vortex spacing

简明释义

涡距

英英释义

例句

1.The aerodynamic efficiency of the wing is affected by the vortex spacing 涡旋间距 between the trailing edges.

机翼的空气动力效率受到后缘之间的涡旋间距 涡旋间距的影响。

2.In fluid dynamics, vortex spacing 涡旋间距 can influence the stability of flow patterns.

在流体动力学中，涡旋间距 涡旋间距可以影响流动模式的稳定性。

3.Engineers must calculate the optimal vortex spacing 涡旋间距 to minimize drag in their designs.

工程师必须计算最佳的涡旋间距 涡旋间距以最小化设计中的阻力。

4.For optimal performance, the vortex spacing 涡旋间距 should be fine-tuned based on operating conditions.

为了获得最佳性能，涡旋间距 涡旋间距应根据操作条件进行微调。

5.The researchers adjusted the vortex spacing 涡旋间距 in their simulations to observe changes in turbulence.

研究人员在他们的模拟中调整了涡旋间距 涡旋间距以观察湍流的变化。

作文

In the field of fluid dynamics, the term vortex spacing refers to the distance between two or more vortices in a fluid flow. Understanding vortex spacing is crucial for analyzing various phenomena, such as turbulence, lift generation in aerodynamics, and mixing processes in chemical engineering. Vortices are swirling motions of fluid that can significantly impact the behavior of the flow around them. For instance, in aviation, the vortex spacing created by aircraft wings can affect the performance of other nearby aircraft, particularly during takeoff and landing phases.One of the most notable applications of vortex spacing is in the design of airfoils. Engineers must consider how the distance between vortices influences lift and drag forces. A smaller vortex spacing can lead to increased lift but may also result in higher drag, which can be detrimental to flight efficiency. Conversely, a larger vortex spacing can reduce drag but might not provide sufficient lift, especially at lower speeds. Therefore, finding an optimal balance is essential for effective airfoil design.In addition to aerodynamics, vortex spacing plays a vital role in environmental studies, particularly in understanding ocean currents and weather patterns. The spacing of vortices in large bodies of water can influence nutrient distribution, temperature gradients, and even the formation of weather systems. Researchers utilize models to predict how changes in vortex spacing can alter these environmental factors, leading to better forecasting and management strategies.Moreover, vortex spacing is also significant in industrial applications, such as mixing and separation processes. In chemical reactors, the arrangement and distance between vortices can affect reaction rates and product yields. Engineers strive to optimize vortex spacing to enhance mixing efficiency, ensuring that reactants come into contact with each other effectively. This optimization can lead to reduced processing times and improved overall efficiency in chemical production.Furthermore, understanding vortex spacing contributes to advancements in renewable energy technologies. In wind turbine design, the interaction of vortices generated by one turbine can impact the performance of adjacent turbines. By studying the vortex spacing between turbines, engineers can optimize their layout to maximize energy capture while minimizing wake losses.In conclusion, the concept of vortex spacing is integral to various scientific and engineering disciplines. Its implications extend from aerodynamics and environmental science to industrial processes and renewable energy applications. As our understanding of fluid dynamics continues to evolve, the significance of vortex spacing will undoubtedly remain a focal point for researchers and engineers alike. By optimizing vortex spacing, we can enhance performance, improve efficiency, and contribute to more sustainable practices across multiple fields.

在流体动力学领域，术语涡旋间距指的是流体流动中两个或多个涡旋之间的距离。理解涡旋间距对于分析各种现象至关重要，例如湍流、空气动力学中的升力生成以及化学工程中的混合过程。涡旋是流体的旋转运动，可以显著影响周围流动的行为。例如，在航空中，飞机机翼产生的涡旋间距可以影响其他附近飞机的性能，尤其是在起飞和着陆阶段。涡旋间距的一个显著应用是在气动翼的设计中。工程师必须考虑涡旋之间的距离如何影响升力和阻力。较小的涡旋间距可能导致升力增加，但也可能导致更高的阻力，这对飞行效率有害。相反，较大的涡旋间距可以减少阻力，但可能无法提供足够的升力，特别是在低速时。因此，找到最佳平衡对于有效的气动翼设计至关重要。除了空气动力学，涡旋间距在环境研究中也发挥着重要作用，特别是在理解海洋洋流和天气模式方面。大水体中涡旋的间距可以影响营养物质分布、温度梯度，甚至天气系统的形成。研究人员利用模型预测涡旋间距的变化如何改变这些环境因素，从而导致更好的预测和管理策略。此外，涡旋间距在工业应用中也很重要，例如混合和分离过程。在化学反应器中，涡旋的排列和距离可以影响反应速率和产品产量。工程师努力优化涡旋间距以提高混合效率，确保反应物有效接触。这种优化可以缩短处理时间，提高化学生产的整体效率。此外，理解涡旋间距有助于可再生能源技术的进步。在风力发电机设计中，一个涡轮产生的涡旋与邻近涡轮的相互作用可以影响其性能。通过研究涡轮之间的涡旋间距，工程师可以优化它们的布局，以最大限度地捕获能量，同时减少尾流损失。总之，涡旋间距的概念对各种科学和工程学科至关重要。它的影响从空气动力学和环境科学扩展到工业过程和可再生能源应用。随着我们对流体动力学理解的不断发展，涡旋间距的重要性无疑将继续成为研究人员和工程师的焦点。通过优化涡旋间距，我们可以提高性能、改善效率，并为多个领域的可持续实践做出贡献。