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通过热台显微镜和球团腐蚀试验测定MgO和CrO基耐火原料对富PbO铜渣的耐腐蚀性。

Corrosion Resistance of MgO and CrO-Based Refractory Raw Materials to PbO-Rich Cu Slag Determined by Hot-Stage Microscopy and Pellet Corrosion Test.

作者信息

Ludwig Maciej, Śnieżek Edyta, Jastrzębska Ilona, Prorok Ryszard, Li Yawei, Liao Ning, Nath Mithun, Vlček Jozef, Szczerba Jacek

机构信息

Faculty of Materials Science and Ceramics, AGH University of Science and Technology, Al. Mickiewicza 30, 30-059 Kraków, Poland.

Forglass Sp. z.o.o., Wadowicka 8a, 30-415 Kraków, Poland.

出版信息

Materials (Basel). 2022 Jan 18;15(3):725. doi: 10.3390/ma15030725.

DOI:10.3390/ma15030725
PMID:35160671
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8836856/
Abstract

Chemical resistance of commercial refractory raw materials against Cu slag is critical to consider them as candidates for the production of refractories used in Cu metallurgy. In this study, we show the comparative results for the corrosion resistance of four commercial refractory raw materials-magnesia chromite co-clinkers FMC 45 and FMC 57, PAK, and fused spinel SP AM 70-against aggressive, low-melting PbO-rich Cu slag (Z1) determined by hot-stage microscopy (up to 1450 °C) and pellet test (1100 and 1400 °C). Samples were characterized after the pellet test by XRD, SEM/EDS, and examination of their physicochemical properties to explore the corrosion reactions and then assess comparatively their chemical resistance. Since many works have focused on corrosion resistance of refractory products, the individual refractory raw materials have not been investigated so far. In this work, we show that magnesia chromite co-clinker FMC 45 exhibits the most beneficial properties considering its application in the production of refractories for the Cu industry. Forsterite (MgSiO) and güggenite (CuMgO) solid solutions constitute corrosion products in FMC 45, and its mixture with slag shows moderate dimensional stability at high temperatures. On the other hand, the fused spinel SP AM 70 is the least resistant to PbO-rich Cu slag (Z1); it starts to sinter at 970 °C, followed by a fast 8%-shrinkage caused by the formation of güggenite solid solution in significant amounts.

摘要

商用耐火原料对铜渣的耐化学性对于将它们视为用于铜冶金的耐火材料生产候选材料而言至关重要。在本研究中,我们展示了四种商用耐火原料——镁铬共熔熟料FMC 45和FMC 57、PAK以及电熔尖晶石SP AM 70——对侵蚀性的、低熔点的富PbO铜渣(Z1)的耐腐蚀性对比结果,该结果是通过热台显微镜(最高1450°C)和造粒试验(1100和1400°C)测定的。造粒试验后,通过XRD、SEM/EDS对样品进行表征,并检测其物理化学性质,以探究腐蚀反应,进而比较评估它们的耐化学性。由于许多研究都集中在耐火产品的耐腐蚀性上,到目前为止尚未对单一的耐火原料进行研究。在本工作中,我们表明,考虑到镁铬共熔熟料FMC 45在铜工业耐火材料生产中的应用,它展现出了最有益的性能。镁橄榄石(MgSiO)和古根石(CuMgO)固溶体构成了FMC 45中的腐蚀产物,并且它与炉渣的混合物在高温下表现出适度的尺寸稳定性。另一方面,电熔尖晶石SP AM 70对富PbO铜渣(Z1)的耐受性最差;它在970°C开始烧结,随后由于大量形成古根石固溶体而快速收缩8%。

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