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引用次数: 0
摘要
摘要 采用熔滴造粒法和熔体离心法研究了熔滴在水中结晶的物理过程。根据该过程的初始数据、熔滴直径和冷却条件,建立了一个数学模型来确定铝合金颗粒的冷却和结晶速率以及结构树枝状参数。通过预测颗粒微观结构的树枝状参数,可以预测微观结构的分散程度,进而预测颗粒材料的强度特性。模型参数考虑到了落料速度、散热过程的特征以及介质热物理参数的温度依赖性。我们开发了一个应用软件来实现所开发的数学模型。所开发的数学模型使用 Microsoft Visual C++ 编程语言实现。该数学模型针对高合金铝合金(铝-铜-镁体系的 D1 和 D16 合金,以及铝-锌-镁-铜体系的 B95 和 B96Ts 合金)的造粒进行了测试,这些合金是通过离心熔融喷涂法和在水中冷却的滴落法获得的。全尺寸样品的结晶速率是根据材料的树枝状结构参数分析测得的。对树枝状参数的计算值和实际颗粒样品的测量值进行的分析表明,模拟和测量结果趋同性良好。
COOLING AND CRYSTALLIZATION OF MOLTEN ALUMINUM ALLOY DROPS IN WATER
The physical processes of crystallization of melt drops in water were studied using the drop granulation and melt centrifugation methods. A mathematical model was developed to determine the cooling and crystallization rates and structural dendritic parameter for aluminum alloy granules based on the initial data of the process, the diameter of melt drops, and cooling conditions. Predicting the dendritic parameter of the microstructure of granules makes it possible to predict the level of microstructure dispersion and hence the strength properties of the granulate material. The model parameters take into account the drop speed, features of heat removal processes, and the temperature dependence of the thermophysical parameters of the media. An application program implementing the developed mathematical model was developed. The developed mathematical model was implemented using the Microsoft Visual C++ programming language. The mathematical model was tested for the granulation of high-alloyed aluminum alloys (D1 and D16 alloys of the Al–Cu–Mg system, and B95 and B96Ts alloys of the Al–Zn–Mg–Cu system) obtained by centrifugal melt spraying and the drop method with cooling in water. Crystallization rate in full-scale samples was measured based on an analysis of the structural dendritic parameter of the material. Analysis of the calculated values of the dendritic parameter and its measurements for real granule samples shows good convergence of the simulation and measurement results.
期刊介绍:
Journal of Applied Mechanics and Technical Physics is a journal published in collaboration with the Siberian Branch of the Russian Academy of Sciences. The Journal presents papers on fluid mechanics and applied physics. Each issue contains valuable contributions on hypersonic flows; boundary layer theory; turbulence and hydrodynamic stability; free boundary flows; plasma physics; shock waves; explosives and detonation processes; combustion theory; multiphase flows; heat and mass transfer; composite materials and thermal properties of new materials, plasticity, creep, and failure.