applied fluid dynamics

简明释义

应用流体动力学

英英释义

例句

1.Researchers in marine engineering utilize applied fluid dynamics (应用流体力学) to design more efficient hull shapes for ships.

海洋工程的研究人员利用应用流体力学来设计更高效的船体形状。

2.In automotive engineering, applied fluid dynamics (应用流体力学) is used to improve the aerodynamics of vehicles for better fuel efficiency.

在汽车工程中，应用流体力学被用来改善车辆的空气动力学，以提高燃油效率。

3.The study of weather patterns often employs applied fluid dynamics (应用流体力学) to model atmospheric movements.

天气模式的研究通常采用应用流体力学来模拟大气运动。

4.The design of aircraft wings heavily relies on applied fluid dynamics (应用流体力学) to optimize lift and minimize drag.

飞机机翼的设计严重依赖于应用流体力学来优化升力并最小化阻力。

5.In the field of civil engineering, applied fluid dynamics (应用流体力学) helps in designing effective drainage systems.

在土木工程领域，应用流体力学有助于设计有效的排水系统。

作文

Understanding the concept of applied fluid dynamics is essential for various fields of engineering and science. Applied fluid dynamics refers to the practical application of fluid dynamics principles to solve real-world problems involving fluids in motion. This can include anything from the design of aircraft and automobiles to the analysis of weather patterns and ocean currents. The study of applied fluid dynamics allows engineers and scientists to predict how fluids behave under different conditions, which is crucial for innovation and safety in many industries.One of the primary areas where applied fluid dynamics is utilized is in aerospace engineering. Engineers must understand how air flows over wings and fuselages to design aircraft that are both efficient and safe. By applying the principles of applied fluid dynamics, they can conduct simulations and experiments that help optimize the shape of an aircraft to reduce drag and improve fuel efficiency. This not only enhances performance but also contributes to environmental sustainability by minimizing emissions.In addition to aerospace, applied fluid dynamics plays a significant role in civil engineering, particularly in the design of hydraulic structures such as dams and bridges. Engineers must consider how water flows around these structures to ensure stability and prevent erosion. By utilizing applied fluid dynamics, they can model water flow and make informed decisions about materials and designs that will withstand the forces exerted by moving water.Another critical application of applied fluid dynamics is in the field of meteorology. Understanding fluid dynamics helps meteorologists predict weather patterns and phenomena such as hurricanes and tornadoes. By analyzing the movement of air and moisture in the atmosphere, scientists can develop models that forecast severe weather events, ultimately saving lives and property. The integration of applied fluid dynamics with advanced computational techniques has revolutionized our ability to understand and predict the Earth's climate.Moreover, applied fluid dynamics is vital in the biomedical field, particularly in understanding blood flow in the human body. Researchers use principles of fluid dynamics to study how blood circulates through arteries and veins, which can lead to advancements in medical treatments and devices. For example, the design of artificial heart valves and stents relies heavily on applied fluid dynamics to ensure that these devices function correctly within the complex system of human circulation.In conclusion, applied fluid dynamics is a multidisciplinary field that encompasses various applications across engineering, environmental science, and medicine. Its principles are fundamental in solving practical problems, enhancing safety, and driving innovation. As technology continues to advance, the importance of applied fluid dynamics will only grow, making it a crucial area of study for future engineers and scientists. By mastering the concepts and applications of applied fluid dynamics, we can better address the challenges faced in our rapidly changing world.

理解应用流体动力学的概念对于各个工程和科学领域至关重要。应用流体动力学是指将流体动力学原理应用于解决涉及流动流体的现实问题。这可以包括从飞机和汽车的设计到天气模式和海洋洋流的分析。研究应用流体动力学使工程师和科学家能够预测流体在不同条件下的行为，这对许多行业的创新和安全至关重要。应用流体动力学被广泛应用于航空航天工程。工程师必须了解空气如何在机翼和机身上流动，以设计既高效又安全的飞机。通过应用应用流体动力学的原理，他们可以进行模拟和实验，帮助优化飞机的形状以减少阻力并提高燃油效率。这不仅提高了性能，还有助于通过减少排放来实现环境可持续性。除了航空航天，应用流体动力学在土木工程中也发挥着重要作用，特别是在水利结构（如大坝和桥梁）的设计中。工程师必须考虑水流如何绕过这些结构，以确保稳定性并防止侵蚀。通过利用应用流体动力学，他们可以对水流进行建模，并就材料和设计做出明智的决策，以承受流动水施加的力量。应用流体动力学的另一个关键应用是在气象学领域。理解流体动力学有助于气象学家预测天气模式和现象，例如飓风和龙卷风。通过分析大气中空气和水分的运动，科学家可以开发出预测严重天气事件的模型，从而最终拯救生命和财产。将应用流体动力学与先进的计算技术相结合，彻底改变了我们理解和预测地球气候的能力。此外，应用流体动力学在生物医学领域也至关重要，特别是在理解人体内血液流动方面。研究人员利用流体动力学的原理研究血液如何在动脉和静脉中循环，这可以促成医疗治疗和设备的进步。例如，人工心脏瓣膜和支架的设计在很大程度上依赖于应用流体动力学，以确保这些设备在复杂的人体循环系统中正常工作。总之，应用流体动力学是一个多学科领域，涵盖了工程、环境科学和医学等多个应用。其原理在解决实际问题、增强安全性和推动创新方面是基础性的。随着技术的不断进步，应用流体动力学的重要性将只会增加，使其成为未来工程师和科学家研究的关键领域。通过掌握应用流体动力学的概念和应用，我们可以更好地应对快速变化的世界所面临的挑战。