Joerg Volpp , Yuji Sato , Masahiro Tsukamoto , Lewin Rathmann , Marius Möller , Samuel J. Clark , Kamel Fezzaa , Tim Radel , Kevin Klingbeil
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引用次数: 0
摘要
金属和金属合金在高温下的材料特性往往是未知的,但对于了解预测和改进激光束技术等高温工艺的物理机制来说却是必要的。表面张力是一项基本性质,本研究利用激光在钢基体中诱导蒸汽通道,并通过现场 X 射线观测提取蒸汽通道直径,测量了钢在沸腾温度以上的表面张力。测量原理基于钥匙孔内的压力平衡,即钥匙孔壁汽化产生的反冲压力与周围熔池产生的表面张力压力相抵消。测量结果表明,在沸点以上温度升高时,表面张力会增加,这与理论预期不符。为了形成所测得的钥匙孔形状,表面张力必须增加,以抵消不断增加的反冲压力。
Material properties of metals and metal alloys at high temperatures are often unknown, but necessary to understand physical mechanisms for prediction and improvement of high temperature processes, such as laser beam technologies. Surface tension is an elementary property that was measured in this study above the boiling temperature of steel using a laser-induced vapor channel in a steel substrate and the extraction of the vapor channel diameter from in-situ X-ray observations. The measurement principle is based on the pressure balance inside the keyhole, where the recoil pressure from keyhole wall vaporization works against the surface tension pressure from the surrounding melt pool. An increase in surface tension at increasing temperatures above the boiling point was measured against theoretical expectations. In order to create the keyhole shapes measured, the surface tension must increase to counterbalance the increasing recoil pressure.
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