马氏体和奥氏体钢的低温等离子体氮化以提高耐摩擦腐蚀性能*

IF 0.3 Q4 THERMODYNAMICS HTM-Journal of Heat Treatment and Materials Pub Date : 2023-02-01 DOI:10.1515/htm-2022-1030
I. Hahn, S. Siebert, H. Paschke, T. Brückner, S. Weber
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引用次数: 0

摘要

摩擦腐蚀是摩擦系统中磨损和腐蚀同时发生及其相互作用。在许多应用中,例如食品工业或医药中的介质润滑滚动轴承和(切削)工具,会发生摩擦腐蚀并导致高材料损失和材料损坏。低温等离子体氮化处理可显著提高机械和化学应力钢表面的耐摩擦腐蚀性能。在这个过程中,氮被强行溶解在表面区域(高达约。20 μm),含量高达15wt .-%,无沉淀。这导致金属晶格的极端膨胀和变形(“膨胀马氏体”,“膨胀奥氏体”),这导致硬度增加高达1000 HV,同时具有相同甚至更高的抗点蚀性。由于膨胀马氏体/奥氏体的形成,马氏体钢X40Cr14和X54CrMnN13-2以及奥氏体CrMn钢的耐摩擦腐蚀性能较初始状态有显著提高,表现为摩擦腐蚀侵蚀下材料损失降低40 - 70%。结果表明,耐摩擦腐蚀性能与表面处理工艺参数、钢的化学成分及其晶格有关。
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Low-Temperature Plasma Nitriding of Martensitic and Austenitic Steels to Increase Tribocorrosion Resistance*
Abstract Tribocorrosion is the simultaneous occurrence of wear and corrosion in a tribosystem and their interaction. In many applications, such as media-lubricated rolling bearings and (cutting-)tools in the food industry or medicine, tribocorrosion occurs and leads to a high material loss and damage to materials. The tribocorrosion resistance of mechanically and chemically stressed steel surfaces can be significantly increased by low-temperature plasma nitriding at T < 400 °C. In this process, nitrogen is forcibly dissolved in the surface area (up to approx. 20 μm) in high contents of 15 wt.-% without precipitation. This results in an extreme expansion and distortion of the metal lattice (“expanded martensite”, “expanded austenite”), which leads to an increase in hardness of up to 1000 HV with the same or even increased pitting corrosion resistance. Due to the formation of expanded martensite/austenite, the tribocorrosion resistance of the martensitic steels X40Cr14 and X54CrMnN13-2 and that of an austenitic CrMn steel can be significantly improved compared to the initial state, which is expressed in a 40–70 % lower material loss under tribocorrosive attack. It was found that the tribocorrosion resistance depends on the process parameters of the surface treatment and on the chemical composition of the steels and their crystal lattice.
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