微液滴的非机械驱动是操纵微小尺寸液体流动的新方法。
Using non mechanical means to pump and position liquid micro drops is a novel way to control fluids in sub millimeter scale.
在干湿交替作用下,微液滴的扩展与腐蚀电流之间相互影响、相互促进。
Under cyclic wet-dry conditions, it showed a closed relation between the spreading of micro-droplets and corrosion current. They were influenced and promoted with each other.
微液滴冲击冷却系统的实验平台的设计:确定实验平台结构及控制系统的设计方案;
The experiment plat design of micro droplet impingement cooling system: Confirm the design scheme of the experiment plat frame and the control system;
同时,因为它们是小液滴和冰晶形成需要的凝结核,因此尘埃微粒还能在云微物理学层面给云层带来改变。
Aerosols also affect cloud microphysics because they act as nuclei around which water droplets or ice forms.
微溶胶粒子可以凝结成更大的液滴,并逐渐长大,直至流向织物过滤介质底部而被排除。
Micro sol particles can condense into greater droplet, and grew up until the flow to the fabric filter medium bottom and be ruled out.
目的:利用静电液滴法制备三维生长的微囊化人乳腺癌细胞球并初步用于抗肿瘤药物筛选。
AIM: to prepare three-dimensional microencapsulated human breast cancer spheroid with electrostatic droplet generator and apply it in the screening of anticancer drug.
结论当滴加高锰酸钾液使供试液呈微红色时应迅速地完成实验操作。
CONCLUSIONS When experimental liquid changed into red, the experiment rapidly finished after dripping potassium permanganate.
在微化工过程中,微米量级的颗粒和液滴表面传递现象的研究具有重要的基础意义。
In the process of microchemical engineering, the research on the transfer phenomena on the surface concerning micrometer-size particle and droplet is of important basic significance.
采用顶空单液滴微萃取样品处理方法分离富集水中苯系物,用气相色谱法进行测定。
Benzene homologues in water were separated and enriched by head-space single-drop microextraction and determined by gas chromatography.
液滴微流控系统是微流控芯片领域的一个新的分支,由于其诸多独特的优势而得到了广泛的研究和报道。
Droplet microfluidics is a new area in microfluidics research and has been extensively studied and reported due to its various unique advantages.
本文所得结论为在流聚焦微沟道内获得分散性良好且大小可控的液滴提供了理论和数据支持。
Physical explanation is also proposed based on the Fluid dynamics. Thereby it provides a important reference to generate highly monodisperse and size-controllable droplets in microfluidic devices.
本文研究了流聚焦微沟道内不同两相流速比对单分散性液滴形成的影响。
Micro flow-focusing devices with different flow rate conditions are studied in order to produce highly monodisperse droplets.
本文研究了流聚焦微沟道内不同两相流速比对单分散性液滴形成的影响。
Micro flow-focusing devices with different flow rate conditions are studied in order to produce highly monodisperse droplets.
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