electroosmotic

简明释义

英[ˌɛlɛktrəʊˈɒzməʊtɪk]美[ˌɛlɛkˈtroʊˌɑzməˈtɪk]

电渗的

英英释义

单词用法

同义词

反义词

例句

1.In this paper, we studied the effects of voltage and different pulse-time ratio on electric conductivity during the process of electroosmotic dewatering on samples of bean curd.

本文采用不等占空比电场对豆凝乳进行脱水，主要考察了电压的大小和不等占空比对豆凝乳电导率的影响。

2.In this paper, we study the dewatering efficiency of tofu by using DC electroosmotic dewatering, different pulse-time electric fieldelectroosmotic dewatering and weight pressure.

本文在传统的重力压榨的基础上，又分别采用直流电场电渗透以及不等占空比电场电渗透来研究豆凝乳的脱水效果。

3.In this paper, we study the dewatering efficiency of tofu by using DC electroosmotic dewatering, different pulse-time electric fieldelectroosmotic dewatering and weight pressure.

本文在传统的重力压榨的基础上，又分别采用直流电场电渗透以及不等占空比电场电渗透来研究豆凝乳的脱水效果。

4.A microfluidic electroosmotic pump (EOP) capable of generating high pressure was investigated.

设计了一种高压微流量电渗泵。

5.Electroosmotic pump is a liquid driving apparatus, which has its advantages of simplified equipment, non pulsing flow rate, large flow range and moderate working voltage etc.

电渗泵是一种液流驱动泵，具有装置简单、载流无脉动、流量范围大和驱动电压适中等优点。

6.The coated column prepared by this method was good enough to repress the electroosmotic flow and the adsorption of the proteins on the capillary wall.

通过物理吸附方法将其涂布在熔融石英毛细管内表面，测定了涂层柱的电渗流及其对碱性蛋白质的分离能力。

7.Electroosmotic cell used to measure the two parameters was developed and then typical tests were conducted with this apparatus.

文章研制成一种可以对两个参数进行测量的设备——电渗仪，并进行了典型试验。

8.The results of these tests can be helpful to more reasonable design in ground improvement with electroosmotic.

应用电渗仪的试验结果，可以更科学合理地进行电渗加固设计。

9.The electroosmotic dewatering method is a new typical technology in soybean productions , especially in bean curd skin.

电渗透脱水在豆制品加工中，特别是豆腐皮加工中的应用，正处在研究阶段。

10.The proposed system consists of an electroosmotic pump and two solenoid valves, all of which are controlled by a PC computer automatically.

该系统由一台电渗泵和两个电磁三通阀组成，均由计算机控制，实现了准确、重现和自动的分析要求。

11.The electroosmotic 电渗透 effect is critical in designing efficient water filtration systems.

在设计高效水过滤系统时，电渗透 电渗透效应至关重要。

12.In drug delivery systems, electroosmotic 电渗透 pumps can enhance the efficiency of transporting medications through biological membranes.

在药物输送系统中，电渗透 电渗透泵可以提高药物穿过生物膜的效率。

13.Researchers are exploring electroosmotic 电渗透 phenomena to improve soil remediation techniques.

研究人员正在探索电渗透 电渗透现象，以改善土壤修复技术。

14.The process of electroosmotic 电渗透 flow is utilized in microfluidic devices to manipulate small volumes of fluids.

在微流体设备中，利用电渗透 电渗透流动来操控小体积的液体。

15.By applying an electric field, we can induce electroosmotic 电渗透 flow to move particles in a controlled manner.

通过施加电场，我们可以诱导电渗透 电渗透流动，以控制粒子的移动。

作文

The study of fluid dynamics has led to various applications in science and engineering, one of which is the phenomenon known as electroosmotic flow. This process occurs when an electric field is applied across a porous medium, causing the movement of liquid through the material due to the interaction between the electric field and the charged particles within the liquid. Understanding electroosmotic flow is crucial in several fields, including soil mechanics, microfluidics, and biomedical engineering. In soil mechanics, electroosmotic techniques are often employed to improve the stability of soil structures. By applying an electric field to saturated soils, engineers can enhance the drainage of excess water, leading to increased soil strength and reduced settlement. This method is particularly useful in areas where traditional drainage methods are ineffective or impractical. Microfluidics is another area where electroosmotic flow plays a significant role. In lab-on-a-chip devices, fluids are manipulated at the microscale, and electroosmotic flow allows for precise control over the movement of small volumes of liquids. This capability is essential for various applications, including chemical analysis, biological assays, and drug delivery systems. The ability to drive fluids using electric fields rather than mechanical pumps simplifies the design of these devices and can lead to more efficient processes. In biomedical engineering, electroosmotic flow is being explored for its potential in drug delivery systems. Researchers are investigating how to utilize electric fields to enhance the transport of therapeutic agents across biological barriers, such as cell membranes. This approach could lead to more effective treatments with fewer side effects, as it allows for targeted delivery of drugs to specific tissues or cells. Despite the numerous advantages of electroosmotic flow, there are challenges that researchers and engineers must address. One major issue is the dependence of electroosmotic flow on the properties of the medium through which the fluid is moving. Factors such as pore size, surface charge, and fluid viscosity can significantly affect the efficiency of electroosmotic transport. Therefore, it is essential to conduct thorough studies to optimize these parameters for each specific application. Moreover, the long-term stability of electroosmotic systems remains a concern, particularly in soil applications where environmental conditions can change over time. Ensuring that the electric field remains effective and does not degrade under varying conditions is critical for the success of electroosmotic methods in practical scenarios. In conclusion, the concept of electroosmotic flow is a fascinating area of study with wide-ranging applications across different fields. Its ability to manipulate fluid movement through the application of electric fields opens up new possibilities for innovation in engineering and technology. As research continues to advance, we can expect to see even more applications of electroosmotic flow that will benefit society, from improving infrastructure to revolutionizing healthcare. Understanding and mastering the principles behind electroosmotic flow will undoubtedly be essential for future advancements in these fields.

流体动力学的研究导致了科学和工程中各种应用，其中之一是被称为电渗透流的现象。当在多孔介质上施加电场时，液体由于电场与液体中带电颗粒之间的相互作用而通过材料移动。理解电渗透流在多个领域至关重要，包括土壤力学、微流体学和生物医学工程。在土壤力学中，通常采用电渗透技术来改善土壤结构的稳定性。通过对饱和土壤施加电场，工程师可以增强多余水分的排水，从而提高土壤强度并减少沉降。这种方法在传统排水方法无效或不切实际的地区特别有用。微流体学是另一个电渗透流发挥重要作用的领域。在芯片实验室设备中，流体在微观尺度上被操控，而电渗透流允许对小体积液体的精确控制。这种能力对于各种应用至关重要，包括化学分析、生物检测和药物递送系统。利用电场驱动流体而不是机械泵简化了这些设备的设计，并可以导致更高效的过程。在生物医学工程中，研究人员正在探讨如何利用电渗透流在药物递送系统中的潜力。研究人员正在研究如何利用电场增强治疗剂穿过生物屏障（如细胞膜）的运输。这种方法可能导致更有效的治疗，副作用更少，因为它允许将药物靶向递送到特定组织或细胞。尽管电渗透流有许多优点，但研究人员和工程师必须解决一些挑战。一个主要问题是电渗透流对流体移动介质的性质的依赖。孔径、表面电荷和流体粘度等因素会显著影响电渗透运输的效率。因此，进行全面研究以优化每个特定应用的这些参数是至关重要的。此外，尤其是在土壤应用中，电渗透系统的长期稳定性仍然是一个问题，因为环境条件可能会随时间变化。确保电场保持有效并且不会在不同条件下退化，对于电渗透方法在实际场景中的成功至关重要。总之，电渗透流的概念是一个迷人的研究领域，具有广泛的跨领域应用。其通过施加电场操控流体运动的能力为工程和技术的创新开辟了新的可能性。随着研究的不断推进，我们可以期待看到更多电渗透流的应用将惠及社会，从改善基础设施到革新医疗保健。理解和掌握电渗透流背后的原理无疑将是未来这些领域进步的关键。