液滴的蒸发

R. Kayser, H. Bennett
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引用次数: 4

摘要

对液滴预热阶段的两种理想模型进行了理论分析。这些模型包含了瞬态热传导和蒸发的影响。假设液滴表面积随时间线性减小。这个假设需要解决移动边界问题。然而,这些模型不考虑气相质量输运。在有限梯度模型中,液滴和周围热气体的温度在空间和时间上都是变化的。在零梯度模型中,气体温度随时间和空间变化,而液滴温度仅随时间变化,即液滴温度在空间上是均匀的。给出了液滴潜热和蒸发速率常数的典型值的数值算例,这些算例需要大量的合流超几何函数计算。有限梯度模型和零梯度模型给出的温度分布在所有被检验的情况下,误差都在20%以内。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evaporation of a Liquid Droplet
Two idealized models for the preheat stage of liquid droplets are analyzed theoretically. These models contain the effects of transient heat conduction and evaporation. It is assumed that the droplet surface area decreases linearly with time. This assumption necessitates the solution of moving boundary problems. These models, however, do not consider gas-phase mass transport. In the finite-gradient model, the temperatures of both the droplet and surrounding hot gases vary spatially and temporally. In the zero-gradient model the gas temperature varies spatially and temporally but the droplet temperature varies only temporally, i.e., the droplet temperature is spatially uniform. Numerical examples, which require extensive calculations of confluent hypergeometric functions, are presented for typical values of the droplet latent heat and evaporation rate constant. The temperature profiles given by the finite-gradient and zero-gradient models agree to within 20 percent of each other for all cases examined.
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