竖直管道内强迫循环下非凝性气体对蒸汽冷凝的影响

doi:10.16511/j.cnki.qhdxxb.2017.22.033

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摘要非凝性气体对蒸汽冷凝具有重要影响作用，能够大大增加蒸汽冷凝过程的传热热阻，减小传热系数。为研究非凝性气体对竖直管道内蒸汽冷凝的影响，基于Nusselt理论建立了强迫循环条件下蒸汽冷凝的传热传质类比模型。将模型的计算结果与实验数据进行了对比，结果表明：模型能够准确地预测竖直管道内蒸汽冷凝传热系数。模型中非凝性气体为空气，空气的入口质量分数对蒸汽冷凝传热系数具有较大影响。当入口空气的质量分数从8.73%到 22.45% 变化时，入口处冷凝传热系数从4.8 kW/（m²·K）到1.2 kW/（m²·K）变化，且沿着管道轴向冷凝传热系数逐渐减小。当入口温度从100 ℃到140 ℃变化时，传热系数逐渐减小。该研究表明非凝性气体的种类、质量分数和入口温度为影响蒸汽冷凝传热的重要因素。

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	马喜振
	贾海军
	刘洋

关键词 ：非凝性气体, 冷凝, 传热传质, 强迫循环

Abstract：Non-condensable gases have an important influence on steam condensation by increasing the thermal resistance during condensation and decreasing the heat transfer coefficient. A heat and mass analogy model based on the Nusselt's theory is developed for steam condensation in a vertical pipe with forced convection. The predicted effects of the non-condensable gases on the condensation are with agreement with experimental data. The heat transfer coefficient in the inlet varies from 4.8 kW/(m²·K) to 1.2 kW/(m²·K) for inlet air mass fractions from 8.73% to 22.45%. The heat transfer coefficient then decreases along the pipe. Increasing the inlet temperature from 100 ℃ to 140 ℃ reduces the inlet heat transfer coefficient. The research shows that the inlet temperature and the kind and the mass fraction of non-condensable gas are the important factors governing steam condensation rate.

Key words： non-condensable gas condensation heat and mass transfer forced convection

收稿日期: 2016-08-05 出版日期: 2017-05-15

ZTFLH:

TK124

通讯作者: 贾海军,研究员,E-mail:jiaha@tsinghua.edu.cn E-mail: jiaha@tsinghua.edu.cn

引用本文:

马喜振, 贾海军, 刘洋. 竖直管道内强迫循环下非凝性气体对蒸汽冷凝的影响[J]. 清华大学学报（自然科学版）, 2017, 57(5): 530-536.
MA Xizhen, JIA Haijun, LIU Yang. Effect of non-condensable gases on steam condensation in a vertical pipe with forced convection. Journal of Tsinghua University(Science and Technology), 2017, 57(5): 530-536.

链接本文:

http://jst.tsinghuajournals.com/CN/10.16511/j.cnki.qhdxxb.2017.22.033 或 http://jst.tsinghuajournals.com/CN/Y2017/V57/I5/530

图1 液膜冷凝模型

表1 实验参数^[11]

图2 不同空气质量分数和入口温度下的沿管道轴向的传热系数

图3 各个模型下的沿管道轴向的传热系数

图4 入口温度为100℃时非凝性气体分别为空气、氦气和氩气时的冷凝传热系数

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