质子交换膜电解槽流场结构研究现状及展望

摘要/Abstract

摘要： 随着全球“双碳”目标的推进，能源转型的核心挑战聚焦于风光电等可再生能源的高效利用，而质子交换膜（PEM）电解水过程响应速度快、能耗低、产氢压力高，适应可再生能源发电的波动性特征。目前质子交换膜电解槽（PEMEC）的高成本制约其大规模应用，优化流道设计以提高电流密度是实现降本增效的关键技术路径。分析了平行、蛇形、叉指形、网格状流道等类型的优劣，并总结了流道与其他组件（如扩散层、催化层）的协同优化研究进展。结果表明，通过优化流道几何形状，可以有效改善流体动力学特性，提升传质和传热效率，同时减少流动阻力、气泡滞留以及局部电流密度不均等问题，显著提高电解槽的整体性能，可为PEMEC的进一步优化提供参考。

关键词: 质子交换膜电解槽, 流道几何形状, 协同优化, 模拟

Abstract: With the global advancement of carbon peaking and carbon neutrality goals, the core challenge of energy transition focuses on the efficient utilization of renewable energy sources such as wind and solar power. Proton exchange membrane (PEM) water electrolysis, characterized by its fast response, low energy consumption, and high hydrogen production pressure, is well-suited to accommodate the fluctuating nature of renewable energy generation, making it a rational choice for integrating renewable energy. However, the high cost of PEM electrolyzers (PEMEC) currently limits their large-scale application. Optimizing flow channel design to increase current density is a critical technological pathway for cost reduction. The advantages and disadvantages of parallel, serpentine, interdigitated, grid-like, and other less common flow channel typesare comprehensively reviewed,and the current state of research on the synergistic optimization of flow channels with other components (such as diffusion layers and catalytic layers) are analyzeed. Comprehensive analysis indicates that optimizing the geometric shape of flow channels can effectively improve fluid dynamic properties, enhance mass and heat transfer efficiency, while reducing flow resistance, bubble retention, and uneven local current density distribution. These improvements can significantly enhance the overall performance of the electrolyzer, providing valuable insights for the further optimization of PEMEC.

Key words: proton exchange membrane electrolyzer, flow channel geometry, synergistic optimization, simulation

王子朋王晶晶王延飞郑梦莲. 质子交换膜电解槽流场结构研究现状及展望[J]. 石油炼制与化工, 2026, 57(2): 1-12.

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