steerable nozzle with rudder

简明释义

带舵转动导管

英英释义

例句

1.The new fighter jet features a steerable nozzle with rudder, allowing for enhanced maneuverability during aerial combat.

这款新型战斗机配备了可转向喷嘴和舵，在空战中实现了更好的机动性。

2.Engineers designed a steerable nozzle with rudder for the drone to allow it to perform complex flight patterns.

工程师为无人机设计了一个可转向喷嘴和舵，使其能够执行复杂的飞行模式。

3.In the recent test, the submarine was equipped with a steerable nozzle with rudder to improve its navigation capabilities underwater.

在最近的测试中，这艘潜艇配备了可转向喷嘴和舵，以提高其水下导航能力。

4.The rocket's steerable nozzle with rudder provides precise control during atmospheric re-entry.

火箭的可转向喷嘴和舵在大气再入过程中提供了精确的控制。

5.Using a steerable nozzle with rudder has significantly improved the agility of our marine vehicles.

使用可转向喷嘴和舵显著提高了我们海洋车辆的灵活性。

作文

In the realm of aerospace engineering, the term steerable nozzle with rudder refers to a sophisticated mechanism that enhances the maneuverability of aircraft and spacecraft. This technology is crucial for improving flight control and stability, allowing pilots to navigate complex aerial environments with precision. The steerable nozzle with rudder system operates by directing the thrust produced by the engines in various directions, which can significantly influence the aircraft's trajectory. The concept of a steerable nozzle with rudder integrates both aerodynamic principles and advanced engineering design. Traditional nozzles typically expel exhaust gases in a fixed direction, limiting the ability to change course rapidly. However, with the introduction of steerable nozzles, engineers have developed a way to pivot the nozzle itself, thereby redirecting thrust. When combined with a rudder, which is a surface used to steer the vehicle, the effectiveness of this system is greatly enhanced. One of the most notable applications of the steerable nozzle with rudder is in military jets and advanced fighter aircraft. These planes require exceptional agility and responsiveness to evade enemy threats and execute complex maneuvers. By utilizing a steerable nozzle with rudder, pilots can perform sharp turns and rapid ascents or descents that would be impossible with conventional nozzle designs. This capability not only increases the aircraft’s combat effectiveness but also improves the safety of the pilots during high-stakes missions.Moreover, the steerable nozzle with rudder has implications beyond military usage. Commercial aviation can also benefit from this technology, particularly in enhancing fuel efficiency and reducing emissions. By optimizing the direction of thrust, airlines can achieve smoother flights with less turbulence, leading to a more comfortable experience for passengers. Furthermore, the ability to control the aircraft more precisely can lead to shorter travel times, as planes can take more direct routes without compromising safety.In the context of space exploration, the steerable nozzle with rudder plays an essential role in spacecraft navigation. When launching or landing on other celestial bodies, precise control over the vehicle's orientation and trajectory is vital. The flexibility offered by a steerable nozzle with rudder allows spacecraft to adjust their paths efficiently, ensuring successful missions to destinations such as Mars or the Moon. As space agencies continue to push the boundaries of exploration, technologies like these will become increasingly important.In conclusion, the steerable nozzle with rudder represents a significant advancement in the field of aerodynamics and propulsion systems. Its ability to enhance maneuverability, improve flight efficiency, and contribute to safety makes it a valuable asset in both military and civilian aviation, as well as in space exploration. As technology continues to evolve, we can expect further innovations in this area, leading to even more sophisticated aerial and space vehicles. Understanding the mechanics and applications of the steerable nozzle with rudder is crucial for anyone interested in the future of flight and space travel.

在航空航天工程领域，术语可转向喷嘴与舵指的是一种复杂的机制，它增强了飞机和航天器的机动性。这项技术对于提高飞行控制和稳定性至关重要，使飞行员能够精确地导航复杂的空中环境。可转向喷嘴与舵系统通过将发动机产生的推力朝不同方向引导，显著影响飞机的轨迹。可转向喷嘴与舵的概念融合了空气动力学原理和先进的工程设计。传统喷嘴通常以固定方向排放废气，限制了快速改变航向的能力。然而，通过引入可转向喷嘴，工程师们开发了一种旋转喷嘴本身的方法，从而重定向推力。当与舵结合时，作为用于驾驶车辆的表面，这一系统的有效性得到了极大的增强。可转向喷嘴与舵最显著的应用之一是在军用喷气机和先进的战斗机中。这些飞机需要卓越的灵活性和响应能力，以躲避敌方威胁并执行复杂的机动。通过利用可转向喷嘴与舵，飞行员可以进行急转弯和快速上升或下降，这在传统喷嘴设计中是无法实现的。这种能力不仅提高了飞机的作战有效性，还在高风险任务中提高了飞行员的安全性。此外，可转向喷嘴与舵在商业航空中也有应用，特别是在提高燃油效率和减少排放方面。通过优化推力的方向，航空公司可以实现更平稳的飞行，减少颠簸，为乘客提供更舒适的体验。此外，更精确的飞机控制能力可以缩短旅行时间，因为飞机可以在不妨碍安全的情况下采取更直接的航线。在太空探索的背景下，可转向喷嘴与舵在航天器导航中发挥着至关重要的作用。在其他天体上发射或着陆时，对飞行器的方向和轨迹进行精确控制至关重要。由可转向喷嘴与舵提供的灵活性使航天器能够高效地调整路径，确保成功完成前往火星或月球等目的地的任务。随着航天机构不断推动探索的边界，这些技术将变得越来越重要。总之，可转向喷嘴与舵代表了空气动力学和推进系统领域的重要进展。它增强机动性、提高飞行效率并有助于安全的能力，使其成为军用和民用航空以及太空探索中的宝贵资产。随着技术的不断发展，我们可以期待这一领域的进一步创新，导致更加复杂的空中和太空飞行器。理解可转向喷嘴与舵的机制和应用对于任何对未来飞行和太空旅行感兴趣的人来说都是至关重要的。