ANALYSIS OF THE FORM AND EVOLUTION OF THE SOLID PHASE DURING DIRECTIONAL CRYSTALLIZATION OF NON-FERROUS METALS WITH ELECTROMAGNETIC INFLUENCE BY ULTRASONIC AND TEMPERATURE METHODS

Q3 Materials Science

PNRPU Mechanics Bulletin Pub Date : 2022-12-15 DOI:10.15593/perm.mech/2022.4.15

G. Losev, A. Mamykin

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Abstract

The paper is devoted to the experimental study of new mechanisms of controlling the process of directional crystallization of non-ferrous metals. The focus of the study is on the development and testing of measuring techniques applicable both to laboratory modeling and to processes under real operating conditions. The mechanism of controlling the rate and homogeneity of crystallization of a metal melt by changing the phase angles between the supply currents of a traveling magnetic field induction stirrer is proposed. This makes it possible to generate vortex flows of various topologies in the liquid metal, in particular, to change the number of large-scale vortices or to suppress the large-scale flow. It is shown that the hydrodynamic flows have an impact on the crystallization front shape, which allows one to control the homogeneity of metal solidification by changing the characteristics of the power supply of the inductor. It is important to note that a change in the phase angles of the currents while maintaining the supply amplitude does not significantly affect the crystallization rate, which opens up wide possibilities for controlling processes by changing both the current strength and the phase angles. The temperature method for determining the position of the crystallization front was successfully applied and verified by ultrasonic velocimetry measurements. It has been found that, in the presence of developed flows in a liquid medium, thermocouple measurements provide good agreement (up to a few percent) of the measured position and geometric shape of the crystallization front with the ultrasonic measurement data. In the absence of liquid phase stirring, the difference between the thermocouple and ultrasonic measurements increases slightly. Nevertheless, even in this case, the thermocouple method can be used to correctly determine the position and velocity of the crystallization front.

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用超声波和温度法分析电磁影响下有色金属定向结晶固相的形成和演化

本文对控制有色金属定向结晶过程的新机制进行了实验研究。研究的重点是开发和测试适用于实验室建模和实际操作条件下的过程的测量技术。提出了通过改变行磁场感应搅拌器供电电流之间的相位角来控制金属熔体结晶速率和均匀性的机理。这使得在液态金属中产生各种拓扑结构的涡旋流动成为可能，特别是改变大尺度涡旋的数量或抑制大尺度流动。结果表明，流体动力流动对结晶前沿形状有影响，可以通过改变电感电源的特性来控制金属凝固的均匀性。值得注意的是，在保持电源振幅的同时，电流相位角的变化不会显著影响结晶速率，这为通过改变电流强度和相位角来控制过程开辟了广泛的可能性。成功地应用了温度法确定结晶锋位置，并通过超声测速验证了该方法的有效性。已经发现，在液体介质中存在发达流动的情况下，热电偶测量提供了与超声测量数据很好的一致(高达百分之几)的测量位置和结晶锋的几何形状。在没有液相搅拌的情况下，热电偶和超声波测量之间的差异略有增加。然而，即使在这种情况下，热电偶方法也可以用来正确地确定结晶锋的位置和速度。

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

PNRPU Mechanics Bulletin Materials Science-Materials Science (miscellaneous)

CiteScore

1.10

自引率

0.00%

发文量