Transport Phenomena in Fuel Cells

燃料电池中的传输现象

• 批准号: RGPIN-2016-05479
• 负责人: Djilali, Nedjib
• 金额: $ 4.23万
• 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: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=709756
• 关键词: Transport; Phenomena; Fuel; Cells

Fuel cells are electrochemical energy conversion devices that offer the prospect of efficient, low to zero emission power for vehicles, homes and portable electronics. The long-term objectives of the proposed research are to facilitate the commercial deployment of polymer electrolyte membrane (PEM) fuel cells by lowering performance and cost barriers. We propose to measure, model and predict the transfer process of reactant gases, heat, mass, water, electrical and protonic chargecollectively known as transport phenomenathat are central to the performance and cost of PEM fuel cells. These transport phenomena and the electrochemical energy conversion that generates power take place in the membrane-electrode assembly (MEA). The MEA is a thin multilayered structure consisting of a PEM sandwiched between three distinct porous layers: a nanostructured composite catalyst layer; a micro-porous layer; and a fibrous gas diffusion layer. Many of the limitations of current technology are associated with the lack of fundamental understanding of the transport processes and of their relationship to the structure and morphology of the MEA porous layers. In the first axis of this multi-pronged research program we will use a combination of tomographic imaging, numerical reconstruction and advanced computational modelling to resolve transport phenomena, including dynamic liquid water transport, within the nanostructure of the fuel cell porous media. This will provide critical information on the effectiveness of the transport processes and their relationship to the nanostructure of the porous layers and to the interfaces between them. The second axis will addresses the question of how to eventually control the fabrication process to realize such designs/structures. Catalyst layers are fabricated by depositing and drying an “ink” consisting of suspended particles that tend to agglomerate. We will chart new directions with simulations and novel microscopic visualization of the process to shed light on the fabrication process which to date has evolved by trial and error. The third axis will synthesize fundamental insights, observations and models to a) explore functionalized porous media that optimize transport and catalyst utilization; and b) develop a bipolar membrane fuel cell that combines an acidic PEM on the anode with an alkaline anion exchange membrane and which allows self-humidified operation that minimizes losses, as well as use of less expensive non-precious metal catalysts. This program addresses pacing issue in the commercialization of fuel cells; furthers the boundaries of knowledge in transport phenomena relevant to a wide range of applications, including batteries, water filtration, and geological carbon sequestration; and provides exciting opportunities for training highly qualified personnel in areas of critical importance to the Canadian clean energy sector.

燃料电池是电化学能量转换装置，其为车辆、家庭和便携式电子设备提供高效、低至零排放功率的前景。拟议研究的长期目标是通过降低性能和成本障碍来促进聚合物电解质膜（PEM）燃料电池的商业部署。 我们建议测量，建模和预测的反应物气体，热，质量，水，电和质子chargecolecultively称为传输phenomenathat是核心的PEM燃料电池的性能和成本的传输过程。这些传输现象和产生电力的电化学能量转换发生在膜电极组件（MEA）中。MEA是由夹在三个不同多孔层之间的PEM组成的薄多层结构：纳米结构化复合催化剂层;微孔层;和纤维气体扩散层。当前技术的许多局限性与缺乏对传输过程及其与MEA多孔层结构和形态的关系的基本了解有关。 在这个多管齐下的研究计划的第一轴，我们将使用断层成像，数值重建和先进的计算建模相结合，以解决运输现象，包括动态液态水运输，在燃料电池多孔介质的纳米结构。这将提供关键信息的传输过程的有效性和它们的关系的纳米结构的多孔层和它们之间的界面。 第二个轴将解决如何最终控制制造过程以实现这种设计/结构的问题。催化剂层通过沉积和干燥由倾向于聚集的悬浮颗粒组成的“油墨”来制造。我们将绘制新的方向与模拟和新的微观可视化的过程中，揭示了制造过程中，迄今已演变的试验和错误。 第三个轴将综合基本见解、观察和模型，以a）探索优化传输和催化剂利用的功能化多孔介质;和B）开发一种双极膜燃料电池，该电池将阳极上的酸性PEM与碱性阴离子交换膜结合起来，并允许自增湿操作以最大限度地减少损失，以及使用更便宜的非贵金属催化剂。 该计划解决了燃料电池商业化的步伐问题;进一步扩大了与广泛应用相关的运输现象的知识边界，包括电池，水过滤和地质碳封存;并为培训加拿大清洁能源部门至关重要的领域的高素质人员提供了令人兴奋的机会。