course trim control
简明释义
航向微调控制
英英释义
例句
1.The course trim control helps reduce pilot workload by allowing the aircraft to fly level without constant input.
航向修整控制通过允许飞机在不需要持续输入的情况下平飞,帮助减轻飞行员的工作负担。
2.The pilot adjusted the course trim control to stabilize the aircraft during turbulence.
飞行员调整了航向修整控制以在颠簸期间稳定飞机。
3.During the flight, the co-pilot frequently monitored the course trim control for any necessary adjustments.
在飞行过程中,副驾驶经常监控航向修整控制以进行必要的调整。
4.Before takeoff, the crew checked the course trim control to ensure optimal flight performance.
在起飞前,机组人员检查了航向修整控制以确保最佳飞行性能。
5.Using the course trim control, the captain was able to maintain a straight path over the ocean.
通过使用航向修整控制,机长能够在海洋上保持直线路径。
作文
In the world of aviation, understanding the nuances of flight control is essential for both pilots and engineers. One critical aspect of this control system is known as course trim control, which plays a significant role in maintaining the aircraft's stability and efficiency during flight. The concept of course trim control refers to the adjustments made to the aircraft's control surfaces to ensure that it maintains a desired flight path without excessive pilot input. This is particularly important during long flights, where fatigue can set in, making it difficult for pilots to maintain constant manual control.The primary function of course trim control is to alleviate the need for continuous pressure on the control yoke or stick. By adjusting the trim, pilots can set the aircraft to fly straight and level with minimal effort. This is achieved through the use of trim tabs located on the ailerons, elevator, and rudder. When a pilot makes a trim adjustment, they are essentially changing the aerodynamic forces acting on these control surfaces, allowing the aircraft to maintain its course more efficiently.For instance, if an aircraft is climbing and the pilot notices that it tends to pitch up excessively, they can adjust the elevator trim to counteract this tendency. By doing so, the aircraft will require less back pressure on the control yoke, thus reducing pilot workload. This is especially beneficial during long-haul flights, where maintaining focus and minimizing fatigue is crucial for safety.Moreover, course trim control is not only vital for pilot comfort but also for fuel efficiency. An aircraft that is well-trimmed will fly more efficiently, requiring less engine power to maintain altitude and speed. This translates into lower fuel consumption, which is a significant factor in modern aviation, especially given the rising costs of fuel and the growing emphasis on environmental sustainability.In addition to traditional aircraft, the principles of course trim control are also applicable to drones and other unmanned aerial vehicles (UAVs). These systems utilize sophisticated algorithms to automatically adjust trim settings based on real-time data from various sensors. This automation allows UAVs to maintain stable flight paths even in changing conditions, showcasing the evolution of flight control technology.However, despite the advancements in technology, pilots must still have a solid understanding of course trim control and how to apply it effectively. Training programs emphasize the importance of recognizing when to make trim adjustments and understanding the aircraft's behavior in response to these changes. A well-trained pilot can use course trim control to enhance their flying experience and improve overall safety.In conclusion, course trim control is a fundamental aspect of flight management that significantly impacts pilot workload, fuel efficiency, and overall aircraft performance. As aviation technology continues to advance, the principles behind course trim control remain relevant and critical for both traditional and modern flight operations. Understanding and mastering this concept is essential for anyone involved in aviation, ensuring safer and more efficient flights in the skies.
在航空领域,理解飞行控制的细微差别对于飞行员和工程师都是至关重要的。一个关键的方面被称为航向修整控制,它在维持飞机的稳定性和飞行效率方面发挥着重要作用。航向修整控制的概念是指对飞机控制面进行的调整,以确保其在没有过多飞行员输入的情况下保持所需的飞行路径。这在长途飞行中尤为重要,因为疲劳可能会影响飞行员持续手动控制的能力。航向修整控制的主要功能是减轻对控制杆或操纵杆持续施加压力的需要。通过调整修整,飞行员可以设置飞机以最小的努力飞行直线并保持水平。这是通过位于副翼、升降舵和方向舵上的修整舵面来实现的。当飞行员进行修整调整时,他们实际上是在改变作用于这些控制面的气动力,从而使飞机更有效地保持航向。例如,如果一架飞机正在爬升,飞行员注意到它倾向于过度俯仰,他们可以调整升降舵修整来抵消这种趋势。通过这样做,飞机将需要更少的后压在控制杆上,从而减少飞行员的工作负担。这在长途飞行中尤其有利,因为保持专注和减少疲劳对于安全至关重要。此外,航向修整控制不仅对飞行员的舒适性至关重要,而且对燃油效率也至关重要。一架良好修整的飞机将更高效地飞行,维持高度和速度所需的发动机功率更少。这转化为较低的燃油消耗,这在现代航空中是一个重要因素,特别是在燃油成本上升和对环境可持续性日益重视的背景下。除了传统飞机外,航向修整控制的原理同样适用于无人机和其他无人飞行器(UAV)。这些系统利用复杂的算法根据来自各种传感器的实时数据自动调整修整设置。这种自动化使无人机能够在变化的条件下保持稳定的飞行路径,展示了飞行控制技术的演变。然而,尽管技术不断进步,飞行员仍然必须对航向修整控制有扎实的理解,并能有效应用。培训项目强调识别何时进行修整调整的重要性,以及理解飞机对这些变化的反应行为。一名训练有素的飞行员可以利用航向修整控制来增强飞行体验,提高整体安全性。总之,航向修整控制是飞行管理的基本方面,对飞行员工作负担、燃油效率和整体飞机性能产生重大影响。随着航空技术的不断进步,航向修整控制背后的原理仍然相关且对传统和现代飞行操作至关重要。理解和掌握这一概念对于任何参与航空的人来说都是必不可少的,确保在空中更加安全和高效的飞行。
