High Purity Hydrogen and Carbon Dioxide Separation with Electrochemical Pump Operation of HT-PBI Fuel Cell at 120°C

ECS Meeting Abstracts Pub Date : 2023-08-28 DOI:10.1149/ma2023-01361955mtgabs

Derrick Maxwell, Qiang Sun, Humberto Rojas, Ian Kendrick, Ryan Pavlicek, Emory De Castro, Akarsh Aurora, Sanjeev Mukerjee

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Abstract

A commercially available, polybenzimidazole (PBI) membrane based electrochemical hydrogen pump (EHP) platform was thoroughly evaluated to generate a benchmark set of performance. A primary gas mixture of CO 2 and H 2 with a ratio of 4:1 was selected to demonstrate the performance of EHP s while addressing concerns of CO 2 poisoning effect. There is no indication of significant CO poisoning as a result of reverse water gas shift reaction (RWGS), and nearly Faradaic current efficiencies were successfully achieved. It was found that humidification of the feed gas at room temperature improved polarization performance while also improving energy efficiency, thus reducing the need for tightly controlled relative humidity of feed gas. A new perspective on EHP energy efficiency calculation methodology is also provided by inclusion of the cell heating requirement into the calculation. In this manner, an overall improvement to energy efficiency nearing 20% was realized by dropping the cell temperature to 120°C while paying no significant penalty to electrochemical performance. Nearly 99.99% pure H 2 and 99.93% pure CO 2 were produced with a hydrogen yield of 99.34%.

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HT-PBI燃料电池在120°C下电化学泵操作的高纯氢和二氧化碳分离

对市售的聚苯并咪唑(PBI)膜基电化学氢泵(EHP)平台进行了全面评估，以产生一组基准性能。在解决CO 2中毒问题的同时，选择CO 2和H 2的主要气体混合物，其比例为4:1，以展示EHP s的性能。没有迹象表明，由于反向水气转换反应(RWGS)导致严重的CO中毒，并且成功地实现了接近法拉第电流效率。研究发现，在室温下对原料气进行加湿可以改善极化性能，同时提高能源效率，从而减少对原料气相对湿度的严格控制。通过将电池加热要求纳入计算，还提供了EHP能源效率计算方法的新视角。通过这种方式，将电池温度降至120°C，在电化学性能没有明显损失的情况下，实现了近20%的整体能效提升。氢气产率为99.34%，h2纯度接近99.99%，co2纯度为99.93%。

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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