Grain boundary character and superplasticity of fine-grained ultra-high carbon steel : Superplasticity and its applications

T. Furuhara, E. Sato, T. Mizoguchi, Shuji Furimoto, T. Maki
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引用次数: 12

Abstract

The characteristics and superplasticity of the (a + θ) microduplex structures formed by various thermomechanical processings were studied in an ultra-high carbon steel (Fe-1.4Cr-1.0C). After heavy warm rolling of pearlite, an (a + θ) microduplex structure with equi-axed a grains of 0.4 pm in diameter and spheroidized θ particles of 0.2 μm in diameter is obtained. The a matrix exhibits a recovered structure in which most of a grain boundaries are low-angle boundaries, resulting in rather smaller elongation at 973 K. Heavy cold rolling and annealing of pearlite produces an (a + θ) microduplex structure which consists of the coarse-grain region (d α ∼ 0.4 μm) with high-angle a boundaries and the fine-grain region (d α ∼ 0.2 μm) with low-angle a boundaries. Superplasticity in this specimen is slightly better than the warm-rolled specimen. When pearlite was austenitized in the (y + θ) region, quenched and tempered at the temperature below A 1 , an (a + θ) microduplex structure in which a and θ grain sizes are nearly the same as in the warm-rolled specimen and most of a boundaries are of high-angle one is formed. Such ultra-fine a grains are formed through the recovery of the fine (a' lath martensite + θ) mixture during tempering. This microduplex structure exhibits superior superplasticity. Heavy warm rolling prior to the quenching and tempering improves total elongation further because the distribution of prior y grain size is more uniform. When cold-rolled pearlite was austenitized and air-cooled, an (a + θ) microduplex structure with high-angle a boundary is formed. However, since the a grain size was relatively large (ca. 2 μm), its superplastic performance is poor. Finally, more simplification of processing for superplasticity was attempted. Further improvement of superplasticity was achieved by omitting the tempering in the quenching and tempering treatment.
细晶超高碳钢的晶界特性与超塑性:超塑性及其应用
研究了超高碳钢(Fe-1.4Cr-1.0C)在不同热处理条件下形成的(a + θ)微双相组织的特征和超塑性。珠光体经过重温轧制后,得到了直径为0.4 pm的等轴a晶粒和直径为0.2 μm的球化θ晶粒的(a + θ)微双相组织。在973 K时,a基体表现出一种恢复组织,其中大部分晶界为低角晶界,导致延伸率较小。珠光体经冷轧退火后形成(a + θ)微双相组织,由具有高a角边界的粗晶区(d α ~ 0.4 μm)和具有低a角边界的细晶区(d α ~ 0.2 μm)组成。该试样的超塑性略好于热轧试样。当珠光体在(y + θ)区奥氏体化,在低于a1的温度下淬火回火时,形成了A和θ晶粒尺寸与热轧试样基本相同,且晶界大部分为大角度晶界的(A + θ)微双相组织。这种超细晶粒是通过回火过程中细小(a'板条马氏体+ θ)混合物的恢复而形成的。这种微双相组织表现出优异的超塑性。淬火回火前的重温轧制进一步提高了总伸长率,因为先前的晶粒尺寸分布更加均匀。冷轧珠光体经奥氏体化和风冷处理后,形成具有大角度a边界的(a + θ)微双相组织。但由于a晶粒尺寸较大(约2 μm),其超塑性性能较差。最后,对超塑性加工进行了进一步简化。通过在淬火回火处理中省略回火,进一步提高了材料的超塑性。
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