1)  bridging
气液堵塞
1.
At hanging downcomer bottom-orifices,there exist three fluid flow states: only liquid flowing downwards through orifices(called "descending");only vapor flowing upwards through orifices(called "bubbling");neither of vapor-liquid phases flowing through orifices(called "bridging").
悬挂式降液管液流孔存在3种气液流动状态:只有液体流过液流孔(称走液态),只有气体流过液流孔(称走气态),气液二相都不流动(称气液堵塞态)。
2)  Gas-liquid
气液
1.
The research on heat transfer from a heater in gas-liquid mist flow;
在气液雾状流中传热分析与实验
2.
They are widely used as gas-liquid contactors and reactors in chemical, petrochemical and biochemical industries.
学术界和工业应用研究领域对鼓泡塔和气升式反应器的关注日益增加,在化学、石化和生化工业中广泛用作气液接触器和反应器,与其他多相反应器相比有其独特的优点:无机械传动部件因而易于维护,界面积大,气液传输速率高,传热特性好。
3)  gas-liquid interface
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。
4)  gas-liquid separation
气液分离
1.
In view of the complexity of the process of emptying petroleum pipeline with compressed air,this paper proposed a new method for gas-liquid separation,which adopted multiple separating techniques.
针对长输管线气顶排空作业的复杂性,结合多种分离技术的特点,提出了一种气液分离方法,并给出了基于该方法的分离器结构和分离原理。
2.
There are lots of occasions which need for gas-liquid separation,but the separation technologies and equipments have considerable limitations.
需要进行气液分离的场合众多,各分离技术设备又具有相当的局限性,本文介绍了国内外气液分离技术及设备的进展及其应用情况,详细分析了气液的重力沉降分离、惯性分离、过滤分离和离心分离的分离原理和设备。
5)  gas-liquid reaction
气液反应
1.
Kinetics of gas-liquid reaction between NO and Co(en)_3~(3+);
NO与乙二胺合钴离子气液反应动力学研究
6)  gas-liquid ratio
气液比
1.
The gas-liquid ratio is 1.
7×104m3,累计气液比1。
2.
During drilling process,relevant parameters were: gas-liquid ratio 180-240,foam liquid concentration 4-8%.
在钻进过程中,调整参数为:气液比180~240,泡沫液浓度4%~8%。
3.
The influence of temperature, gas-liquid ratio, gas-liquid rate, residual oil saturation and permeability on steam foam sealing ability is studied on the basis of microscopic percolation study.
在蒸汽泡沫微观渗流研究的基础上 ,研究了温度、气液比、气液速率、残余油饱和度以及渗透率对蒸汽泡沫封堵能力的影响。
参考词条
补充资料:浓氯化钠注射液 ,高渗氯化钠注射液,高张氯化钠注射液
药物名称:浓氯化钠注射液

英文名:Injection 10% Sodium Chloride

别名:浓氯化钠注射液 ,高渗氯化钠注射液,高张氯化钠注射液
外文名: Injection 10% Sodium Chloride, Hypertonic saline
适应症: 用于脱水症及调节体内水与电解质的平衡。
用量用法: 静脉滴注,临用前稀释,用量与浓度视病情需要而定。
注意事项: 心、肾功能不全者慎用。
规格: 注射剂:1g/10ml,本品为氯化钠的高渗灭菌水溶液。



类别:调节水、电解质及酸碱平衡药
说明:补充资料仅用于学习参考,请勿用于其它任何用途。