不同水冷结构的超大型梁坯连铸模具的传热行为

Shi-bo Wang, Zhao-zhen Cai, Miao-yong Zhu
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摘要

优良的水冷结构有助于实现模具内高效、合理的热传递,这对实现超大型型钢毛坯连铸(ULBBCC)至关重要。因此,本研究设计了由三块不同水冷结构的宽面铜板和两块不同水冷结构的窄面铜板组成的不同超大型梁坯模具(ULBBM),在此基础上,考虑流固耦合相互作用,建立了水冷结构中铜板与冷却水流耦合的三维传热模型。然后,通过比较模型预测水温和实测水温,验证了模型的准确性。最后,重点比较了不同水冷结构下模具的传热行为以及冷却水的温度和流动演变,并提出了最优的水冷结构。结果表明,带有半圆形根部的水槽水冷结构(模具 II)有助于 ULBBM 的窄面铜板获得极佳的温度均匀性,并实现热传递的均匀化。直径为 10 毫米的小孔水槽水冷结构(模具 III)使超薄板宽面铜板圆角处的最高温度降至 582.9 K,半月板附近的最大圆周温差降至 103.3 K,有助于宽面铜板获得更高的温度均匀性和更低的圆角温度,实现传热均匀化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

The Heat Transfer Behavior of Ultra-Large Beam Blank Continuous Casting Mold with Different Water-Cooling Structure

The Heat Transfer Behavior of Ultra-Large Beam Blank Continuous Casting Mold with Different Water-Cooling Structure

The excellent water-cooling structure contributes to achieve efficient and reasonable heat transfer in the mold, which is essential for achieving the ultra-large beam blank continuous casting (ULBBCC). Therefore, this work designed different ultra-large beam blank mold (ULBBM) which were composed of three wide face copper plates with different water-cooling structures and two narrow face copper plates with different water-cooling structures, on the basis of which a three-dimensional heat transfer model of the copper plate coupling with the cooling water flow in the water-cooling structure was developed with the consideration of fluid-solid coupling interaction. Then, the accuracy of the model was verified by comparing the model-predicted and measured water temperatures. Finally, the focus is comparing the heat transfer behavior of the mold under different water-cooling structures, as well as the temperature and flow evolution of the cooling water, and the most optimal water-cooling structure was proposed. The results show that the water-cooling structure of water slots with semicircular roots (Mold II) contributes the narrow face copper plate of ULBBM to obtain excellent temperature uniformity and achieve homogenization of heat transfer. The water-cooling structure of small hole water channel with a diameter of 10 mm (Mold III) decreases the maximum temperature at the fillet of wide face copper plate of ULBBM to 582.9 K and the maximum circumferential temperature difference near the meniscus to 103.3 K, and which contributes the wide face copper plate to obtain higher temperature uniformity and lower fillet temperature, and achieve homogenization of heat transfer.

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