applied hydrodynamics

简明释义

应用水动力学

英英释义

例句

1.The study of ship design heavily relies on applied hydrodynamics (应用流体动力学) to optimize hull shapes.

船舶设计的研究在很大程度上依赖于应用流体动力学 (应用流体动力学)来优化船体形状。

2.In environmental engineering, applied hydrodynamics (应用流体动力学) helps in modeling the dispersion of pollutants in water bodies.

在环境工程中，应用流体动力学 (应用流体动力学)有助于模拟污染物在水体中的扩散。

3.In sports science, applied hydrodynamics (应用流体动力学) is used to analyze swimmers' movements in water.

在运动科学中，应用流体动力学 (应用流体动力学)用于分析游泳者在水中的动作。

4.Researchers use applied hydrodynamics (应用流体动力学) to improve the efficiency of tidal energy systems.

研究人员利用应用流体动力学 (应用流体动力学)来提高潮汐能源系统的效率。

5.The principles of applied hydrodynamics (应用流体动力学) are essential for designing efficient water treatment facilities.

设计高效的水处理设施时，应用流体动力学 (应用流体动力学)的原理至关重要。

作文

Applied hydrodynamics is a branch of fluid mechanics that focuses on the practical application of fluid dynamics principles to solve real-world problems. It plays a crucial role in various fields, including engineering, environmental science, and maritime operations. By understanding the behavior of fluids in motion, engineers and scientists can design more efficient systems, predict natural phenomena, and improve safety measures in water-related activities.One of the most significant applications of applied hydrodynamics (应用水动力学) is in the field of naval architecture. Ship designers utilize the principles of fluid dynamics to create vessels that minimize resistance and maximize stability. By conducting experiments in towing tanks and utilizing computational fluid dynamics (CFD) simulations, they can optimize hull shapes to enhance performance. This not only leads to faster ships but also reduces fuel consumption, which is essential for both economic and environmental reasons.In addition to naval architecture, applied hydrodynamics (应用水动力学) is vital in the design of hydraulic systems. Engineers rely on the principles of fluid mechanics to create efficient pumps, turbines, and piping systems. For instance, in hydroelectric power plants, the flow of water through turbines is carefully analyzed to maximize energy conversion. By applying hydrodynamic principles, engineers can ensure that these systems operate at peak efficiency, providing sustainable energy while minimizing waste.Another critical area where applied hydrodynamics (应用水动力学) is utilized is in environmental science. Understanding how water flows in rivers, lakes, and oceans is essential for managing ecosystems and predicting the impact of human activities on these environments. For example, hydrodynamic models can simulate the dispersion of pollutants in water bodies, allowing scientists to assess the potential risks to aquatic life and public health. These models help policymakers make informed decisions about water quality management and conservation efforts.Furthermore, applied hydrodynamics (应用水动力学) is instrumental in the study of natural disasters such as floods and tsunamis. By analyzing the flow of water during these events, researchers can develop better prediction models and early warning systems. This knowledge is crucial for disaster preparedness and response, potentially saving lives and reducing economic losses.In recent years, advancements in technology have further enhanced the field of applied hydrodynamics (应用水动力学). The use of high-performance computing and sophisticated modeling software allows for more accurate simulations of fluid behavior. These tools enable researchers to explore complex scenarios that were previously difficult to analyze, leading to new insights and innovations.In conclusion, applied hydrodynamics (应用水动力学) is an essential discipline that bridges theoretical fluid dynamics with practical applications. Its significance spans across multiple sectors, from engineering and environmental science to disaster management. As we continue to face challenges related to water resources and climate change, the insights gained from applied hydrodynamics (应用水动力学) will be invaluable in developing sustainable solutions and enhancing our understanding of fluid behavior in various contexts.