微流体

CO2激光直写加工聚合物微流体芯片的建模研究

Modeling Research of CO_2 Laser Direct Writing Polymer Microfluidic Chip

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 chips based on MEMS technology exhibit great potentials in analytical chemistry and biomedical fields .

引入微流体力学理论对PCR微流控芯片微通道的结构进行优化设计。

The microchannel structure of micro-flow PCR chip is made optimized design by microfluid mechanical theory .

结合实验表明文中建立的ANSYS微流体模型在低载荷下与实验基本吻合，在高载荷下产生失真。

The simulation of ANSYS accords with actual flowing in the nozzles only under the low velocity .

基于MEMS的微流体机械研究进展

Investigation Progress in MEMS-based Micro Fluid Machinery

微机电系统（MEMS）是涉及微电子学、微机械学、微流体学等多个学科领域内容的复杂系统，具有多学科、多物理域交叉耦合的特点，为其产品的设计带来了较大的难度。

MEMS is a complex system which refers to several disciplines such as micro-electronics , micro-mechanics and micro-fluidics .

我们能利用微流体，像斯坦福的SteveQuake公司制造的芯片。

We can now leverage microfluidics , like this chip made by Steve Quake at Stanford .

用于SPR生物传感器的微流体系统设计与制作

The Design and Manufacture of Microfluid System for SPR Biosensors

微流体芯片技术在ABO血型基因分型中的应用

Application of Microfluidic Chip Analytical Systems in ABO Genotyping

微流体泵的定向净流量主要来自于Navier-Stokes方程的非线性。

The directional flow rate of the pump is governed by nonlinearity of Navier-Stokes equations .

而作为微电子机械系统（MEMS）的一个重要分支，微流体系统已得到了很大的发展和广泛的应用。

As one of the main branches of MEMS , micro flow systems have achieved a great development and wide application .

实现定量和混合的PDMS微流体器件的研究

PDMS-based Microfluidic Devices with Capability of Metering and Mixing

基于SU-8负胶的微流体器件的制作及研究

Fabrication and study of microfluidic devices using SU-8

表明格子Boltzmann方法可以作为微流体混合器及微流体芯片设计中的一种有效的分析工具。

Above results show that the lattice Boltzmann method could be used as a powerful tool for the researches of microfluidic mixers and microfluidic chips .

随着MEMS技术在生物医学工程领域的广泛应用，微流体驱动与控制技术的研究已逐渐成为MEMS研究的一个热点。

With the extensive application of Micro-electromechanical System ( MEMS ) in the domain of BME , fluid driving and controlling technique has become one of the research hotspots of MEMS technique .

介绍了实现微流体的精确定量和快速混合的基本方法，设计并制作了采用基于PDMS通道的微流体器件。

It presents a new approach to realize the exact metering and quick mixing . The microfluidic device based on PDMS channels is designed and fabricated .

基于Micro-PIV技术的电动微流体测量研究

Research on Electrokinetic Microflow Measurement Based on Micro-PIV

PCR-CE微流体芯片控制系统开发

PCR-CE Micro-fluidic Chip Control System Development

本文针对现有基于压电陶瓷的驱动控制系统体积较大、功耗高和输出信号不稳定等缺点，引入嵌入式设计方法，设计了一种基于ARM技术的微流体驱动控制系统。

According to the faults of existing driving control system which based on Piezoelectric ceramic , such as large size , high power consumption , unstable output signal , etc. this paper designed a microfluidic driving control system based on ARM technology by the embedded design method .

微型泵是微流体控制系统的重要组成部件，在生化分析、药物输送、芯片冷却等领域都有着广泛的应用前景，已成为MEMS研究领域中的热点课题之一。

As an important component of micro fluidic controlling systems , micropump has many applications , such as biological and chemical analysis , drug delivery , IC chip cooling , and the like . Micropumps have become one hotspot in MEMS research fields .

作为MEMS技术的一个重要分支，微流体系统已得到了很大的发展和广泛的应用，但其内部的流动和传递过程的理论仍不成熟。

As one of the main branches of MEMS , micro flow systems have achieved a great development and wide application . However , there are many unsolved academic problems and challenges in the flow and transport processes of the micro fluidic systems .

以电渗或压力驱动下不可压缩的牛顿流体为对象，使用N-S方程和连续性方程描述微流体的运动，使用热传导方程和相变方程描述制冷作用下微流体的能量传导以及产生的相变。

The micro fluid movement was described by N-S equation and continuity equation , the micro fluid energy transmission and the generations of the phase change were described by heat conduction equation and phase-change equation .

在典型结构的PCF-SPR传感器的基础上，我们设计了大孔径微流体通道的PCF-SPR传感器。

Based on the typical structure of the PCF-SPR sensor , a PCF-SPR sensor with large size microfluidic channels is proposed .

基于硅结构的微流体控制系统（μFCs）是微机电系统（MEMS）中的一个重要分支，可广泛用于生物、医学、化工、电子等领域。

Micro fluidic controlling system (μ FCs ) based on silicon structure is an important part of Micro-electro-mechanical Systems ( MEMS ) and has great wide applications in the future in many fields such as biology , medicine , chemistry , electronics , and so on .

此外，本论文还采用微流体芯片纺丝装置进行了简化工艺法RSF水溶液的干纺初探，发现通过该技术，RSF纤维的结构与性能有望进一步改善。

In addition , the microfluidic chip was tried to dry spin RSF fibers from the simply prepared RSF aqueous solution . It was found that the structures and properties of the resultant RSF fiber could be improved by using this technology .

基于微流体数字化技术的微化学反应器

Micro Chemical Reactor Based on the Digitalization Technology of Micro fluid

微流体速度流型影响因素数值模拟分析

Numerical analysis on the influence factors of velocity profile in microfluidic

规整双重乳液的微流体数字化制备原理实验

Principle experiments of standardized double emulsions using digitalization of microfluids technology

生物芯片无阀压电扩散管微流体泵流场数值模拟

Numerical Simulations of Periodical Flows of Piezoelectric Valveless Micropump for Biochips

生物芯片压电微流体泵扩散管液体流量效率分析

Flow Rate Analysis of Diffuser of Micro - Pumps in Biochips