Study of Strength Characteristics of Steel Specimens after Selective Laser Melting of Powder Materials 17-4PH, 316L, 321

Anton Zhukov, Boris Barakhtin, Pavel Kuznetsov
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引用次数: 15

Abstract

By the method of selective laser melting of powder materials nanostructured stainless steels 17-4PH, 316L, 321 were obtained. In all experiments the recorded hardness increase depending on the construction parameters. Obtained relationship of hardness increase with the carbon ratio, which explained by the chemical composition of the metal in the melting zone. It is suggested that the effect of hardness increase is associated with structural changes as to the formation and dissolution of hardening nanophases. Methods of metallography were performed in structural studies. Traces of interlayer segregation were detected inside the grains as turbulent eddies in the bands of different saturation tone caused by the migration of convective (mass transfer) metal atoms. It was visible signs of crystallization through the grain places the image (dendrite crystals). These facts revealed structural features suggest that the adhesion layers of melted powder was initiated by the colder layers and going mechanism epitaxy by coherently oriented groups of atoms from layers of melting.

粉末材料17-4PH, 316L, 321选择性激光熔化后钢试样强度特性研究
采用粉末材料选择性激光熔融法制备了17-4PH、316L、321纳米结构不锈钢。在所有实验中,记录的硬度随施工参数的增加而增加。得到了硬度增加与碳比的关系,这可以用熔区金属的化学成分来解释。硬度提高的效果与硬化纳米相的形成和溶解的结构变化有关。在结构研究中采用金相方法。在对流(传质)金属原子迁移引起的不同饱和度条带中,发现了层间偏析的痕迹。可见通过颗粒处的结晶迹象(树突晶体)。这些事实揭示的结构特征表明,熔体粉末的粘附层是由较冷的层和熔体层中相干取向的原子群外延形成的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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