Sustainable energy production, inherently transient and non-uniformly distributed around the world, requires the rapid development of sustainable energy storage technologies. Recently, pure iron powder was proposed as a high-energy density carrier. While promising, challenges are faced, such as nanoparticle emissions, micro-explosions or cavitation. In this work, a screening of the impact of the most common impurities in iron sources on these mechanisms was conducted through purely thermodynamic simulations. Two idealized models were considered to obtain a range of plausible flame temperatures and emitted gases when considering a purely diffusive regime in standard conditions and stoichiometric air–fuel mixture. The flame temperature and iron evaporation are increasing with the specific energy. A strong evaporation of C, S, Mo, Cu and P is also expected. Most impurities are predicted to decrease cavitation, except for Mn and MnO. The regeneration process by hydrogen-based direct reduction in fluidized bed reactors is also discussed. MgO and CaO are the most promising additions in terms of reducing nanoparticles and porosities, as well as to improve the fluidization and reduction kinetics of the combusted products. The potential of Fe powder as sustainable fuel, already very promising, could be further improved by the addition of selectively chosen impurities.This article is part of the discussion meeting issue 'Sustainable metals: science and systems'.
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机译:可持续能源生产本质上是瞬态的,并且在全球范围内分布不均匀,需要可持续储能技术的快速发展。最近,纯铁粉被提出作为一种高能量密度的载体。虽然前景广阔,但也面临着挑战,例如纳米颗粒排放、微爆炸或空化。在这项工作中,通过纯热力学模拟筛选了铁源中最常见的杂质对这些机制的影响。在考虑标准条件下的纯扩散状态和化学计量空气-燃料混合物时,考虑了两个理想化模型以获得一系列合理的火焰温度和排放气体。火焰温度和铁蒸发量随着比能量的增加而增加。预计 C、S、Mo、Cu 和 P 也会强烈蒸发。预计大多数杂质会减少空化,但 Mn 和 MnO 除外。还讨论了流化床反应器中氢基直接还原的再生过程。MgO 和 CaO 是减少纳米颗粒和孔隙率以及改善燃烧产物的流化和还原动力学方面最有前途的添加剂。铁粉作为可持续燃料的潜力已经非常有前途,可以通过添加选择性选择的杂质来进一步提高。本文是讨论会议题“可持续金属:科学与系统”的一部分。
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