{"title":"质子交换膜燃料电池磨合/调节的基础和实践方面。","authors":"Mitja Kostelec, Matija Gatalo, Nejc Hodnik","doi":"10.1002/tcr.202400114","DOIUrl":null,"url":null,"abstract":"<p>Proton exchange membrane fuel cells (PEMFCs) have proven to be a promising power source for various applications ranging from portable devices to automotive and stationary power systems. The production of PEMFC involves numerous stages in the value chain, with each stage presenting unique challenges and opportunities to improve the overall performance and durability of the PEMFC stack. These include steps such as manufacturing the key components such as the platinum-based catalyst, processing these components into the membrane electrode assemblies (MEAs), and stacking the MEAs to ultimately produce a PEMFC stack. However, it is also known that the break-in or conditioning phase of the stack plays a crucial role in the final performance as well as durability. It involves several key phenomena such as hydration of the membrane, swelling of the ionomer, redistribution of the catalyst and the creation of suitable electrochemical interfaces – establishment of the triple phase boundary. These improve the proton conductivity, the mass transport of reactants and products, the catalytic activity of the electrode and thus the overall efficiency of the FC. The cruciality of break-in is demonstrated by the improvement in performance, which can even be over 50 % compared to the initial state. The state-of-the-art approach for the break-in of MEAs involves an electrochemical protocol, such as voltage cycling, using a PEMFC testing station. This method is time-consuming, equipment-intensive, and costly. Therefore, new, elegant, and cost-effective solutions are needed. Nevertheless, the primary aim is to achieve maximum/optimal performance so that it is fully operational and ready for the market. It is therefore essential to better understand and deconvolute these complex mechanisms taking place during break-in/conditioning. Strategies include controlled humidity and temperature cycling, novel electrode materials and other advanced break-in methods such as air braking, vacuum activation or steaming. In addition, it is critical to address the challenges associated with standardisation and quantification of protocols to enable interlaboratory comparisons to further advance the field.</p>","PeriodicalId":10046,"journal":{"name":"Chemical record","volume":null,"pages":null},"PeriodicalIF":7.0000,"publicationDate":"2024-10-08","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/tcr.202400114","citationCount":"0","resultStr":"{\"title\":\"Fundamental and Practical Aspects of Break-In/Conditioning of Proton Exchange Membrane Fuel Cells\",\"authors\":\"Mitja Kostelec, Matija Gatalo, Nejc Hodnik\",\"doi\":\"10.1002/tcr.202400114\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Proton exchange membrane fuel cells (PEMFCs) have proven to be a promising power source for various applications ranging from portable devices to automotive and stationary power systems. 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The cruciality of break-in is demonstrated by the improvement in performance, which can even be over 50 % compared to the initial state. The state-of-the-art approach for the break-in of MEAs involves an electrochemical protocol, such as voltage cycling, using a PEMFC testing station. This method is time-consuming, equipment-intensive, and costly. Therefore, new, elegant, and cost-effective solutions are needed. Nevertheless, the primary aim is to achieve maximum/optimal performance so that it is fully operational and ready for the market. It is therefore essential to better understand and deconvolute these complex mechanisms taking place during break-in/conditioning. Strategies include controlled humidity and temperature cycling, novel electrode materials and other advanced break-in methods such as air braking, vacuum activation or steaming. 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引用次数: 0
摘要
质子交换膜燃料电池(PEMFC)已被证明是一种前景广阔的动力源,适用于从便携式设备到汽车和固定动力系统等各种应用领域。质子交换膜燃料电池的生产涉及价值链中的多个阶段,每个阶段都为提高质子交换膜燃料电池堆的整体性能和耐用性带来了独特的挑战和机遇。这些步骤包括制造铂基催化剂等关键部件、将这些部件加工成膜电极组件(MEA)以及堆叠 MEA 以最终生产出 PEMFC 堆。然而,众所周知,堆栈的磨合或调节阶段对最终性能和耐用性起着至关重要的作用。这涉及几个关键现象,如膜的水化、离子聚合物的膨胀、催化剂的重新分布以及合适的电化学界面的形成--三相边界的建立。这些现象改善了质子传导性、反应物和产物的质量传输、电极的催化活性,从而提高了 FC 的整体效率。性能的改善证明了磨合的重要性,与初始状态相比,性能改善甚至可以超过 50%。最先进的 MEA 磨合方法涉及电化学协议,例如使用 PEMFC 测试站进行电压循环。这种方法耗时长、设备密集、成本高昂。因此,我们需要新的、优雅的和具有成本效益的解决方案。然而,首要目标是实现最高/最优性能,使其能够完全投入使用,并随时准备投放市场。因此,必须更好地理解和破解磨合/调节过程中发生的这些复杂机制。策略包括控制湿度和温度循环、新型电极材料和其他先进的磨合方法,如空气制动、真空激活或蒸气。此外,关键是要解决与协议标准化和量化相关的挑战,以便进行实验室间比较,进一步推动该领域的发展。
Fundamental and Practical Aspects of Break-In/Conditioning of Proton Exchange Membrane Fuel Cells
Proton exchange membrane fuel cells (PEMFCs) have proven to be a promising power source for various applications ranging from portable devices to automotive and stationary power systems. The production of PEMFC involves numerous stages in the value chain, with each stage presenting unique challenges and opportunities to improve the overall performance and durability of the PEMFC stack. These include steps such as manufacturing the key components such as the platinum-based catalyst, processing these components into the membrane electrode assemblies (MEAs), and stacking the MEAs to ultimately produce a PEMFC stack. However, it is also known that the break-in or conditioning phase of the stack plays a crucial role in the final performance as well as durability. It involves several key phenomena such as hydration of the membrane, swelling of the ionomer, redistribution of the catalyst and the creation of suitable electrochemical interfaces – establishment of the triple phase boundary. These improve the proton conductivity, the mass transport of reactants and products, the catalytic activity of the electrode and thus the overall efficiency of the FC. The cruciality of break-in is demonstrated by the improvement in performance, which can even be over 50 % compared to the initial state. The state-of-the-art approach for the break-in of MEAs involves an electrochemical protocol, such as voltage cycling, using a PEMFC testing station. This method is time-consuming, equipment-intensive, and costly. Therefore, new, elegant, and cost-effective solutions are needed. Nevertheless, the primary aim is to achieve maximum/optimal performance so that it is fully operational and ready for the market. It is therefore essential to better understand and deconvolute these complex mechanisms taking place during break-in/conditioning. Strategies include controlled humidity and temperature cycling, novel electrode materials and other advanced break-in methods such as air braking, vacuum activation or steaming. In addition, it is critical to address the challenges associated with standardisation and quantification of protocols to enable interlaboratory comparisons to further advance the field.
期刊介绍:
The Chemical Record (TCR) is a "highlights" journal publishing timely and critical overviews of new developments at the cutting edge of chemistry of interest to a wide audience of chemists (2013 journal impact factor: 5.577). The scope of published reviews includes all areas related to physical chemistry, analytical chemistry, inorganic chemistry, organic chemistry, polymer chemistry, materials chemistry, bioorganic chemistry, biochemistry, biotechnology and medicinal chemistry as well as interdisciplinary fields.
TCR provides carefully selected highlight papers by leading researchers that introduce the author''s own experimental and theoretical results in a framework designed to establish perspectives with earlier and contemporary work and provide a critical review of the present state of the subject. The articles are intended to present concise evaluations of current trends in chemistry research to help chemists gain useful insights into fields outside their specialization and provide experts with summaries of recent key developments.