Effects of CaO addition into CuO/ZnO/Al2O3 catalyst on hydrogen production through water gas shift reaction

International Journal of Renewable Energy Development Pub Date : 2024-05-15 DOI:10.61435/ijred.2024.59257

Z. D. Hastuti, E. Rosyadi, Hana Nabila Anindita, Imron Masfuri, Nurdiah Rahmawati, Tyas Puspita Rini, Trisno Anggoro, Wargiantoro Prabowo, F. R. Saputro, Ade Syafrinaldy

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Abstract

Hydrogen is a promising renewable energy carrier and eco-friendly alternative to fossil fuels. Water-gas-shift reaction (WGSR) is commonly used to generate hydrogen from renewable biomass feedstocks. Enriching hydrogen content in synthesis gas (syngas) production can be made possible by applying the WGSR after gasification. WGSR can achieve a maximal carbon monoxide (CO) conversion using a commercially patented CZA (Cu/ZnO/Al2O3) catalyst. This study proposed three in-lab self-synthesized CZA catalysts to be evaluated and compared with the patented catalyst performance-wise. The three catalysts were prepared with co-precipitation of different Cu:Zn:Al molar ratios: CZA-431 (4:3:1), CZA-531 (5:3:1) and CZA-631 (6:3:1). The catalysts characteristics were determined through X-ray diffraction (XRD), Brunauer-Emmett-Teller (BET) analysis and Scanning Electron Microscopy (SEM) techniques. CO gas was mixed with steam in a catalytic reactor with a 3:1 molar ratio, running continuously through the catalyst at 250 °C for 30 mins. All three catalysts, however, performed below expectations, where CZA-431 had a CO conversion of 77.44%, CZA-531 48.75%, and CZA-631 71.67%. CaO, as a co-catalyst, improved the performance by stabilizing the gas composition faster. The CO conversion of each catalyst also improved: CZA-431 improved its CO conversion to 97.39%, CZA-531 to 96.71%, and CZA-631 to 95.41%. The downward trend of the CO conversion was deemed to be caused by copper content found in CZA-531 and CZA-631 but not in CZA-431, which tended to form a Cu-Zn metal complex, weakening the catalyst's activity.

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在 CuO/ZnO/Al2O3 催化剂中添加 CaO 对通过水煤气变换反应制氢的影响

氢是一种前景广阔的可再生能源载体，也是化石燃料的生态友好型替代品。水-气变换反应（WGSR）通常用于从可再生生物质原料中制氢。通过在气化后应用水-气变换反应，可以提高合成气（Syngas）生产中的氢含量。使用获得商业专利的 CZA（Cu/ZnO/Al2O3）催化剂，WGSR 可实现一氧化碳（CO）的最大转化率。本研究提出了三种实验室自合成的 CZA 催化剂，并与专利催化剂进行了性能评估和比较。这三种催化剂是通过共沉淀不同摩尔比的 Cu:Zn:Al 制得的：CZA-431 (4:3:1)、CZA-531 (5:3:1) 和 CZA-631 (6:3:1)。催化剂的特性是通过 X 射线衍射 (XRD)、Brunauer-Emmett-Teller (BET) 分析和扫描电子显微镜 (SEM) 技术确定的。一氧化碳气体与蒸汽在催化反应器中以 3:1 的摩尔比混合，在 250 °C 下连续通过催化剂 30 分钟。然而，所有三种催化剂的性能都低于预期，其中 CZA-431 的 CO 转化率为 77.44%，CZA-531 为 48.75%，CZA-631 为 71.67%。作为助催化剂，CaO 可以更快地稳定气体成分，从而提高性能。每种催化剂的 CO 转化率也有所提高：CZA-431 的 CO 转化率提高到 97.39%，CZA-531 提高到 96.71%，CZA-631 提高到 95.41%。一氧化碳转化率的下降趋势被认为是由于 CZA-531 和 CZA-631 中的铜含量造成的，而 CZA-431 中的铜含量并不高。

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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International Journal of Renewable Energy Development

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