Transport phenomena in fuel cells

燃料电池中的传输现象

• 批准号: 105723-2011
• 负责人: Djilali, Nedjib
• 金额: $ 5.1万
• 依托单位: University of Victoria
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2015
• 资助国家: 加拿大
• 起止时间: 2015-01-01 至 2016-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=569105
• 关键词: Transport; phenomena; fuel; cells

Polymer Electrolyte Membrane Fuel Cells (PEMFCs) are electrochemical energy conversion devices that can provide clean power to road vehicles, homes and portable electronics. The operation and durability of a fuel cell depend on the regulation of several transport processes: the flow of reactant gases, product water, heat, electrons and protons in conjunction with reaction kinetics. These processes take place in a variety of materials and components having characteristic features ranging from nanometers to centimeters. Further progress in this relatively young and evolving technology is limited by transport phenomena issues at the boundaries of current knowledge. Information on the morphological structure and transport parameters of the porous electrode layers is scarce. Liquid water is often present in PEMFCs, and while this helps maintain hydration of the polymer membrane, it also leads to flooding; the mechanisms of liquid water formation and transport are not well understood. Due to the multi-layered architecture of fuel cells, significant losses can occur at interfaces; the interfacial phenomena need to be characterized and quantified. The in-situ environment in a PEMFC makes experimental observations extremely challenging. We proposes new experimental and computational methods to: a) resolve the nano-structure and transport phenomena in composite catalyst layers by using a combination of advanced microscopy, reconstruction techniques and pore scale modelling; b) measure and predict the effective conductivities of porous electrodes; c) improve understanding of the challenging issue of water transport through visualization and dynamic simulations; d) integrate state-of-the art component models in a multi-scale computational framework; and e) validate and apply the model to explore novel concepts and strategies to improve transport processes. This research will inform development work at collaborating Canadian companies at the vanguard of fuel cell technology, will advances knowledge in two-phase and porous media transport processes relevant to many engineering and natural systems, and will provide stimulating opportunities to train young researchers.

聚合物电解质膜燃料电池（PEMFC）是一种电化学能量转换装置，可以为道路车辆、家庭和便携式电子设备提供清洁能源。燃料电池的运行和耐久性取决于几个传输过程的调节：反应气体、产物水、热、电子和质子的流动以及反应动力学。这些过程发生在具有从纳米到厘米的特性特征的各种材料和组件中。这一相对年轻和不断发展的技术的进一步进展受到目前知识边界上的传输现象问题的限制。多孔电极层的形态结构和传输参数的信息是稀缺的。液态水通常存在于PEMFC中，虽然这有助于保持聚合物膜的水合作用，但也会导致溢流;液态水形成和运输的机制尚未得到很好的理解。由于燃料电池的多层结构，在界面处可能会发生显著的损耗;需要对界面现象进行表征和量化。质子交换膜燃料电池的现场环境使得实验观测极具挑战性。我们提出了新的实验和计算方法：a）通过使用先进的显微镜、重建技术和孔尺度建模的组合来解决复合催化剂层中的纳米结构和传输现象; B）测量和预测多孔电极的有效电导率; c）通过可视化和动态模拟来提高对水传输的挑战性问题的理解; d）在多尺度计算框架中集成最先进的组件模型;以及e）验证和应用该模型以探索改进运输过程的新概念和策略。 这项研究将为处于燃料电池技术前沿的合作加拿大公司的开发工作提供信息，将促进与许多工程和自然系统相关的两相和多孔介质运输过程的知识，并将为培训年轻研究人员提供激励机会。