Suppression of surface hot shortness due to Cu in recycled steels : Environmental benign manufacturing and material processing toward dematerialization

K. Shibata, Soek-Jong Seo, Masashi Kaga, H. Uchino, Akio Sasanuma, K. Asakura, C. Nagasaki
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引用次数: 44

Abstract

The most serious problem in the recycling of steel is the occurrence of surface hot shortness during hot deformation due to the mixing of Cu from scrap into steels. Tin accelerates the effect of Cu. The surface hot shortness is caused by liquid embrittlement, that is, formation of the liquid Cu-enriched phase through preferential oxidation of Fe atoms at the steel/scale interface during heating for hot deformation and penetration of this Cu-enriched phase into the grain boundaries. Decrease in the amount of the liquid Cu-enriched phase penetrating into grain boundaries can suppress the surface hot shortness. The amount of the liquid Cu-enriched phase penetrating into the grain boundaries can be reduced by the suppression of oxidation, occlusion of the Cu-enriched phase into the scale, back-diffusion of Cu into the steel matrix and suppression of penetration of the liquid Cu-enriched phase. Therefore, the effects of various elements and conditions of heating and deformation on the surface hot shortness, oxidation, amount of the Cu-enriched phase at the interface and the penetration were examined by tensile tests at high temperatures, thermogravimetry and optical microscopy. The conclusion can be summarized as follows. Silicon, Mn, S (+Mn) and B reduce the susceptibility to the surface hot shortness through decreasing the amount of Cu-enriched phase at the steel/scale interface. The effect of Si is significant. Carbon reduces the oxidation rate in LNG combustion gas. Phosphorus, Si, B and C reduce the susceptibility to the surface hot shortness through restraining the penetration of the Cu-enriched phase into grain boundaries. Heating at higher temperatures reduces the susceptibility mainly through a reduction in the amount of the Cu-enriched phase at the steel/scale interface, although the loss of steels by oxidation increases. A large grain size accelerates the surface hot shortness. A small amount of H 2 O in air significantly accelerates the surface hot shortness. Effects of H 2 O in heating atmosphere depend on the steel composition and more detailed research on this is desired. Very slow deformation does not cause liquid embrittlement through dynamical re-crystallization, while at a fast deformation rate the embrittlement is suppressed by an increase in the critical stress for the liquid embrittlement. Multiple methods using physical metallurgy suggested by the present research for suppressing the surface hot shortness should be applied together with other methods through separation, smelting and design of fabrication in order to promote the recycling of steels.
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抑制再生钢中Cu引起的表面热短性:环保制造和非物质化的材料加工
钢的回收利用中最严重的问题是由于废钢中的铜混入钢中,在热变形过程中产生表面热短。锡加速了铜的作用。表面热短是由液体脆化引起的,即在加热热变形过程中,钢/垢界面处的铁原子优先氧化形成液态富cu相,富cu相渗入晶界。减少富cu液相渗进晶界的量可以抑制表面热短度。通过抑制氧化作用、富Cu相在水垢中的遮挡作用、Cu向钢基体中的反扩散作用和抑制富Cu液相的渗透作用,可以减少富Cu液相渗入晶界的量。因此,通过高温拉伸试验、热重法和光学显微镜研究了不同元素和加热变形条件对表面热短度、氧化、界面富cu相数量和渗透的影响。结论可以概括如下。硅、Mn、S (+Mn)和B通过减少钢/垢界面富集cu相的数量来降低对表面热短的敏感性。Si的影响是显著的。碳降低了LNG燃烧气体中的氧化速率。磷、Si、B和C通过抑制富cu相向晶界的渗透来降低对表面热短的敏感性。在较高温度下加热主要通过减少钢/垢界面上富cu相的数量来降低磁化率,尽管氧化导致钢的损失增加。大晶粒尺寸加速了表面热短。空气中少量的h2o显著加速了表面热短。加热气氛中h2o的影响取决于钢的成分,需要对此进行更详细的研究。非常缓慢的变形不会通过动态再结晶引起液体脆化,而在快速变形速率下,液体脆化的临界应力的增加抑制了脆化。本研究提出的多种抑制表面热短的物理冶金方法,应通过分离、冶炼和工艺设计,与其他方法共同应用,以促进钢材的循环利用。
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