fluidic device

简明释义

射联件

英英释义

例句

1.Researchers are using a fluidic device to study the behavior of cells in different environments.

研究人员正在使用流体装置研究细胞在不同环境中的行为。

2.This fluidic device can accurately measure the viscosity of various fluids.

这个流体装置可以准确测量各种液体的粘度。

3.In the lab, we tested a fluidic device that separates particles based on their size.

在实验室中，我们测试了一种根据颗粒大小分离的流体装置。

4.The new fluidic device is designed to control the flow of liquids in microfluidic applications.

新的流体装置旨在控制微流体应用中的液体流动。

5.The fluidic device was integrated into the medical diagnostic system for better accuracy.

该流体装置被集成到医疗诊断系统中，以提高准确性。

作文

In the realm of modern engineering, the term fluidic device refers to a type of technology that utilizes the principles of fluid dynamics to control and manipulate fluids. These devices have gained significant attention due to their versatility and efficiency in various applications, ranging from industrial processes to medical devices. The underlying concept of a fluidic device is relatively simple: by directing the flow of liquids or gases through strategically designed channels, one can achieve desired outcomes such as mixing, separation, or actuation. One of the most remarkable aspects of fluidic devices is their ability to operate without moving parts. This characteristic not only reduces wear and tear but also minimizes maintenance requirements, making them highly reliable. For instance, in the field of medicine, fluidic devices are utilized in microfluidics, where tiny volumes of fluids are manipulated for applications like drug delivery and diagnostic testing. The precision with which these devices can handle small quantities of fluids enables researchers to conduct experiments with greater accuracy and efficiency.Moreover, fluidic devices are often more environmentally friendly compared to traditional mechanical systems. Since they rely on the flow of fluids rather than mechanical components, they tend to consume less energy and produce less waste. This makes them an attractive option for industries looking to reduce their carbon footprint and promote sustainability.In industrial settings, fluidic devices are employed in processes such as chemical mixing and material handling. By optimizing fluid flow, these devices can enhance productivity and ensure consistent quality in manufacturing processes. For example, in the production of paints and coatings, fluidic devices can be used to achieve uniform dispersion of pigments, resulting in superior product performance.The versatility of fluidic devices extends beyond industrial applications; they are also making waves in the field of robotics. Engineers are exploring the integration of fluidic devices into robotic systems to create soft robots that can navigate complex environments. These soft robots, powered by fluidic actuators, can mimic the movements of biological organisms, offering new possibilities in fields ranging from search and rescue operations to minimally invasive surgeries.In conclusion, the significance of fluidic devices in contemporary technology cannot be overstated. Their unique ability to manipulate fluids with precision and efficiency makes them invaluable across various sectors. As research continues to advance in this field, we can expect to see even more innovative applications of fluidic devices that will revolutionize the way we approach engineering challenges. The future of technology seems promising with the ongoing development of fluidic devices, paving the way for smarter, more efficient solutions to complex problems.

在现代工程领域，术语流体装置指的是一种利用流体动力学原理来控制和操纵流体的技术。这些设备由于其在各种应用中的多功能性和高效性而受到广泛关注，从工业过程到医疗设备。流体装置的基本概念相对简单：通过将液体或气体的流动引导通过精心设计的通道，可以实现所需的结果，例如混合、分离或驱动。流体装置最显著的特点之一是它们能够在没有运动部件的情况下运行。这一特性不仅减少了磨损，还最小化了维护要求，使它们具有高度的可靠性。例如，在医学领域，流体装置被用于微流体技术，其中微量流体被操控用于药物输送和诊断测试等应用。这些设备可以以极高的精度处理小量流体，使研究人员能够以更高的准确性和效率进行实验。此外，与传统机械系统相比，流体装置通常更加环保。由于它们依赖流体的流动而不是机械部件，因此它们往往消耗更少的能源并产生更少的废物。这使得它们成为希望减少碳足迹并促进可持续发展的行业的有吸引力的选择。在工业环境中，流体装置被用于化学混合和物料搬运等过程。通过优化流体流动，这些设备可以提高生产力并确保制造过程中的一致质量。例如，在涂料和涂层的生产中，流体装置可以用于实现颜料的均匀分散，从而产生优越的产品性能。流体装置的多功能性不仅限于工业应用；它们在机器人领域也正在引起关注。工程师们正在探索将流体装置集成到机器人系统中，以创建能够在复杂环境中导航的软机器人。这些由流体驱动的软机器人能够模仿生物有机体的运动，为从搜索和救援操作到微创手术等领域提供新的可能性。总之，流体装置在当代技术中的重要性不容小觑。它们以精确和高效操纵流体的独特能力使它们在各个行业中不可或缺。随着这一领域的研究不断进展，我们可以期待看到更多创新的流体装置应用，这将彻底改变我们应对工程挑战的方式。随着流体装置的持续发展，技术的未来似乎充满希望，为复杂问题提供更智能、更高效的解决方案。