wing suction

简明释义

舷边进水管

英英释义

例句

1.Pilots must understand how wing suction (翼吸力) affects their aircraft's performance during maneuvers.

飞行员必须了解wing suction (翼吸力)如何影响飞机在机动中的表现。

2.During takeoff, the wing suction (翼吸力) helps the airplane gain altitude quickly.

在起飞过程中，wing suction (翼吸力)帮助飞机快速升高。

3.The research focused on optimizing wing suction (翼吸力) to improve the overall aerodynamic efficiency.

这项研究集中于优化wing suction (翼吸力)以改善整体气动效率。

4.Engineers are studying the effects of wing suction (翼吸力) on fuel efficiency in modern jets.

工程师们正在研究wing suction (翼吸力)对现代喷气式飞机燃油效率的影响。

5.The design of the aircraft's wings incorporates wing suction (翼吸力) to enhance lift during flight.

飞机机翼的设计结合了wing suction (翼吸力)以增强飞行中的升力。

作文

The concept of wing suction plays a crucial role in the field of aerodynamics and aviation. Understanding this phenomenon is essential for designing efficient aircraft and improving their performance. Wing suction refers to the aerodynamic force that occurs when air flows over the wings of an aircraft. As the wings move through the air, they create a difference in air pressure above and below the wing surface. This difference in pressure generates lift, allowing the aircraft to ascend and remain airborne.To grasp the significance of wing suction, it is important to consider how lift is generated. When an aircraft's wing is designed with a specific shape, known as an airfoil, it helps to manipulate airflow. The upper surface of the wing is typically curved, while the lower surface is flatter. As air flows over the wing, it travels faster over the curved upper surface than it does over the flatter lower surface. According to Bernoulli's principle, faster-moving air results in lower pressure. Consequently, the pressure above the wing decreases, creating a suction effect that pulls the wing upwards.This wing suction effect is not only vital for takeoff and flight but also for maneuverability and stability during various phases of flight. Pilots rely on the principles of wing suction to perform turns, climbs, and descents. A thorough understanding of how this suction works enables engineers to design wings that maximize lift while minimizing drag, ultimately leading to more fuel-efficient and high-performing aircraft.In recent years, advancements in technology have allowed for more precise calculations and simulations of wing suction. Computational fluid dynamics (CFD) has revolutionized the way engineers analyze airflow around wings. By simulating different wing designs and angles of attack, engineers can identify the optimal configurations that enhance wing suction and overall aircraft performance. This not only improves safety but also contributes to environmental sustainability by reducing fuel consumption.Moreover, the study of wing suction extends beyond traditional fixed-wing aircraft. Unmanned aerial vehicles (UAVs) and drones also benefit from understanding this aerodynamic principle. As these technologies continue to evolve, the need for efficient wing suction becomes increasingly important for applications ranging from aerial photography to delivery services.In conclusion, wing suction is a fundamental concept in aerodynamics that underpins the principles of flight. Its implications reach far beyond the realm of aviation, influencing the design and operation of various flying vehicles. As we advance in our understanding of wing suction, we pave the way for innovations that can transform the future of air travel and contribute to a more sustainable world. The importance of mastering this concept cannot be overstated, as it is integral to both current and future developments in aerospace engineering.

“翼吸力”这一概念在空气动力学和航空领域中发挥着至关重要的作用。理解这一现象对于设计高效的飞机和提高其性能至关重要。“翼吸力”是指当空气流过飞机的机翼时所产生的空气动力学力。当机翼穿过空气时，它在机翼表面上方和下方产生了气压差。这种气压差产生了升力，使飞机能够上升并保持在空中。要理解“翼吸力”的重要性，考虑升力是如何产生的非常重要。当飞机的机翼设计成特定形状，即气动外形时，它有助于操控气流。机翼的上表面通常是弯曲的，而下表面则较平坦。当空气流过机翼时，它在弯曲的上表面上流动得比在较平坦的下表面上流动得更快。根据伯努利原理，流动速度越快，气压就越低。因此，机翼上方的压力降低，产生一种吸力效果，将机翼向上拉。这种“翼吸力”效应不仅对起飞和飞行至关重要，而且对飞行的各个阶段中的机动性和稳定性也至关重要。飞行员依赖于“翼吸力”的原理来进行转弯、爬升和下降。深入理解这种吸力的工作原理使工程师能够设计出最大化升力同时最小化阻力的机翼，从而最终导致更节能和高性能的飞机。近年来，技术的进步使得对“翼吸力”的计算和模拟更加精确。计算流体动力学（CFD）彻底改变了工程师分析机翼周围气流的方式。通过模拟不同的机翼设计和攻角，工程师可以识别出增强“翼吸力”和整体飞机性能的最佳配置。这不仅提高了安全性，还通过减少燃料消耗促进了环境可持续性。此外，“翼吸力”的研究不仅限于传统的固定翼飞机。无人机（UAV）和无人驾驶飞行器也受益于对这一空气动力学原理的理解。随着这些技术的不断发展，优化“翼吸力”的需要在从航拍到快递服务等应用中变得越来越重要。总之，“翼吸力”是空气动力学中的一个基本概念，它支撑着飞行原理。它的影响远不止航空领域，影响着各种飞行器的设计和操作。随着我们对“翼吸力”的理解不断深入，我们为创新铺平了道路，这些创新可以改变未来的航空旅行，并为创建一个更可持续的世界做出贡献。掌握这一概念的重要性不言而喻，因为它对于当前和未来的航空航天工程发展至关重要。