air flow(aerofoil
简明释义
机翼翼型
英英释义
例句
1.To achieve better performance, the air flow (aerofoil) must be carefully analyzed.
为了达到更好的性能,必须仔细分析气流(翼型)。
2.Understanding air flow (aerofoil) helps in improving fuel efficiency in vehicles.
理解气流(翼型)有助于提高车辆的燃油效率。
3.Engineers use software to simulate air flow (aerofoil) patterns during the testing phase.
工程师在测试阶段使用软件模拟气流(翼型)模式。
4.The shape of the air flow (aerofoil) directly affects lift and drag forces.
气流(翼型)的形状直接影响升力和阻力。
5.The design of the wing is crucial for optimizing air flow (aerofoil) around the aircraft.
机翼的设计对于优化飞机周围的气流(翼型)至关重要。
作文
The study of aerodynamics is crucial in understanding how objects move through the air. One of the key concepts in this field is air flow (aerofoil), which refers to the movement of air around a solid object, particularly wings or blades designed to generate lift. The shape of an aerofoil is specifically engineered to manipulate the air flow (aerofoil) in a way that maximizes efficiency and performance. When an aircraft wing is designed, the aerofoil shape is critical. It typically has a curved upper surface and a flatter lower surface. This design causes the air flow (aerofoil) above the wing to travel faster than the air flow (aerofoil) below it, creating a difference in pressure. According to Bernoulli's principle, this pressure difference results in lift, allowing the aircraft to rise into the sky.In addition to aircraft, air flow (aerofoil) principles are also applicable in various fields such as automotive design, wind turbines, and even sports equipment like bicycles and golf balls. For instance, a well-designed bicycle frame can significantly reduce drag by optimizing the air flow (aerofoil) around it, allowing the cyclist to maintain higher speeds with less effort.Understanding air flow (aerofoil) is not limited to just theoretical knowledge; it also involves practical applications. Engineers conduct wind tunnel tests to observe how different aerofoil shapes affect air flow (aerofoil). These tests provide invaluable data that can lead to improvements in design and performance. By analyzing the patterns of air flow (aerofoil), engineers can identify areas where turbulence occurs and make necessary adjustments to enhance stability and efficiency.Moreover, advancements in technology have allowed for more sophisticated simulations of air flow (aerofoil). Computational fluid dynamics (CFD) software enables engineers to model complex air flow (aerofoil) scenarios without the need for extensive physical testing. This not only saves time and resources but also leads to more innovative designs that push the boundaries of what is possible in aerodynamics.In conclusion, the concept of air flow (aerofoil) is fundamental to the field of aerodynamics. Its implications extend beyond aviation, influencing various industries and technologies. By mastering the principles of air flow (aerofoil), engineers and designers can create more efficient and effective systems that harness the power of air to achieve remarkable feats. As we continue to explore the dynamics of air flow (aerofoil), we pave the way for future innovations that will shape our world in ways we can only begin to imagine.
空气动力学的研究对于理解物体如何在空气中移动至关重要。这个领域的一个关键概念是气流(翼型),它指的是空气在固体物体周围的运动,特别是设计用于产生升力的机翼或叶片。翼型的形状专门设计用于操控气流(翼型),以最大化效率和性能。当设计飞机机翼时,翼型的形状是至关重要的。它通常具有弯曲的上表面和较平坦的下表面。这种设计使得翼型上方的气流(翼型)速度比下方的气流(翼型)快,从而造成压力差。根据伯努利原理,这种压力差导致升力,使飞机能够升空。除了航空器,气流(翼型)的原理还适用于汽车设计、风力涡轮机,甚至自行车和高尔夫球等运动器材。例如,一个设计良好的自行车框架可以通过优化周围的气流(翼型)来显著减少阻力,使骑行者以更少的努力维持更高的速度。理解气流(翼型)不仅限于理论知识;它还涉及实际应用。工程师进行风洞测试,以观察不同的翼型形状如何影响气流(翼型)。这些测试提供了宝贵的数据,可以导致设计和性能的改进。通过分析气流(翼型)的模式,工程师可以识别出湍流发生的区域,并做出必要的调整,以增强稳定性和效率。此外,技术的进步使得对气流(翼型)的更复杂的模拟成为可能。计算流体动力学(CFD)软件使工程师能够建模复杂的气流(翼型)场景,而无需进行大量的物理测试。这不仅节省了时间和资源,还导致了更具创新性的设计,推动了空气动力学的边界。总之,气流(翼型)的概念是空气动力学领域的基础。它的影响超越了航空,影响着各个行业和技术。通过掌握气流(翼型)的原理,工程师和设计师可以创造出更高效、更有效的系统,利用空气的力量实现卓越的成就。随着我们继续探索气流(翼型)的动态,我们为未来的创新铺平了道路,这将以我们只能开始想象的方式塑造我们的世界。
