Thermodynamic analysis of MnWO4 as an oxygen carrier in a chemical looping scheme for hydrogen production

Next Sustainability Pub Date : 2024-01-01 DOI:10.1016/j.nxsust.2024.100033

Juliana López van der Horst , Francisco Pompeo

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Abstract

In the last few years, hydrogen has attracted much attention because of its importance in the transition to a sustainable energy system and its use as a raw material in many industrial processes. In this context, chemical looping is proposed as an alternative to traditional methane reforming processes, where methane is partially oxidized by the lattice oxygen of a solid oxygen carrier instead of using water or pure oxygen. This work presents a thermodynamic analysis of MnWO₄ as an oxygen carrier and the compositions at equilibrium were calculated by minimizing the total Gibbs free energy of the system. To evaluate its possible integration into a chemical looping scheme, this study assesses the optimal reaction temperature and reactant molar ratio to attain high hydrogen yield while avoiding carbon formation. The findings suggest that temperatures exceeding 775°C and ratios above stoichiometry are necessary. For successful regeneration, air or water can be used. In the former case a stoichiometric ratio of 1.5:1 of O₂ to MnO/W is required, while for the latter, an excess of water in necessary.

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化学循环制氢方案中作为氧载体的 MnWO4 的热力学分析

在过去几年中，氢气因其在向可持续能源系统过渡中的重要性以及在许多工业流程中作为原材料的用途而备受关注。在此背景下，有人提出了化学循环作为传统甲烷重整工艺的替代方法，即甲烷被固体氧载体的晶格氧部分氧化，而不是使用水或纯氧。本研究对作为氧载体的 MnWO4 进行了热力学分析，并通过最小化系统的总吉布斯自由能计算出了平衡时的成分。为了评估将其纳入化学循环方案的可能性，本研究评估了最佳反应温度和反应物摩尔比，以获得高产氢量，同时避免形成碳。研究结果表明，温度必须超过 775°C，反应物摩尔比必须高于化学计量。为了成功再生，可以使用空气或水。前者要求氧气与 MnO/W 的化学计量比为 1.5:1，而后者则需要过量的水。

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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