Numerical Investigation of the Impact of Subcooling Inlet on Water Flow Boiling Heat Transfer Through a Microchannel

A. Al-Waaly
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Abstract

The effect of subcooling inlet has a big effect of the flow patterns for the flow boiling through a microchannel. Higher subcooling lower mass flux will delay the nucleate boiling and vice versa. The water flow boiling inside a microchannel has been analyzed numerically. The microchannel depth was 0.24 mm while the length was 40 mm. The supplied heat fluxes were 500 kW·m-2, 1000 kW·m-2and 1500 kW·m-2 with mass velocities of 400 kg·m-2·s-1 and 800 kg·m-2·s-1. The degrees of subcoooling of inlet water were 5oC, 10oC, 15oC, 20oC, and 25oC. The results showed that the degree subcooling has a considerable impact on both the wall temperature and flow patterns. The rise in the degree of subcooling kept the nucleate flow boiling and retarded the development of convective boiling. In addition, there was a reflection point at which the impact of heat flux on the average of the convective coefficient of heat transfer was altered. The increase in the heat flux may lead to an increase or reduction in the average HTC with respect to the location of the reflection point. The reflection points were 7oC and 5oC for the mass velocities 400 kg·m-2·s-1 and 800 kg·m-2·s-1. Thus, both the degree of subcooling and the heat flux should be simultaneously considered when it comes to the enhancement of HTC during the flow boiling inside the microchannels.
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过冷入口对微小通道水流沸腾传热影响的数值研究
入口过冷度对通过微通道的沸腾流的流动模式有很大影响。过冷度越高,质量通量越低,成核沸腾越晚,反之亦然。我们对微通道内的水流沸腾进行了数值分析。微通道深度为 0.24 毫米,长度为 40 毫米。提供的热通量分别为 500 kW-m-2、1000 kW-m-2 和 1500 kW-m-2,质量速度分别为 400 kg-m-2-s-1 和 800 kg-m-2-s-1。进水过冷度分别为 5oC、10oC、15oC、20oC 和 25oC。结果表明,过冷度对壁面温度和流动模式都有相当大的影响。过冷度的升高保持了核流动沸腾,延缓了对流沸腾的发展。此外,热通量对对流传热系数平均值的影响在一个反射点上发生了变化。热通量的增加可能会导致相对于反射点位置的 HTC 平均值的增加或减少。在质量速度为 400 kg-m-2-s-1 和 800 kg-m-2-s-1 时,反射点分别为 7oC 和 5oC。因此,在微通道内流动沸腾过程中提高 HTC 时,应同时考虑过冷度和热通量。
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