eddy-making resistance

简明释义

涡流阻力

英英释义

Eddy-making resistance refers to the opposition encountered by fluid flow due to the formation of eddies, which are swirling currents that disrupt the smooth flow of the fluid.

涡流产生阻力是指流体流动中由于涡流的形成而遇到的阻力,涡流是扰乱流体平稳流动的旋转流动。

例句

1.To optimize the heat exchanger, engineers had to calculate the eddy-making resistance 涡流阻力 involved.

为了优化热交换器,工程师们必须计算涉及的eddy-making resistance 涡流阻力

2.Engineers are studying how eddy-making resistance 涡流阻力 affects the flow of fluids in pipelines.

工程师们正在研究eddy-making resistance 涡流阻力如何影响管道中的流体流动。

3.The design of the new turbine took into account the eddy-making resistance 涡流阻力 to improve efficiency.

新涡轮的设计考虑了eddy-making resistance 涡流阻力以提高效率。

4.In aerodynamics, minimizing eddy-making resistance 涡流阻力 is crucial for reducing drag on aircraft.

在空气动力学中,最小化eddy-making resistance 涡流阻力对减少飞机阻力至关重要。

5.The research focused on the impact of eddy-making resistance 涡流阻力 on the performance of marine vessels.

研究集中在eddy-making resistance 涡流阻力对海洋船只性能的影响上。

作文

In the field of fluid dynamics, understanding the concept of eddy-making resistance is crucial for engineers and scientists. This term refers to the resistance encountered by a fluid as it flows past an object, creating swirling motions or eddies. These eddies can significantly impact the efficiency of various systems, from aircraft wings to underwater turbines. The study of eddy-making resistance helps in designing more efficient structures that minimize energy loss due to turbulence. When a fluid flows over a surface, it interacts with that surface in complex ways. At certain speeds and angles, the flow can separate from the surface, causing the formation of vortices or eddies. These eddies create a form of drag known as eddy-making resistance, which can hinder performance and increase energy consumption. For example, in aerodynamics, the design of an airplane wing must consider eddy-making resistance to ensure smooth airflow and reduce fuel consumption. Moreover, eddy-making resistance is not only relevant in aerodynamics but also plays a significant role in marine engineering. Ships and submarines experience this type of resistance as they move through water. Engineers must account for eddy-making resistance when designing hull shapes to optimize speed and fuel efficiency. A well-designed hull can minimize turbulence and allow for smoother travel through water, ultimately leading to better performance. Understanding eddy-making resistance also has implications in environmental science. For instance, the movement of water in rivers and oceans is affected by the presence of obstacles such as rocks and vegetation. These obstacles create eddies that can influence sediment transport and nutrient distribution. By studying eddy-making resistance, scientists can gain insights into how ecosystems function and how to manage them effectively. In conclusion, the concept of eddy-making resistance is vital across various fields, including engineering, environmental science, and physics. By grasping how eddies form and affect fluid flow, professionals can design better systems that enhance efficiency and sustainability. Whether in the sky or underwater, the principles behind eddy-making resistance are fundamental to optimizing performance and reducing energy waste. As technology advances, further research into this phenomenon will continue to play a key role in innovation and development. Understanding and mastering the intricacies of eddy-making resistance is essential for anyone involved in fluid dynamics. It is a concept that bridges theory and practical application, making it a cornerstone of modern engineering and environmental management.

在流体动力学领域,理解“eddy-making resistance”这一概念对工程师和科学家至关重要。这个术语指的是流体在流经物体时遇到的阻力,导致旋涡或涡流的形成。这些涡流会显著影响各种系统的效率,从飞机机翼到水下涡轮机。对“eddy-making resistance”的研究有助于设计更高效的结构,最大限度地减少因湍流造成的能量损失。当流体在表面上流动时,它与该表面的相互作用是复杂的。在某些速度和角度下,流动可能会从表面分离,导致涡旋或涡流的形成。这些涡流产生一种称为“eddy-making resistance”的阻力,这可能会妨碍性能并增加能耗。例如,在空气动力学中,飞机机翼的设计必须考虑“eddy-making resistance”,以确保气流平稳并减少燃料消耗。此外,“eddy-making resistance”不仅在空气动力学中相关,还在海洋工程中发挥着重要作用。船只和潜艇在水中移动时会经历这种类型的阻力。工程师在设计船体形状时必须考虑“eddy-making resistance”,以优化速度和燃料效率。精心设计的船体可以最小化湍流,使水中的旅行更加平稳,最终提高性能。理解“eddy-making resistance”在环境科学中也具有重要意义。例如,河流和海洋中的水流动受到岩石和植被等障碍物的影响。这些障碍物会产生涡流,影响沉积物运输和养分分布。通过研究“eddy-making resistance”,科学家可以深入了解生态系统的功能以及如何有效管理它们。总之,“eddy-making resistance”的概念在工程、环境科学和物理学等多个领域至关重要。通过掌握涡流的形成及其对流体流动的影响,专业人士可以设计出更好的系统,从而提高效率和可持续性。无论是在天空中还是水下,关于“eddy-making resistance”的原理都是优化性能和减少能源浪费的基础。随着技术的进步,对这一现象的进一步研究将继续在创新和发展中发挥关键作用。理解和掌握“eddy-making resistance”的复杂性对于任何参与流体动力学的人来说都是必不可少的。这是一个将理论与实际应用结合起来的概念,使其成为现代工程和环境管理的基石。