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高温氧化过程中曲面的原位热重分析

In Situ Thermogravimetric Analysis of Curved Surfaces During High-Temperature Oxidation.

作者信息

Kendall Megan, Auinger Michael, Robinson Cadyn L J, Owen Chris, Sackett Elizabeth

机构信息

Department of Materials Science and Engineering, Swansea University, Swansea SA1 8EN, UK.

WMG, University of Warwick, Coventry CV4 7AL, UK.

出版信息

Materials (Basel). 2025 May 24;18(11):2463. doi: 10.3390/ma18112463.

DOI:10.3390/ma18112463
PMID:40508461
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12155867/
Abstract

Conveyance tube manufacturing via a hot-finished, welded route is an energy-intensive process that promotes the rapid surface oxidation of curved surfaces. Previous studies have used computational and theoretical techniques to assess the oxidation of curved surfaces. However, experimental techniques for assessing the oxidation of curved surfaces, as well as for validating existing computational and analytical studies, have significant limitations that impact their ability to accurately recreate industrial processes. The challenges of thermogravimetric analysis (TGA) for in situ tests for the oxidation of cylindrical geometries were investigated, using an as-welded conveyance tube, and compared to an equivalent tube normalised in industry as well as computational predictions for the same geometry and thermal conditions. A core element of this work was the use of a refractory dummy sample to quantify thermal buoyancy and flow-induced vibration. There was a strong agreement between the oxide mass gain predicted by a computational model compared to that of the TGA sample, with only a 5% discrepancy. However, oxide thickness gain, measured using electron microscopy, showed poor agreement, particularly when comparing industrial and experimental results. This was attributed to the need for further work to account for transient heating, oxide porosity, atmospheric composition variation, and the effect of thermomechanical operations during conveyance tube manufacturing, e.g., hydraulic descaling.

摘要

通过热加工焊接路线制造输送管是一个能源密集型过程,会促进曲面的快速表面氧化。先前的研究已使用计算和理论技术来评估曲面的氧化情况。然而,用于评估曲面氧化以及验证现有计算和分析研究的实验技术存在重大局限性,影响了它们准确重现工业过程的能力。使用一根焊态输送管研究了热重分析(TGA)用于圆柱形几何形状原位氧化测试的挑战,并将其与工业上归一化的等效管以及相同几何形状和热条件下的计算预测进行了比较。这项工作的一个核心要素是使用耐火假样品来量化热浮力和流动引起的振动。计算模型预测的氧化物质量增益与TGA样品的氧化物质量增益之间有很强的一致性,差异仅为5%。然而,使用电子显微镜测量的氧化物厚度增益显示出较差的一致性,特别是在比较工业和实验结果时。这归因于需要进一步开展工作来考虑瞬态加热、氧化物孔隙率、大气成分变化以及输送管制造过程中的热机械操作(如液压除鳞)的影响。

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