hydrodynamic form

简明释义

流线型

英英释义

例句

1.The hydrodynamic form 水动力形态 of the fish was studied to understand its swimming efficiency.

研究了鱼的水动力形态 hydrodynamic form，以了解其游泳效率。

2.The research focused on optimizing the hydrodynamic form 水动力形态 of the new boat design to enhance speed and fuel efficiency.

研究集中于优化新船设计的水动力形态 hydrodynamic form，以提高速度和燃油效率。

3.In order to reduce drag, the team modified the hydrodynamic form 水动力形态 of the swimming pool's water return system.

为了减少阻力，团队修改了游泳池水回流系统的水动力形态 hydrodynamic form。

4.Engineers used computational fluid dynamics to analyze the hydrodynamic form 水动力形态 of the underwater vehicle.

工程师利用计算流体动力学分析了水下车辆的水动力形态 hydrodynamic form。

5.A streamlined hydrodynamic form 水动力形态 is crucial for the performance of racing yachts.

流线型的水动力形态 hydrodynamic form 对于赛车游艇的性能至关重要。

作文

The study of fluid dynamics is an essential aspect of engineering and physics, particularly when it comes to understanding how objects interact with fluids. One crucial concept within this field is the hydrodynamic form, which refers to the shape of an object that allows it to move efficiently through a fluid, such as water or air. This form plays a significant role in various applications, from designing ships and submarines to optimizing the aerodynamics of vehicles and aircraft.To fully grasp the importance of hydrodynamic form, we must first consider the principles of fluid dynamics. When an object moves through a fluid, it displaces the fluid around it, creating pressure differences that can either aid or hinder its movement. The hydrodynamic form of an object influences these pressure differences and, consequently, its drag and lift forces. For instance, a streamlined shape minimizes resistance and allows for smoother passage through the fluid, while a blunt shape tends to create turbulence and increased drag.In naval architecture, the design of ships heavily relies on achieving an optimal hydrodynamic form. Engineers use advanced computer simulations and wind tunnel testing to analyze how different shapes perform in water. A well-designed hull can improve fuel efficiency, increase speed, and enhance stability. For example, modern racing yachts are crafted with sleek lines and pointed bows, allowing them to slice through water with minimal resistance. This emphasis on hydrodynamic form not only improves performance but also contributes to sustainability by reducing fuel consumption.Similarly, in the aviation industry, the hydrodynamic form translates to aerodynamic design. Aircraft are meticulously designed to minimize drag and maximize lift, ensuring they can fly efficiently and safely. The wings of an airplane, for instance, are shaped to create lift while maintaining a streamlined profile that reduces air resistance. The principles governing hydrodynamic form are applied to optimize the overall performance of the aircraft, enhancing speed and fuel efficiency.Moreover, the relevance of hydrodynamic form extends beyond traditional transportation. In sports, athletes often utilize designs that embrace these principles to enhance their performance. Swimmers wear specially designed suits that reduce drag in the water, while cyclists use aerodynamic helmets and bike frames to minimize air resistance. These innovations showcase how understanding hydrodynamic form can lead to significant improvements in competitive settings.In conclusion, the concept of hydrodynamic form is fundamental to various fields, including engineering, aviation, and sports. It encompasses the design principles that enable objects to navigate through fluids efficiently, directly impacting performance and energy consumption. As technology continues to evolve, the pursuit of optimizing hydrodynamic form will remain a critical focus, driving innovation and sustainability across multiple industries. Understanding and applying these principles will not only enhance our current capabilities but also pave the way for future advancements in fluid dynamics.

流体动力学的研究是工程和物理学中的一个重要方面，特别是在理解物体如何与流体相互作用时。这个领域内的一个关键概念是hydrodynamic form（流体动力形态），它指的是一种物体的形状，使其能够在流体中高效移动，这种流体可以是水或空气。这种形态在各种应用中发挥着重要作用，从船舶和潜艇的设计到优化车辆和飞机的气动性能。要充分理解hydrodynamic form的重要性，我们首先必须考虑流体动力学的原理。当一个物体在流体中移动时，它会排开周围的流体，产生压力差，这可能有助于或阻碍其运动。物体的hydrodynamic form影响这些压力差，因此也影响其阻力和升力。例如，流线型的形状最小化了阻力，使物体能够更平稳地通过流体，而钝形的形状则往往会产生湍流和增加阻力。在海洋建筑学中，船舶的设计在很大程度上依赖于实现最佳的hydrodynamic form。工程师使用先进的计算机模拟和风洞测试来分析不同形状在水中的表现。一个设计良好的船体可以改善燃油效率，提高速度，并增强稳定性。例如，现代赛车帆船的设计采用流线型的线条和尖锐的船头，使其能够以最小的阻力划过水面。这种对hydrodynamic form的重视不仅提高了性能，还通过减少燃料消耗为可持续发展做出了贡献。类似地，在航空工业中，hydrodynamic form转化为气动设计。飞机经过精心设计，以最小化阻力并最大化升力，确保它们能够高效安全地飞行。例如，飞机的机翼被设计成在创造升力的同时保持流线型轮廓，从而减少空气阻力。支配hydrodynamic form的原理被应用于优化飞机的整体性能，提高速度和燃油效率。此外，hydrodynamic form的相关性超越了传统交通运输。在体育中，运动员经常利用这些原则的设计来提升他们的表现。游泳运动员穿着专门设计的泳衣，以减少水中的阻力，而自行车手则使用气动头盔和自行车框架，以最小化空气阻力。这些创新展示了理解hydrodynamic form如何在竞争环境中带来显著的改进。总之，hydrodynamic form的概念对于多个领域至关重要，包括工程、航空和体育。它包含了使物体能够高效穿越流体的设计原则，直接影响性能和能量消耗。随着技术的不断发展，优化hydrodynamic form的追求将仍然是一个关键焦点，推动多个行业的创新和可持续发展。理解和应用这些原则不仅会增强我们当前的能力，还有望为流体动力学的未来进步铺平道路。