Development of an ejector for passive hydrogen recirculation in PEM fuel cell systems by applying 2D CFD simulation

Automotive and Engine Technology Pub Date : 2023-07-31 DOI:10.1007/s41104-023-00133-z

Gerald Singer, Rebekka Köll, Patrick Pertl, Alexander Trattner

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Abstract

The anode subsystem is a major energy consumer of polymer-electrolyte-membrane (PEM) fuel cell systems. A passive hydrogen recirculation system, like an ejector, is an excellent solution to maximize hydrogen utilization while maintaining low parasitic losses. However, high development efforts are necessary to maximize the performance of the ejector for the entire operating range. This research paper provides part of a toolchain for ejector development, consisting in particular of a multi-parameter simulation based on rotational symmetric 2D CFD. The 2D CFD greatly helps optimize the design of the ejector, reducing development effort, and increasing accuracy. In addition, the main correlations between thermodynamic states and geometry on the entrainment ratio are evaluated. Subsequently, an ejector is designed for a PEM fuel cell application using 2D CFD and the results show in which operating range a single ejector can be applied. This toolchain enables rapid design and optimization of ejector geometry, saving development time and cost while increasing accuracy and extending the operating range.

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应用二维CFD模拟开发PEM燃料电池系统中用于被动氢气再循环的喷射器

阳极子系统是聚合物电解质膜（PEM）燃料电池系统的主要能源消耗者。被动氢气再循环系统，如喷射器，是一种极好的解决方案，可以最大限度地提高氢气利用率，同时保持低寄生损耗。然而，为了在整个操作范围内最大限度地提高喷射器的性能，需要付出高昂的开发努力。本文为喷射器的开发提供了工具链的一部分，特别是基于旋转对称二维CFD的多参数模拟。2D CFD大大有助于优化喷射器的设计，减少开发工作量，提高精度。此外，还评估了热力学状态和几何结构之间对夹带率的主要相关性。随后，使用2D CFD为PEM燃料电池应用设计了一个喷射器，结果表明在哪个工作范围内可以应用单个喷射器。该工具链能够快速设计和优化喷射器几何结构，节省开发时间和成本，同时提高精度并扩大操作范围。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Automotive and Engine Technology

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