The driving control system is the important equipment system in the applications of Digitalization of Microfluidic technology.
驱动控制系统是微流体数字化技术各项应用中的重要设备系统。
Microfluidic technology can address this issue through its ability to control complex reactions at critical times and locations.
微流体技术通过在关键时间和关键区域对此进行控制可以解决这一问题。
And it proposed the special design requirements of piezoelectric driving control system, which were applied for Digitalization of Microfluidic technology by above conclusions.
在此基础上,提出了微流体数字化技术用压电驱动控制系统的特殊设计要求。
Microfluidic chips based on MEMS technology exhibit great potentials in analytical chemistry and biomedical fields.
基于MEMS技术的微流体芯片在分析化学和生物医学领域显示了巨大的应用潜力。
Microfluidic chip technology has the preparation of simple, low reagent use, easy to operate, etc. , so in the biochemical analysis of the growing attention.
微流控芯片技术具有制备简单、试剂用量少、操作方便等优点,因此在生化分析中的应用越来越受到重视。
The character of microfluidic chip and capillary is analyzed, and UV-Curing technology is expounded.
分析了微流控芯片与毛细管各自特点,并对紫外固化技术进行了阐述。
To develop a practical PCR microfluidic chip system, the polymethylmethacrylate (PMMA) based continuous-flow PCR microfluidic chip system and its application technology was researched in this thesis.
为了开发一套实用的PCR微流控芯片系统,本论文对以PMMA(聚甲基丙烯酸甲酯)为基底材料的连续流式PCR微流控芯片系统及其应用技术进行了研究。
To develop a practical PCR microfluidic chip system, the polymethylmethacrylate (PMMA) based continuous-flow PCR microfluidic chip system and its application technology was researched in this thesis.
为了开发一套实用的PCR微流控芯片系统,本论文对以PMMA(聚甲基丙烯酸甲酯)为基底材料的连续流式PCR微流控芯片系统及其应用技术进行了研究。
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