高温高压下 PEM 燃料电池中的动态热传输和质量传输:三维模型研究

IF 6.7 1区 工程技术 Q2 ENERGY & FUELS
Fuel Pub Date : 2024-11-06 DOI:10.1016/j.fuel.2024.133623
Qianqian Wang , Jixuan Lu , Weibo Zheng , Bing Li , Jim P. Zheng , Guomin Cui , Liang Hao , Pingwen Ming
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引用次数: 0

摘要

由于局部热波动和质量波动,新一代质子交换膜燃料电池(PEMFC)在高温(OTs)和高压(OPs)条件下会遇到重大挑战。本研究开发了一个三维瞬态模型,通过纳入微孔层的影响和通道沿线冷却剂温度的变化来分析这些动态变化。结果表明,将 OT 从 80 °C 提高到 90 °C 会使输出电压降低 34-78 mV,使电压欠调/过调增加 0.2-16.6 mV,并使阴极催化剂层(cCL)和冷却剂之间的温差从 1.2 °C 增加到 2.1 °C,从而导致 cCL 的温度波动更加不规则。这些影响源于 cCL 内气液水外流增加,导致膜脱水,特别是在通道附近的电解质中。因此,质子传导相对于氧还原反应(ORR)的滞后(以新引入的达姆克勒数量化)已成为影响传热和反应动力学的关键因素。相反,将 OPs 从 130 kPa [阳极]/120 kPa [阴极] 提高到 400 kPa [阳极]/390 kPa [阴极],可将输出电压提高 50-150 mV,并将动态负载下的质子传导滞后降低 12-54%。这种改善与更高的氧气浓度和膜水有关,而 cCL 温度降低 0.6-2 °C,则有助于提高氧气浓度和膜水。然而,由于膜水含量波动更大,OPs 的上升也导致电压欠调/过调增加,最终导致额外的功率损耗。这些发现对于优化 PEMFC 在极端条件下的性能和推动燃料电池技术的发展至关重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Dynamic thermal and mass transport in PEM fuel cells at elevated temperatures and pressures: A 3D model study
Next-generation proton-exchange membrane fuel cells (PEMFCs) encounter significant challenges at elevated temperatures (OTs) and pressures (OPs) due to local thermal and mass fluctuations. In this study, a three-dimensional transient model was developed to analyze these dynamics by incorporating the effects of the microporous layer and variations in the coolant temperature along the channel. The results indicate that increasing the OT from 80 °C to 90 °C decreases the output voltage by 34–78 mV, increases voltage undershoot/overshoot by 0.2–16.6 mV, and raises the temperature difference between the cathode catalyst layer (cCL) and coolant from 1.2 to 2.1 °C, leading to more irregular temperature fluctuations in the cCL. These effects stem from the increased gas–liquid water outflow within the cCL that induces membrane dehydration, particularly in the electrolyte near the channel. Consequently, the lag in proton conduction relative to the oxygen reduction reaction (ORR), as quantified by the newly introduced Damköhler number, has emerged as a critical factor that influences both heat transfer and reaction kinetics. Conversely, increasing OPs from 130 kPa [anode]/120 kPa [cathode] to 400 kPa [anode]/390 kPa [cathode] improves output voltage by 50–150 mV and reduces proton conduction hysteresis by 12–54 % under dynamic loads. This improvement is linked to higher O2 concentration and membrane water facilitated by a 0.6–2 °C decrease in cCL temperature. However, the rise in OPs also results in an increased voltage undershoot/overshoot due to greater fluctuations in the membrane water content, ultimately leading to additional power loss. These findings are crucial for optimizing PEMFC performance under extreme conditions and advancing fuel cell technology.
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来源期刊
Fuel
Fuel 工程技术-工程:化工
CiteScore
12.80
自引率
20.30%
发文量
3506
审稿时长
64 days
期刊介绍: The exploration of energy sources remains a critical matter of study. For the past nine decades, fuel has consistently held the forefront in primary research efforts within the field of energy science. This area of investigation encompasses a wide range of subjects, with a particular emphasis on emerging concerns like environmental factors and pollution.
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