Thermal simulation of a continuous casting process subjected to water-sprays cooling

IF 0.8 Q4 THERMODYNAMICS

Archives of Thermodynamics Pub Date : 2023-07-20 DOI:10.24425/ather.2020.133628

H. Mzad

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引用次数: 0

Abstract

As in many thermal processing technologies, there is a delicate balance between productivity and quality during ingot cooling process. Higher cooling velocities increase productivity but also create higher temperature gradients inside the ingot. Such a fast cooling does not leave sufficient time to establish the equilibrium within the solid, thus the final metal structure is strongly affected by the set up cooling mode throughout the liquid metal solidification. The first intention in this paper is to compare between three cooling modes in order to identify the required mode for a continuous casting process. Then, we study the influence of heat transfer coefficient on metal liquid-to-solid transition through the spray-cooled zone temperature and the metal latent heat of solidification. A gray iron continuous casting process subjected to water-sprays cooling was simulated using the commercial software for modeling and simulating multiphysics and engineering problems. The primary conclusions, from the obtained results, show the forcefulness of water spray cooling regarding standard cooling. Afterward, we highlight the great influence of heat transfer coefficient on the location of transition region as well as the relationship between heat transfer coefficient, wall outer temperature, latent heat dissipation, and the solidification time.

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水雾冷却下连铸过程的热模拟

与许多热加工技术一样，钢锭冷却过程中生产率和质量之间存在着微妙的平衡。更高的冷却速度可以提高生产率，但也会在铸锭内部产生更高的温度梯度。这种快速冷却没有留下足够的时间来建立固体内部的平衡，因此在整个液态金属凝固过程中，最终的金属结构受到所设置的冷却模式的强烈影响。本文的第一个目的是比较三种冷却模式，以便确定连续铸造过程所需的模式。然后，通过喷冷区温度和金属凝固潜热研究了传热系数对金属液固转变的影响。利用商业多物理场建模和工程问题模拟软件，对灰铸铁水雾冷却连铸过程进行了数值模拟。从所得结果中得出初步结论，说明了水雾冷却相对于标准冷却的有效性。然后，我们强调了传热系数对过渡区位置的重要影响，以及传热系数与壁外温度、潜热散热量和凝固时间之间的关系。

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

Archives of Thermodynamics THERMODYNAMICS-

CiteScore

1.80

自引率

22.20%

发文量

期刊介绍： The aim of the Archives of Thermodynamics is to disseminate knowledge between scientists and engineers interested in thermodynamics and heat transfer and to provide a forum for original research conducted in Central and Eastern Europe, as well as all over the world. The journal encompass all aspect of the field, ranging from classical thermodynamics, through conduction heat transfer to thermodynamic aspects of multiphase flow. Both theoretical and applied contributions are welcome. Only original papers written in English are consider for publication.