aerodynamic control

简明释义

气动控制

英英释义

例句

1.Implementing effective aerodynamic control can significantly reduce drag.

实施有效的空气动力学控制可以显著减少阻力。

2.The research team is developing new materials to enhance aerodynamic control in high-speed vehicles.

研究小组正在开发新材料，以增强高速车辆的空气动力学控制。

3.The racing car's performance relies heavily on its aerodynamic control features.

赛车的性能在很大程度上依赖于其空气动力学控制特性。

4.Engineers are studying aerodynamic control systems to enhance the stability of drones in flight.

工程师正在研究空气动力学控制系统，以增强无人机飞行中的稳定性。

5.The new aircraft design incorporates advanced aerodynamic control to improve fuel efficiency.

新型飞机设计采用了先进的空气动力学控制以提高燃油效率。

作文

In the world of aviation and automotive engineering, the term aerodynamic control refers to the methods and technologies used to manage the airflow around an object, such as an aircraft or a car, to enhance its performance and stability. Understanding aerodynamic control is crucial for engineers and designers who aim to create vehicles that can efficiently navigate through air and reduce drag, thereby improving fuel efficiency and overall speed. The principles of aerodynamic control are rooted in fluid dynamics, which studies how fluids (liquids and gases) behave and interact with solid objects. When an object moves through the air, it displaces the air around it, creating a complex pattern of pressure and velocity changes. By manipulating these patterns, engineers can influence how the object behaves in flight or on the road. One of the key aspects of aerodynamic control is the design of wings and spoilers on aircraft. For instance, the shape and angle of an aircraft's wings can significantly affect lift and drag. A well-designed wing can produce more lift with less drag, allowing the aircraft to fly more efficiently. Similarly, spoilers can be deployed to disrupt airflow and increase drag, which helps slow the aircraft down during landing. This precise manipulation of airflow is an essential component of aerodynamic control. In automotive engineering, aerodynamic control plays a vital role in enhancing vehicle performance. Sports cars, for example, are designed with sleek shapes and features like rear spoilers to optimize their aerodynamics. These design elements help reduce drag and improve stability at high speeds. Engineers use wind tunnel testing and computer simulations to analyze how air flows around a vehicle, allowing them to make informed decisions about design modifications that can enhance aerodynamic control. Moreover, advancements in technology have led to the development of active aerodynamic systems. These systems can adjust various components of a vehicle or aircraft in real-time based on speed and environmental conditions. For example, some modern sports cars can automatically raise or lower their spoilers to optimize aerodynamic control depending on whether they are accelerating or decelerating. This level of adaptability represents a significant leap forward in the pursuit of optimal aerodynamic performance. In conclusion, aerodynamic control is a fundamental concept in the fields of aviation and automotive engineering. It encompasses the strategies and technologies used to manage airflow around moving objects, ultimately enhancing their performance and efficiency. As technology continues to evolve, the importance of mastering aerodynamic control will only grow, leading to faster, safer, and more efficient vehicles that push the boundaries of what is possible in transportation. Understanding the intricacies of aerodynamic control not only benefits engineers and designers but also contributes to the overall advancement of technology in our increasingly mobile world.

在航空和汽车工程的世界中，术语aerodynamic control指的是用于管理物体（如飞机或汽车）周围气流的方法和技术，以增强其性能和稳定性。理解aerodynamic control对于旨在制造能够有效穿越空气并减少阻力的车辆的工程师和设计师至关重要，从而提高燃油效率和整体速度。aerodynamic control的原理源于流体动力学，它研究流体（液体和气体）如何行为以及如何与固体物体相互作用。当一个物体在空气中移动时，会排开周围的空气，产生复杂的压力和速度变化模式。通过操控这些模式，工程师可以影响物体在飞行或行驶中的表现。aerodynamic control的一个关键方面是飞机的机翼和扰流板的设计。例如，飞机机翼的形状和角度会显著影响升力和阻力。设计良好的机翼可以以更少的阻力产生更多的升力，使飞机能够更高效地飞行。同样，扰流板可以被部署来破坏气流并增加阻力，这有助于在着陆时减速。这种对气流的精确操控是aerodynamic control的基本组成部分。在汽车工程中，aerodynamic control在提高车辆性能方面起着至关重要的作用。例如，跑车的设计采用流线型外形和后扰流板等特征，以优化其空气动力学。这些设计元素有助于减少阻力并提高高速稳定性。工程师使用风洞测试和计算机模拟来分析空气如何在车辆周围流动，从而使他们能够就增强aerodynamic control的设计修改做出明智的决策。此外，技术的进步导致了主动空气动力学系统的发展。这些系统可以根据速度和环境条件实时调整车辆或飞机的各个组件。例如，一些现代跑车可以自动升高或降低其扰流板，以优化aerodynamic control，具体取决于它们是在加速还是减速。这种适应能力的水平代表了在追求最佳空气动力学性能方面的重要飞跃。总之，aerodynamic control是航空和汽车工程领域的基本概念。它包括用于管理移动物体周围气流的策略和技术，最终增强其性能和效率。随着技术的不断发展，掌握aerodynamic control的重要性只会增加，导致更快、更安全和更高效的车辆推动交通运输可能性的边界。理解aerodynamic control的复杂性不仅有利于工程师和设计师，也有助于我们日益移动的世界中技术的整体进步。