INFLUENCE OF CONSTANT MAGNETIC FIELD ON STRUCTURE FORMATION IN STEELS AT HIGH-SPEED LASER PROCESSING

Q3 Materials Science
A. Brover, G. Brover
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引用次数: 2

Abstract

Experimental studies of laser-irradiated layers in a magnetic field (MF) have shown a non-trivial morphology of the surface of handling zone of material in case of reflow. Twisting of a thin layer of liquid metal is observed, irradiated area is getting a crescent appearance, definitely strictly oriented in relation to magnetic flux. This is probably due to the effect of Righi-Leduc, as well as the action of Lorentz forces, which deflect the electrons flow. As a result, there is significant mixing of metal in the irradiation zone, chemical composition equalization, which positively affects the strength properties of the products. One of the important consequences of the MF-effect on the results of laser processing is the phenomenon of magnetostriction. In laser irradiation without MF slide lines were observed on the pre-polished surface patterns resulting from the emerging thermal and structural stresses. By analyzing the topography of irradiated surfaces using modern analysis techniques and computer image processing, it was established that irradiation in MF in conditions of magnetostriction decreases the stress level in irradiated areas and reduces the risk of cracking. The results of temperature measurements at the irradiated spot on cooling stage allow establishing that the cooling rate during laser processing in a MF is considerably higher than without the field. It affects the processes of phase and structural transformations. At laser heating in MF microheterogenic austenite is supercooled with great speed to temperatures of martensite transformation. After that its transformation begins, the sequence of which is determined by the level of local saturation, degree of deformation and is controlled by temperature. The first crystals of martensite are formed in the least saturated areas of austenite, and a very high speed (thousands or tens of thousands of °С/s) of the transformation process beginning γ → α prevents martensite self tempering, which partially can occur when the temperature decreases further due to transformation spread on the remaining volume of austenite, grabbing areas of different saturation. As a result, along with the “fresh-formed” martensite in the areas of laser quenching the martensite is formed, in which segregation of carbon or even ε-carbide may occur and residual austenite with high carbon intensity are formed. Released dispersed carbides contribute to obtaining a sufficiently high hardness values of metals irradiated in a MF.
恒磁场对高速激光加工钢组织形成的影响
对磁场中激光辐照层的实验研究表明,在回流的情况下,材料处理区表面具有非平凡的形貌。观察到一薄层液态金属的扭曲,受辐照的区域呈现新月形外观,与磁通量的关系绝对严格定向。这可能是由于Righi-Leduc的影响,以及洛伦兹力的作用,使电子流偏转。因此,在辐照区有明显的金属混合,化学成分均衡,这对产品的强度性能有积极的影响。磁致伸缩现象是磁致伸缩效应对激光加工结果的重要影响之一。在无中频激光照射下,由于热应力和结构应力的出现,在预抛光表面上观察到滑动线。利用现代分析技术和计算机图像处理技术对辐照表面形貌进行了分析,确定了磁致伸缩条件下的中频辐照降低了辐照区域的应力水平,降低了开裂的风险。在冷却阶段辐照点的温度测量结果允许建立在中频激光加工过程中的冷却速率比没有场的要高得多。它影响相和结构转变的过程。在中频激光加热下,微异质奥氏体以极快的速度过冷到马氏体转变温度。之后开始变形,变形顺序由局部饱和程度、变形程度决定,并受温度控制。马氏体的第一个结晶是在奥氏体最不饱和的区域形成的,从γ→α开始的非常高的转变速度(数千或数万°С/s)阻止了马氏体的自回火,当温度进一步降低时,由于转变扩散到奥氏体的剩余体积上,抢占了不同饱和度的区域,部分地发生了自回火。结果表明,在激光淬火区域,伴随“新形成”的马氏体形成的是马氏体,马氏体中可能出现碳甚至ε-碳化物的偏析,形成高碳强度的残余奥氏体。释放的分散碳化物有助于获得足够高的金属在磁场辐照硬度值。
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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来源期刊
Izvestiya Vysshikh Uchebnykh Zavedenij. Chernaya Metallurgiya
Izvestiya Vysshikh Uchebnykh Zavedenij. Chernaya Metallurgiya Materials Science-Materials Science (miscellaneous)
CiteScore
0.90
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0.00%
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81
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