scale of turbulence

简明释义

湍流度

英英释义

例句

1.The scale of turbulence experienced during the storm was higher than anticipated.

暴风雨期间经历的湍流强度高于预期。

2.Passengers were informed about the scale of turbulence expected during the flight.

乘客被告知预计在飞行过程中会有的湍流强度。

3.Meteorologists are studying the scale of turbulence in the atmosphere to improve weather predictions.

气象学家正在研究大气中的湍流强度以改善天气预测。

4.Understanding the scale of turbulence is crucial for aircraft design.

理解湍流强度对于飞机设计至关重要。

5.The pilot had to adjust the flight path due to the unexpected scale of turbulence.

由于意外的湍流强度，飞行员不得不调整航线。

作文

In the study of fluid dynamics, the concept of turbulence plays a crucial role in understanding how fluids behave under various conditions. One key aspect of turbulence is its intensity and extent, often referred to as the scale of turbulence. This term encompasses not only the size of turbulent eddies but also the energy associated with them. The scale of turbulence can vary significantly depending on the flow conditions, such as velocity, viscosity, and the presence of obstacles in the fluid's path.When we examine natural phenomena, the scale of turbulence becomes particularly relevant. For instance, in meteorology, the turbulence within the atmosphere can influence weather patterns, storm development, and even climate change. Understanding the scale of turbulence in these contexts helps meteorologists predict severe weather events more accurately. Similarly, in oceanography, the scale of turbulence affects ocean currents and the distribution of nutrients, which are vital for marine ecosystems.In engineering applications, the scale of turbulence is equally important. For example, in the design of aircraft, engineers must consider the scale of turbulence that the aircraft will encounter during flight. Turbulent airflow can impact lift, drag, and overall performance. By analyzing the scale of turbulence, engineers can optimize designs to enhance safety and efficiency.Moreover, the scale of turbulence has implications in environmental science. In river systems, for instance, the turbulence generated by flowing water can affect sediment transport and erosion. Understanding the scale of turbulence in these environments can aid in the management of waterways and the preservation of aquatic habitats.In conclusion, the scale of turbulence is a multifaceted concept that extends across various fields of study. From meteorology to engineering and environmental science, grasping the nuances of the scale of turbulence enables us to better comprehend complex systems and make informed decisions. As research continues to advance, our understanding of the scale of turbulence will undoubtedly evolve, leading to more effective solutions to the challenges we face in both natural and engineered systems.

在流体动力学的研究中，湍流的概念在理解流体在各种条件下的行为方面起着至关重要的作用。湍流的一个关键方面是其强度和范围，通常被称为湍流的尺度。这个术语不仅包括湍流涡旋的大小，还包括与之相关的能量。湍流的尺度可以根据流动条件如速度、粘度以及流体路径中的障碍物的存在而显著变化。当我们考察自然现象时，湍流的尺度变得尤为重要。例如，在气象学中，大气中的湍流可以影响天气模式、风暴发展甚至气候变化。理解这些背景下的湍流的尺度有助于气象学家更准确地预测严重天气事件。类似地，在海洋学中，湍流的尺度影响海洋洋流和营养物质的分布，这对海洋生态系统至关重要。在工程应用中，湍流的尺度同样重要。例如，在飞机设计中，工程师必须考虑飞机在飞行过程中将遇到的湍流的尺度。湍流气流会影响升力、阻力和整体性能。通过分析湍流的尺度，工程师可以优化设计，以增强安全性和效率。此外，湍流的尺度在环境科学中也有影响。在河流系统中，例如，流动水产生的湍流可以影响沉积物运输和侵蚀。了解这些环境中的湍流的尺度可以帮助管理水道和保护水生栖息地。总之，湍流的尺度是一个多方面的概念，跨越多个研究领域。从气象学到工程学再到环境科学，掌握湍流的尺度的细微差别使我们能够更好地理解复杂系统并做出明智的决策。随着研究的持续进展，我们对湍流的尺度的理解无疑会不断演变，从而导致更有效的解决方案，以应对我们在自然和工程系统中面临的挑战。