aerodynamic influence

简明释义

气动力影响

英英释义

例句

1.The design of the car was heavily influenced by aerodynamic influence 空气动力学影响, which improved its fuel efficiency.

这辆车的设计受到空气动力学影响的重大影响，从而提高了其燃油效率。

2.Engineers studied the aerodynamic influence 空气动力学影响 on the wings to enhance flight performance.

工程师们研究了机翼上的空气动力学影响以增强飞行性能。

3.The aerodynamic influence 空气动力学影响 of the new bicycle frame reduced drag significantly.

新自行车框架的空气动力学影响显著降低了阻力。

4.To achieve better speed, the athlete considered the aerodynamic influence 空气动力学影响 of their racing suit.

为了达到更好的速度，运动员考虑了他们比赛服的空气动力学影响。

5.The research focused on the aerodynamic influence 空气动力学影响 of different car shapes in a wind tunnel.

研究集中在风洞中不同汽车形状的空气动力学影响。

作文

The concept of aerodynamic influence is crucial in the field of aerodynamics, which studies the behavior of air as it interacts with solid objects. This influence is particularly significant in the design and performance of vehicles, aircraft, and even buildings. Understanding how aerodynamic influence affects these structures can lead to improvements in efficiency, safety, and overall functionality.In aviation, for instance, the shape of an aircraft is meticulously designed to minimize drag and maximize lift. The aerodynamic influence on an aircraft’s wings determines how well it can ascend into the sky or maintain its flight path. Engineers use computer simulations and wind tunnel testing to analyze the aerodynamic influence on various wing shapes and configurations. This process helps in identifying the optimal design that allows the aircraft to perform efficiently while consuming less fuel.Similarly, in the automotive industry, manufacturers are increasingly aware of the importance of aerodynamic influence. Cars designed with sleek, low-profile shapes experience less air resistance, which not only improves fuel efficiency but also enhances stability at high speeds. For example, sports cars often feature designs that maximize their aerodynamic influence, allowing them to cut through the air more effectively than traditional vehicles. This has led to a significant shift in how car designs are approached, with engineers focusing on both aesthetics and performance driven by aerodynamic influence.Buildings, too, are affected by aerodynamic influence. Architects consider how wind flows around structures when designing skyscrapers and other tall buildings. A building with poor aerodynamic design can experience excessive wind loads, leading to structural damage or discomfort for occupants. By understanding the aerodynamic influence of wind patterns, architects can create designs that not only withstand harsh weather conditions but also enhance energy efficiency by reducing heating and cooling costs.The implications of aerodynamic influence extend beyond just engineering and design; they also have environmental impacts. By optimizing the aerodynamic properties of vehicles and buildings, we can reduce fuel consumption and greenhouse gas emissions. This is especially important in the context of climate change, where every effort to improve efficiency can contribute to a more sustainable future.Moreover, advancements in technology continue to enhance our understanding of aerodynamic influence. With the rise of computational fluid dynamics (CFD), engineers can simulate airflow around objects with incredible accuracy. This allows for rapid prototyping and testing of new designs without the need for extensive physical models. As we move forward, the integration of artificial intelligence and machine learning into aerodynamic studies will likely yield even more insights into how aerodynamic influence can be harnessed for better design.In conclusion, aerodynamic influence plays a vital role in various fields, from aviation to automotive design and architecture. By comprehensively understanding this concept, we can create more efficient, safe, and environmentally friendly structures and vehicles. The continuous exploration of aerodynamic influence not only drives innovation but also contributes to a sustainable future, making it an essential area of study for engineers and designers alike.

“气动影响”的概念在气动学领域至关重要，气动学研究空气与固体物体相互作用时的行为。这种影响在车辆、飞机甚至建筑物的设计和性能中尤为显著。理解“气动影响”如何影响这些结构，可以提高效率、安全性和整体功能。例如，在航空领域，飞机的形状经过精心设计，以最小化阻力并最大化升力。“气动影响”对飞机机翼的影响决定了它在空中上升或保持飞行路径的能力。工程师使用计算机模拟和风洞测试来分析各种机翼形状和配置的“气动影响”。这一过程有助于识别出允许飞机高效飞行而消耗更少燃料的最佳设计。同样，在汽车工业中，制造商越来越意识到“气动影响”的重要性。设计流线型、低轮廓形状的汽车会经历更少的空气阻力，这不仅提高了燃油效率，还增强了高速行驶时的稳定性。例如，运动型汽车通常采用最大化其“气动影响”的设计，使其能够比传统车辆更有效地切割空气。这导致了对汽车设计方法的重大转变，工程师们开始关注由“气动影响”驱动的美学和性能。建筑物也受到“气动影响”的影响。建筑师在设计摩天大楼和其他高层建筑时，会考虑风如何在结构周围流动。设计不良的建筑可能会经历过大的风载荷，导致结构损坏或给住户带来不适。通过理解风模式的“气动影响”，建筑师可以创造出不仅能够承受恶劣天气条件的设计，还能通过减少供暖和制冷成本来提高能源效率。“气动影响”的影响不仅限于工程和设计，它们还具有环境影响。通过优化车辆和建筑的气动特性，我们可以减少燃料消耗和温室气体排放。这在气候变化的背景下尤其重要，因为每一项提高效率的努力都可以为更可持续的未来做出贡献。此外，技术的进步继续增强我们对“气动影响”的理解。随着计算流体动力学（CFD）的兴起，工程师可以以惊人的准确性模拟物体周围的气流。这使得新设计的快速原型制作和测试成为可能，而无需大量的物理模型。随着我们向前发展，人工智能和机器学习在气动研究中的整合可能会进一步揭示如何利用“气动影响”进行更好的设计。总之，“气动影响”在航空、汽车设计和建筑等多个领域发挥着至关重要的作用。通过全面理解这一概念，我们可以创造出更高效、安全和环保的结构和车辆。对“气动影响”的持续探索不仅推动了创新，还为可持续未来做出了贡献，使其成为工程师和设计师必不可少的研究领域。