尿素造粒塔建模中的两相Stefan问题

The 2nd International Electronic Conference on Processes: Process Engineering&mdash;Current State and Future Trends Pub Date : 2023-06-07 DOI:10.3390/ecp2023-14745

Kim Thanh Vy Ha, Tuan-Anh Nguyen, Quoc-Lan Nguyen, V. Dang, Van-Han Dang, Hoang-Luan Van, Le-Na T. Pham

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引用次数: 0

摘要

．造粒技术常用于生产颗粒尿素和硝酸铵。产生的液滴下落并变成固体，因为冷却空气以逆流的方向流动，带走了热量。一般考虑尿素液滴凝固的三个顺序热间隔:液滴冷却、液相冻结温度下凝固、完整固体颗粒冷却。在本研究中，尿素液滴的凝固被视为具有对流通量边界条件的两相Stefan问题，而不是将整个过程划分为三个连续步骤。用焓法对传热问题进行了数值求解。假设粒子立即达到终端速度。对流换热由终端速度确定。研究了液滴在不同粒径下的温度分布和完全凝固的最小高度。

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Two-Phase Stefan Problem for the Modeling of Urea Prilling Tower

. The prilling technique is frequently used to make granular urea and ammonium nitrate. The generated droplets fall and become solid due to the heat removal by the cooling air, which flows in a counter-current direction. Generally, three sequential thermal intervals for the solidification of urea droplets are considered: cooling of liquid drops, solidification at freezing temperature of the liquid phase, and cooling of complete solid particles. In this study, the solidification of the urea droplets has been considered as a two-phase Stefan problem with convective flux boundary condition rather than dividing the whole process into three sequential steps. The heat transfer problem was solved numerically using the enthalpy method. The particles were assumed to attain the terminal velocity immediately. The convective heat transfer was determined from the terminal velocity. The temperature distribution of the droplets, and the minimum height for complete solidification at different particle diameters were investigated.

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The 2nd International Electronic Conference on Processes: Process Engineering&mdash;Current State and Future Trends

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