methodology involves simulating different anode configurations to pinpoint the key parameters that affect exergy efficiency, thereby minimizing the experimental costs and time associated with traditional approaches. The quantitative results of this study are significant. We found that an anode tortuosity of 5.5 and a porosity range of 0.05–0.1 optimize exergy efficiency, achieving a 15% improvement compared to conventional designs. Additionally, a mean pore radius between 15 and 20 µm was identified as optimal for enhancing cell voltage. These findings elucidate the critical relationship between anode material properties and SOFC performance, offering a practical pathway to improving efficiency. This research provides a novel numerical approach to understanding and optimizing anode characteristics in SOFCs. By highlighting the importance of specific material properties, such as tortuosity and porosity, and demonstrating their impact on exergy efficiency, this study offers valuable guidance for future SOFC design and development.

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固体氧化物燃料电池阳极孔隙率和扭曲度对能效的影响

提高固体氧化物燃料电池（SOFC）的效率对于在全球范围内推进清洁能源解决方案至关重要。提高 SOFC 效率的一个主要挑战是减少阳极扩散极化，这会严重影响其性能。本研究通过研究阳极扭曲度和多孔性对 SOFC 放能效率的影响来解决这一问题。这项研究的新颖之处在于其全面的数值模型，该模型独特地纳入了详细的材料特性及其对 SOFC 性能的影响，特别是侧重于阳极瘤状度和孔隙率。我们使用先进的 Multiphysics 软件开发了一个模型，该模型通过有限差分法离散求解质量、电子转移和能量方程。研究细致地考察了这些参数的变化如何影响 SOFC 的效率，为优化阳极设计提供了新的见解。我们的方法包括模拟不同的阳极配置，找出影响能效的关键参数，从而最大限度地减少与传统方法相关的实验成本和时间。这项研究的定量结果意义重大。我们发现，阳极曲度为 5.5、孔隙率范围为 0.05-0.1 可以优化放能效率，与传统设计相比，放能效率提高了 15%。此外，平均孔半径在 15 至 20 微米之间被认为是提高电池电压的最佳值。这些发现阐明了阳极材料特性与 SOFC 性能之间的重要关系，为提高效率提供了一条切实可行的途径。这项研究为了解和优化 SOFC 的阳极特性提供了一种新颖的数值方法。本研究强调了特定材料特性（如韧性和孔隙率）的重要性，并证明了它们对放电效率的影响，从而为未来 SOFC 的设计和开发提供了宝贵的指导。

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来源期刊

International Journal of Energy Research 工程技术-核科学技术

CiteScore

9.80

自引率

8.70%

发文量

1170

审稿时长

3.1 months

期刊介绍： The International Journal of Energy Research (IJER) is dedicated to providing a multidisciplinary, unique platform for researchers, scientists, engineers, technology developers, planners, and policy makers to present their research results and findings in a compelling manner on novel energy systems and applications. IJER covers the entire spectrum of energy from production to conversion, conservation, management, systems, technologies, etc. We encourage papers submissions aiming at better efficiency, cost improvements, more effective resource use, improved design and analysis, reduced environmental impact, and hence leading to better sustainability. IJER is concerned with the development and exploitation of both advanced traditional and new energy sources, systems, technologies and applications. Interdisciplinary subjects in the area of novel energy systems and applications are also encouraged. High-quality research papers are solicited in, but are not limited to, the following areas with innovative and novel contents: -Biofuels and alternatives -Carbon capturing and storage technologies -Clean coal technologies -Energy conversion, conservation and management -Energy storage -Energy systems -Hybrid/combined/integrated energy systems for multi-generation -Hydrogen energy and fuel cells -Hydrogen production technologies -Micro- and nano-energy systems and technologies -Nuclear energy -Renewable energies (e.g. geothermal, solar, wind, hydro, tidal, wave, biomass) -Smart energy system