jet flap rudder

简明释义

喷射舵

英英释义

例句

1.Engineers conducted simulations to test the performance of the jet flap rudder under various speeds.

工程师进行了模拟测试，以评估喷气襟翼舵在不同速度下的性能。

2.The aircraft's maneuverability improved significantly after the implementation of the jet flap rudder.

在实施喷气襟翼舵后，飞机的机动性显著提高。

3.In adverse weather conditions, the jet flap rudder allowed for more stable flight paths.

在恶劣天气条件下，喷气襟翼舵使飞行路径更加稳定。

4.During the flight test, the pilot noted that the jet flap rudder provided better control during sharp turns.

在飞行测试中，飞行员注意到喷气襟翼舵在急转弯时提供了更好的控制。

5.The design team focused on optimizing the jet flap rudder for enhanced aerodynamic efficiency.

设计团队专注于优化喷气襟翼舵以提高空气动力学效率。

作文

The evolution of aircraft design has been a fascinating journey, marked by numerous innovations that have transformed the way we approach flight. One such innovation is the introduction of the jet flap rudder, a remarkable component that enhances the maneuverability and stability of an aircraft. Understanding the significance of the jet flap rudder requires delving into its function, advantages, and the engineering principles behind it.At its core, the jet flap rudder is designed to improve the aerodynamic efficiency of an aircraft during critical phases of flight, such as takeoff and landing. Traditional rudders operate by redirecting airflow to create a force that changes the aircraft's direction. However, the jet flap rudder employs a different approach by utilizing high-velocity jet streams to augment its effectiveness. This is achieved by directing exhaust from the engines or additional jet nozzles across the rudder surface, which significantly increases the control authority of the rudder at lower speeds.One of the most notable advantages of the jet flap rudder is its ability to provide enhanced directional control during slow-speed operations. This feature is particularly beneficial for larger aircraft, which often face challenges in maintaining stability during takeoff and landing. By generating additional lift and reducing drag, the jet flap rudder allows pilots to execute sharper turns and respond more effectively to sudden changes in flight conditions.Moreover, the implementation of the jet flap rudder can lead to improved safety in aviation. In scenarios where an aircraft experiences a loss of engine power, the enhanced control provided by the jet flap rudder can be crucial for maintaining stability and executing successful emergency landings. The ability to manage yaw and roll with greater precision can make the difference between a safe landing and a potential disaster.From an engineering perspective, the design of the jet flap rudder presents unique challenges and opportunities. Engineers must carefully consider factors such as the placement of jet nozzles, the angle of deflection, and the overall aerodynamic profile of the rudder. Computational fluid dynamics (CFD) simulations play a vital role in optimizing these parameters, allowing engineers to predict how the jet flap rudder will perform under various flight conditions.In conclusion, the jet flap rudder represents a significant advancement in aircraft control technology. Its ability to enhance maneuverability, improve safety, and optimize performance makes it an invaluable component in modern aviation. As we continue to push the boundaries of flight, innovations like the jet flap rudder will undoubtedly play a crucial role in shaping the future of air travel. Understanding this technology not only enriches our knowledge of aviation but also highlights the importance of continuous innovation in ensuring safe and efficient flight operations.

飞机设计的演变是一段引人入胜的旅程，标志着众多创新的出现，这些创新改变了我们对飞行的看法。其中一个创新就是喷气襟翼舵的引入，这一显著的组件增强了飞机的机动性和稳定性。理解喷气襟翼舵的重要性需要深入探讨其功能、优势以及其背后的工程原理。从根本上讲，喷气襟翼舵旨在提高飞机在关键飞行阶段（如起飞和着陆）中的空气动力效率。传统舵面通过重新定向气流来产生改变飞机方向的力。然而，喷气襟翼舵采用了不同的方法，通过利用高速喷流来增强其有效性。这是通过将发动机的排气或额外喷嘴的喷流导向舵面，显著增加了舵面在低速时的控制能力。喷气襟翼舵最显著的优势之一是它在低速操作期间提供增强的方向控制。这一特点对于大型飞机尤其重要，因为它们在起飞和着陆过程中常常面临保持稳定的挑战。通过产生额外的升力和减少阻力，喷气襟翼舵使飞行员能够执行更急促的转弯，并更有效地应对突发的飞行条件变化。此外，实施喷气襟翼舵可以提高航空安全性。在飞机失去发动机动力的情况下，喷气襟翼舵所提供的增强控制对于维持稳定和成功执行紧急着陆至关重要。能够更精确地管理偏航和滚转可能会在安全着陆和潜在灾难之间产生决定性的差异。从工程角度来看，喷气襟翼舵的设计面临独特的挑战与机遇。工程师必须仔细考虑喷嘴的位置、偏转角度以及舵面的整体空气动力轮廓。计算流体动力学（CFD）模拟在优化这些参数方面发挥着至关重要的作用，使工程师能够预测喷气襟翼舵在各种飞行条件下的表现。总之，喷气襟翼舵代表了飞机控制技术的重大进步。其增强机动性、提高安全性和优化性能的能力使其成为现代航空中不可或缺的组成部分。随着我们不断推动飞行的边界，像喷气襟翼舵这样的创新无疑将在塑造航空旅行的未来中发挥重要作用。理解这一技术不仅丰富了我们对航空的认识，还突显了在确保安全高效的飞行操作中持续创新的重要性。