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相关概念视频

Bernoulli's Principle: Applications01:17

Bernoulli's Principle: Applications

There are many devices and situations in which fluid flows at a constant height and so can be analyzed using Bernoulli's principle. These devices include, but are not limited to, entrainment devices and fluid flow measuring devices.
Entrainment devices use a high fluid speed to create low pressures and, thus, entrain one fluid into another. Some examples of these devices are given below:
Laminar Flow01:27

Laminar Flow

Laminar flow represents a smooth, orderly fluid motion where particles move along parallel paths, resulting in minimal mixing between layers. Streamlined particle paths characterize this flow regime and occur under conditions where viscous forces dominate over inertial forces. The distinction between laminar, transitional, and turbulent flow is primarily determined by the Reynolds number, a dimensionless quantity calculated as:
Bioreactor Controls-II01:18

Bioreactor Controls-II

In aerobic fermentations, oxygen is vital for microbial growth and metabolite production. Since air comprises only about 20% oxygen and the gas is poorly soluble in water—just 9 ppm at 20°C—supplying sufficient oxygen becomes a critical challenge, especially in high-demand processes like yeast growth or citric acid production. Even a fully saturated broth may offer only a few seconds of oxygen availability.To address this, sterile or scrubbed air is introduced into the fermentor via a sparger...
Scale-Up Processes01:14

Scale-Up Processes

The scale-up of microbial fermentation processes is essential in industrial biotechnology, allowing the transition from laboratory-scale experiments to commercial-scale production while aiming to maintain product yield and quality. This process requires meticulous adjustment of equipment design, process parameters, and contamination control strategies to accommodate increasing culture volumes.At the laboratory scale, cultures are typically maintained in 1 to 10-liter glass or autoclavable...

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相关实验视频

Updated: Jun 25, 2026

Microfluidic Chips Controlled with Elastomeric Microvalve Arrays
18:11

Microfluidic Chips Controlled with Elastomeric Microvalve Arrays

Published on: October 1, 2007

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可定制的微流体设备:进步,限制和未来的进步

Alaa A A Aljabali1, Mohammad A Obeid1, Vijay Mishra2

  • 1Department of Pharmaceutics and Pharmaceutical Technology, Faculty of Pharmacy, Yarmouk University, Irbid 21163, Jordan.

Current drug delivery
|July 22, 2024
PubMed
概括
此摘要是机器生成的。

微流体利用小道进行流体控制,降低成本和更快的实验. 本综述探讨了可定制微流体器件的当前研究,局限性和未来潜力.

关键词:
微流体学 微流体学这就是SHM SHM.微通道.微通道.器官在芯片上的器官聚乙烯糖醇是一种聚乙烯糖醇.快速检测 快速检测 迅速检测可重复使用性可重复使用性.

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相关实验视频

Last Updated: Jun 25, 2026

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18:11

Microfluidic Chips Controlled with Elastomeric Microvalve Arrays

Published on: October 1, 2007

21.1K
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10:39

Reconfigurable Microfluidic Channel with Pin-discretized Sidewalls

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05:33

Rapid Fabrication of Custom Microfluidic Devices for Research and Educational Applications

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科学领域:

  • 微流体学 微流体学
  • 实验室在芯片上的技术
  • 微型化系统 微型化系统

背景情况:

  • 微流体学研究了微通道中的流体行为,以进行受控的操纵.
  • 这些系统在微尺度上利用独特的流体特性,与宏观系统相比,具有优势.
  • 优势包括减少样品/试剂量,降低成本,以及由于小型化加速实验时间表.

研究的目的:

  • 仔细研究微流体学当前的研究范式.
  • 确定当前存在的局限性,并探索可定制微流体设备的潜在前景.
  • 提供对微流体进步的未来轨迹的有远见的展望.

主要方法:

  • 审查现有的微流体系统及其操作原则.
  • 分析当前的科学进展,并确定该领域的限制.
  • 探索适应性微流体技术的未来方向和潜在应用.

主要成果:

  • 微流体学已经发展成为一个多方面的学科,有专门的子领域,如器官芯片和纸质微流体学.
  • 科学已经取得了重大进展,但将其转化为自主终端用户应用仍然是一个挑战.
  • 现有系统虽然先进,但面临的局限性阻碍了更广泛的采用.

结论:

  • 该论文强调了微流体系统的当前状态,复杂性和挑战.
  • 它强调需要解决更广泛应用的局限性.
  • 确定了未来微流体创新和发展的有希望的途径.