1) gas-liquid interfacial effects
![点击朗读](/dictall/images/read.gif)
气液界面效应
2) interfacial interaction
![点击朗读](/dictall/images/read.gif)
液固界面效应
1.
Dropwise condensation heat transfer performance depends on not only the condensing conditions, but also the interfacial interaction between liquid and solid.
针对液固界面相互作用对滴状冷凝传热的影响,以Rose滴状冷凝传热模型为基础,考虑接触角、脱落直径对冷凝传热的影响,对滴状冷凝过程中液滴空间序列上的构象,作时间序列上的重构,建立了包含液固界面效应的滴状冷凝传热模型。
3) solid-liquid-interfacial-energy-difference(SLIED) effect
![点击朗读](/dictall/images/read.gif)
固液界面效应
1.
This paper reviewes the advances in the investigation of the solid-liquid-interfacial-energy-difference(SLIED) effect on the heat transfer processes of filmwise, transition(filmwise and dropwise co-existing) and dropwise condensation modes for pure vapor and mixture vapor in the presence of non-condensable gas.
介绍了利用固液界面效应强化纯蒸气和含不凝性气体的混合蒸气冷凝传热的强化技术。
4) gas-liquid interface reaction
![点击朗读](/dictall/images/read.gif)
气-液界面反应<冶>
5) effect of gas-water interface
![点击朗读](/dictall/images/read.gif)
气-水界面效应
6) gas-liquid interface
![点击朗读](/dictall/images/read.gif)
气液界面
1.
On the basis of introducing the structure,performance index and test principle of the RMT,this paper describes its favorable application effects in dividing the gas-liquid interface through which fluid in- terface in the subsurface reservoir can be monitored and evaluated regularly thus to determine the.
而本文在介绍仪器结构、性能指标与测试原理的基础上,通过对实际测井资料进行综合分析,阐述了RMT在划分气液界面具有很好的应用效果,能够实现地下储层流体界面的定期监测与评价,从而确定射孔的有效性。
2.
The behaviors of gas-liquid interface associate with two-phase annular flow regime in horizontal micro tubes are investigated with linear stability analysis.
本文以水平微圆管内气液两相环状流气液界面为研究对象,通过分析重力、表面张力和界面剪切力对环状流液膜厚度的影响,重点考虑Rayleigh不稳定性对气液界面的依存关系,得到了不同管径和气核直径变化时不稳定性的变化规律,并分析拟合了最危险波长和气核直径的关联式,为后续建立高热流密度条件下微通道内强化传热理论模型奠定基础。
3.
The composition and optical characte ri stics of a self-made,real-time and microscopic dual wavelength holographic in terferometer for visualizing the concentration profiles on gas-liquid interface were reported in this paper.
利用该系统测量了甲醇 -乙醇 - CO2 等三元物系气液界面处液相侧的浓度场 ,得到了清晰的两个实时全息干涉条纹图 ,清楚地观察到了气液两相界面存在的湍动现象 ,从而验证了该系统的可靠性。
补充资料:液气界面
液气界面
液体与气体的接触分界处。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条