Investigation of Temperature Limitations During Rapid Thermal Cycling of a Micro-Tubular Flame-Assisted Fuel Cell

ASME 2020 14th International Conference on Energy Sustainability Pub Date : 2020-06-17 DOI:10.1115/es2020-1634

R. Milcarek, R. Ghotkar, J. Ahn

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引用次数: 1

Abstract

Despite many efforts and improvements over the last few decades, two of the major challenges facing Solid Oxide Fuel Cells (SOFCs) are slow heating rates to operating conditions (typically < 5 °C.min−1) and a limited ability to thermal cycle (< 200 cycles). Recently a novel hybridized setup that combines a fuel-rich combustion reformer with a SOFC was developed and utilized to investigate rapid heating, cooling and thermal cycling of a micro-Tubular SOFC. The setup places the SOFC directly in the flame and exhaust of the high temperature combustion of methane, which allows for extremely rapid temperature rise in the SOFC. A SOFC with a (La0.8Sr0.2)0.95MnO3-x cathode was tested in the setup, but limitations on air preheating for the cathode resulted in low SOFC cathode temperatures (∼500°C) and low power density. Thermal insulation improved pre-heating of the air delivered to the cathode, increased the SOFC cathode temperature and, when a (La0.60Sr0.40)0.95Co0.20Fe0.80O3-x cathode was applied to the SOFC, resulted in improved power density. After adjusting the thermal insulation, the air temperature near the cathode exceeded ∼750°C during testing. Over 3,000 thermal cycles were conducted at a heating rate exceeding 900°C.min−1 and a cooling rate that exceeded 300°C.min−1. The open circuit voltage was analyzed over the 150 h test and a low degradation rate of ∼0.0008V per 100 cycles per fuel cell was observed. Unlike the previous test, which was conducted at lower temperatures, significant degradation of the current collector was observed during this test. Electrochemical impedance spectroscopy shows that degradation in the SOFC was due to increases in ohmic losses, activation losses at the cathode and increased concentration losses. The setup demonstrates that rapid thermal cycling of micro-Tubular SOFCs can be achieved, but there are limitations on the maximum temperature that can be sustained depending on the current collector.

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微管火焰辅助燃料电池快速热循环温度限制研究

尽管在过去的几十年里做出了许多努力和改进，但固体氧化物燃料电池(sofc)面临的两个主要挑战是加热速度慢(通常< 5°C.min - 1)和热循环能力有限(< 200个循环)。最近，研究人员开发了一种新型的混合装置，将富燃料燃烧重整器与SOFC结合在一起，用于研究微管SOFC的快速加热、冷却和热循环。该装置将SOFC直接置于甲烷高温燃烧的火焰和废气中，这使得SOFC的温度急剧上升。在该装置中测试了具有(La0.8Sr0.2)0.95MnO3-x阴极的SOFC，但阴极空气预热的限制导致SOFC阴极温度低(~ 500°C)和低功率密度。隔热改善了空气的预热，提高了SOFC阴极的温度，当(La0.60Sr0.40)0.95Co0.20Fe0.80O3-x阴极应用于SOFC时，导致功率密度提高。在调整隔热后，测试过程中阴极附近的空气温度超过了~ 750°C。在超过900°C的加热速率下进行了3000多次热循环。min−1，冷却速率大于300℃min−1。在150小时的测试中分析了开路电压，观察到每个燃料电池每100次循环的低降解率为~ 0.0008V。与之前在较低温度下进行的测试不同，在本次测试中观察到集热器的显著退化。电化学阻抗谱分析表明，SOFC的降解是由于欧姆损失、阴极活化损失和浓度损失的增加。该装置表明，微管sofc的快速热循环是可以实现的，但根据集流器的不同，其最高温度是有限制的。

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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ASME 2020 14th International Conference on Energy Sustainability

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