含不凝气体的蒸汽凝结换热数值研究
Numerical Study of Condensation Heat Transfer of Steam with Non-condensable Gas
- 兵工学报 2023年44卷第7期 页码:2080-2091
- 作者机构:
1. 西北工业大学 航海学院, 陕西 西安 710072
2. 西安电子工程研究所, 陕西 西安 710100
- 作者简介:
*邮箱: kan.qin@nwpu.edu.cn
- 基金信息:国家自然科学基金项目(51805435)
DOI:10.12382/bgxb.2022.0225
中图分类号:收稿:2022-04-02,
网络出版:2023-08-07,
纸质出版:2023-07-30
- 稿件说明:
移动端阅览
郭庆, 罗凯, 耿少航, 等. 含不凝气体的蒸汽凝结换热数值研究[J]. 兵工学报, 2023,44(7):2080-2091.
Qing GUO, Kai LUO, Shaohang GENG, et al. Numerical Study of Condensation Heat Transfer of Steam with Non-condensable Gas[J]. Acta Armamentarii, 2023, 44(7): 2080-2091.
郭庆, 罗凯, 耿少航, 等. 含不凝气体的蒸汽凝结换热数值研究[J]. 兵工学报, 2023,44(7):2080-2091. DOI: 10.12382/bgxb.2022.0225.
Qing GUO, Kai LUO, Shaohang GENG, et al. Numerical Study of Condensation Heat Transfer of Steam with Non-condensable Gas[J]. Acta Armamentarii, 2023, 44(7): 2080-2091. DOI: 10.12382/bgxb.2022.0225.
摘要
为研究水下半闭式循环动力系统中高压换热器的性能
建立适用于高压下含大比例不凝气体的蒸汽凝结过程的数值模型
并考虑重力对水平套管式换热器的燃气流道进行多工况仿真计算与试验验证。研究结果表明:由于重力的存在
管道顶部和底部的液膜厚度不均匀
同时管内气相工质会产生二次旋流
两种作用将导致管内换热的不均匀特性;管径的减小将使管内工质流速增加
增大雷诺数的同时也使底部液膜变薄
有助于增强换热;流速增加削弱了重力的影响
使管道顶部和底部换热强度的差距变小;在所设工况下
即使考虑总换热面积的缩减
减小管径仍有助于总换热功率的提升;试验与仿真的管内温度最大误差为19.5%。所得成果可为水下半闭式循环动力系统高压换热器的设计提供参考。
Abstract
In order to study the performance of a high-pressure heat exchanger in an underwater semi-closed cycle power system
we establish a numerical model to analyze the condensation process of steam containing a significant proportion of non-condensable gas under high pressure. The model is verified through a specific experiment
and we conduct simulations of the gas flow channel in the heat exchanger under different working conditions
taking gravity into consideration. The results show that due to the gravity
the liquid film thicknesses at the top and bottom of the pipe are not uniform
resulting in swirling flow within the gas phase. These two effects lead to uneven heat transfer characteristics in the pipe. Additionally
the flow velocity increases with the decreasing pipe diameter
causing a rise in the Reynolds number and a thinning of the bottom liquid film. This contributes to heat transfer. The increased flow velocity also reduces the effect of gravity
reducing the disparity in heat transfer intensity between the top and bottom sections of the pipe. Under the working conditions in this paper
even with a reduced total heat transfer area
reducing the pipe diameter remains conducive to the improvement of the total heat transfer power. The maximum temperature error between the experimental and simulated results is 19.5%. The conclusions contribute to the design of high-pressure heat exchangers in underwater semi-closed cycle power systems.
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references
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