Preliminary Analysis of High-Temperature Corrosion of Metallic Alloys With CO2 and CO2-Based Working Mixtures for Power Plants Applications

Volume 9: Supercritical CO2 Pub Date : 2022-06-13 DOI:10.1115/gt2022-84197

Lorenza Putelli, G. Di Marcoberardino, M. Gelfi, C. Invernizzi, P. Iora, G. Manzolini

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Abstract

CO2 has been proposed in the past decades as a suitable working fluid in power plants. One way to reduce costs is to use carbon dioxide blends instead. There is a lack of knowledge about the behavior of sCO2 blending in the interaction with commercial alloys at high temperatures, so this aspect must be strictly considered. A preliminary study has been performed considering the oxidation behavior of some Ni-based and Fe-based alloy (i.e., alloy 625, AISI 304, and AISI 316) in different conditions. In each case, the oxidation layer developed on the alloy surface was investigated by scanning electron microscope (SEM) coupled with energy-dispersive X-ray spectroscopy (EDS). The analysis was also performed on the cross-section of the sample to evaluate the penetration depth of damage. The results show that the interaction with fluorine-containing compounds is more corrosive than pure CO2. This confirms that although the mixture improves the thermodynamic efficiency of the cycle, their compatibility with materials must be carefully investigated. However, in all the cases studied, in the test conditions, the preliminary analysis doesn’t recommend the use of the tested materials.

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电厂用CO2及CO2基工作混合物对金属合金高温腐蚀的初步分析

在过去的几十年里，二氧化碳被提议作为发电厂的一种合适的工作流体。降低成本的一种方法是使用二氧化碳混合物。由于对sCO2共混在高温下与工业合金相互作用中的行为缺乏了解，因此必须严格考虑这方面的问题。对某些镍基和铁基合金(即625合金、AISI 304合金和AISI 316合金)在不同条件下的氧化行为进行了初步研究。利用扫描电子显微镜(SEM)和能谱仪(EDS)对合金表面形成的氧化层进行了研究。还对试样的横截面进行了分析，以评估损伤的穿透深度。结果表明，与含氟化合物的相互作用比纯CO2具有更强的腐蚀性。这证实，虽然混合物提高了循环的热力学效率，但必须仔细研究它们与材料的相容性。然而，在所有研究的案例中，在测试条件下，初步分析不建议使用测试材料。

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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Volume 9: Supercritical CO2

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