1) microemulsion
微(滴)乳状液
2) emulsion drop
乳状液滴
1.
The effects of treatment time, lift gas flow rate and liquid height in vacuum vessel on inclusion removal in RH degasser were investigated by choosing emulsion drops simulated as inclusions in a water model.
选择乳状液滴作为模拟夹杂物,利用水模型研究了RH装置内夹杂物的物理行为,考察了处理时间、提升气量、真空室内液面高度对夹杂物去除行为的影响规律。
2.
The effects of time and gas flowrate on inclusion removal in a ladle with eccentric bottom gas injected through nozzle and porous plug were investigated by choosing emulsion drops simulated as inclusions in a water model.
通过选择乳状液滴模拟夹杂物和偏心底吹钢包水模型实验,考察了喷嘴和透气砖吹气条件下时间、吹气量对夹杂物去除行为的影响规律。
3) macro emulsion
粗滴乳状液
4) fine emulsion
细(滴)乳状液
5) microemulsion
微乳状液
1.
Investigation of Extraction Process by Titration Calorimetry(Ⅳ)——Formation of Reversed Micelle and Microemulsion in Extraction Organic Phase or Saponated P507;
萃取过程的量热研究(Ⅳ)——皂化P507萃取有机相中反向胶束和微乳状液的形成
2.
Results show that the maximum area of microemulsion region is achieved using tween-60 as surfactant with the km value being of 0.
结果表明,所研究的各体系中,以吐温-60所形成的微乳状液区最大。
3.
The paper simply introduced the classification and property of microemulsion(ME).
介绍了微乳状液的体系类型及性质,阐述了其作为研究热点的应用现状,并预测了微乳状液的前景。
6) microemulsions
微乳状液
1.
The effects of the single surfactant(such as the cationic,anionic and nonionic surfactant respectively),mixed surfactant(e g the anionic and nonionic,cationic and nonionic,anionic and cationic surfactants respectively),cosolvent(containing the alcohol,amine and ether with middle carbon chain)etc on the formation and phase behavior of the water in oil microemulsions were discussed.
讨论了单一表面活性剂( 正、负、非离子表面活性剂) 、混合表面活性剂( 负与非、正与非、正与负离子表面活性剂) 、助溶剂( 中碳醇、胺、醚) 等对油水微乳状液的形成和相行为的影响。
补充资料:无柄液滴法、躺滴法、座滴法等
分子式:
CAS号:
性质:又称无柄液滴法、躺滴法、座滴法等。根据液面外形求算表(界)面张力的一种方法。当待测液液滴稳定地停在水平固体表面上,其外形与液体表面张力γ有关。根据巴什弗思–亚当斯(Bashforth-Adams)方程可有以下关系式ρ1和ρ2分别为待测液体及液滴外介质的密度,g为重力加速度,β为形状因子,b为大小因子。当液体与固体表面接触角大于90°时可根据测出的液滴的赤道半径及其与液滴顶点的垂直距离数值查表得出相应的β及b值,从而算出表面张力γ。本法简便,适用于吸附平衡时间长的体系和低表面张力的测定;也能用于测定界面张力及熔融金属的表(界)面张力。
CAS号:
性质:又称无柄液滴法、躺滴法、座滴法等。根据液面外形求算表(界)面张力的一种方法。当待测液液滴稳定地停在水平固体表面上,其外形与液体表面张力γ有关。根据巴什弗思–亚当斯(Bashforth-Adams)方程可有以下关系式ρ1和ρ2分别为待测液体及液滴外介质的密度,g为重力加速度,β为形状因子,b为大小因子。当液体与固体表面接触角大于90°时可根据测出的液滴的赤道半径及其与液滴顶点的垂直距离数值查表得出相应的β及b值,从而算出表面张力γ。本法简便,适用于吸附平衡时间长的体系和低表面张力的测定;也能用于测定界面张力及熔融金属的表(界)面张力。
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