Influence of the Deep Cryogenic Treatment at the Stabilization of Martensitic Transformation Temperatures at the Smart Material Alloy Cu-14Al-4Ni

E. Lima, M. Nava, P. C. Lima
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Abstract

DCT (deep cryogenic treatment) is commonly used in industry to improve the wear resistance characteristics of steels, especially. However, there are just a few researches about the effects on non-ferrous metals. The purpose of this work was to investigate how DCT affects the properties of Cu-14Al-4Ni alloy treated at different soak time and submitted to thermomechanical cycling. A comparative experimental analysis was performed of the thermal properties of alloys obtained on a vacuum furnace, treated by DCT and thermomechanically cyclized. The results indicates that thermomechanical cycling promoted the appearance and growth of the martensitic phase γ'1, less ductile than the martensitic phase β'1, which together with the induced hardening produced an increase in transformation temperatures and microhardness. The higher the number of cycles, the greater these effects. The DCT promoted an increase in the intensity of the diffraction peaks corresponding to the phase β'1 and the maintenance of them during the thermomechanical cycling of the material, which indicates that the DCT stabilizes the martensitic phase β'1 and, consequently, caused a reduction and stabilization of the martensitic transformation temperatures and the microhardness, when compared to the untreated material. The longer the soaking time of DCT, the greater these effects.
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深低温处理对Cu-14Al-4Ni智能材料合金马氏体相变温度稳定的影响
DCT(深低温处理)是工业上常用的提高钢的耐磨性的方法。然而,对有色金属的影响研究却很少。本研究的目的是研究DCT对Cu-14Al-4Ni合金在不同浸泡时间和热处理循环下的性能的影响。对真空炉制备的经DCT处理和热机械循环处理的合金的热性能进行了对比实验分析。结果表明:热处理循环促进了马氏体相γ′1的出现和生长,但其韧性不及马氏体相β′1,同时诱导硬化导致相变温度和显微硬度升高;循环次数越多,这些影响就越大。在材料的热循环过程中,DCT促进了β′1相对应的衍射峰强度的增加和维持,这表明DCT稳定了马氏体β′1相,从而使马氏体相变温度和显微硬度与未经处理的材料相比降低和稳定。DCT浸泡时间越长,影响越大。
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