rate of turn

简明释义

匝数比

英英释义

例句

1.In racing, the rate of turn (转弯速率) is crucial for maintaining speed through corners.

在赛车中，转弯速率对于在弯道中保持速度至关重要。

2.The engineer calculated the rate of turn (转弯速率) needed for the new roller coaster design.

工程师计算了新过山车设计所需的转弯速率。

3.The pilot adjusted the aircraft's controls to increase the rate of turn (转弯速率) for a smoother maneuver.

飞行员调整了飞机的控制，以增加<取>转弯速率，以实现更平稳的操作。

4.During the flight simulation, we monitored the rate of turn (转弯速率) to ensure safety.

在飞行模拟中，我们监控了转弯速率以确保安全。

5.A higher rate of turn (转弯速率) can lead to increased G-forces on the passengers.

更高的转弯速率可能会导致乘客承受更大的离心力。

作文

The concept of rate of turn is crucial in various fields, particularly in aviation and maritime navigation. Understanding this term can significantly enhance our comprehension of how vehicles maneuver through different environments. The rate of turn refers to the angular change in position over time, typically measured in degrees per second. This measurement is essential for pilots and captains as it helps them determine how quickly they can change their direction without compromising safety or efficiency.In aviation, for instance, a pilot must be aware of the rate of turn when making sharp maneuvers during takeoff or landing. A high rate of turn can lead to increased G-forces on the aircraft, which may affect both the structural integrity of the plane and the comfort of the passengers. Therefore, pilots are trained to calculate and manage their rate of turn to ensure smooth and safe transitions. Additionally, understanding the rate of turn allows pilots to maintain proper flight paths and avoid potential collisions with other aircraft.Similarly, in maritime contexts, the rate of turn is vital for navigating through tight channels or during docking procedures. A ship’s captain must consider the vessel's size and the surrounding environment when determining an appropriate rate of turn. If the rate of turn is too high, the ship may not have enough time to respond to navigational hazards or changes in water currents, leading to dangerous situations. Thus, maritime training includes extensive practice on how to control the rate of turn effectively.Moreover, the rate of turn is not only limited to transportation but also applies to various mechanical systems. For example, in robotics, the rate of turn is a critical factor in programming autonomous vehicles. Engineers must calculate the optimal rate of turn to ensure that robots can navigate their environments efficiently while avoiding obstacles. This aspect of robotics emphasizes the importance of precise calculations and real-time adjustments to achieve the desired movement.Furthermore, in the field of sports, particularly in racing, athletes must understand the rate of turn to optimize their performance. Whether it’s a cyclist navigating a sharp bend or a race car driver taking a corner at high speed, knowing how to manage the rate of turn can mean the difference between winning and losing. Athletes often train to improve their skills in handling turns, focusing on maintaining speed while ensuring stability and control.In conclusion, the rate of turn is a multifaceted concept with applications across various domains, including aviation, maritime navigation, robotics, and sports. By mastering the rate of turn, professionals in these fields can enhance their performance, ensure safety, and improve overall efficiency. Understanding this term not only aids in practical applications but also enriches our knowledge of how different systems interact and function in dynamic environments. As we continue to advance technologically, the significance of the rate of turn will undoubtedly remain a vital component in the design and operation of vehicles and machinery.

“转向速率”这个概念在多个领域中至关重要，尤其是在航空和海洋导航方面。理解这个术语可以显著增强我们对车辆如何在不同环境中机动的理解。“转向速率”指的是单位时间内位置的角度变化，通常以每秒度数来衡量。这个测量对于飞行员和船长来说至关重要，因为它帮助他们确定在不妨碍安全或效率的情况下，可以多快改变方向。例如，在航空领域，飞行员在起飞或降落过程中进行急转弯时，必须了解“转向速率”。较高的“转向速率”可能会导致飞机上增加的G力，这可能影响飞机的结构完整性和乘客的舒适度。因此，飞行员经过培训以计算和管理他们的“转向速率”，以确保平稳和安全的过渡。此外，了解“转向速率”使飞行员能够保持正确的飞行路径，避免与其他飞机的潜在碰撞。同样，在海洋环境中，“转向速率”对于在狭窄水道或停靠程序中的导航至关重要。船长在确定适当的“转向速率”时，必须考虑船只的大小和周围环境。如果“转向速率”过高，船只可能没有足够的时间应对导航危险或水流变化，从而导致危险情况。因此，海事培训包括大量关于如何有效控制“转向速率”的实践。此外，“转向速率”不仅限于交通运输，还适用于各种机械系统。例如，在机器人技术中，“转向速率”是编程自主车辆的关键因素。工程师必须计算最佳的“转向速率”，以确保机器人能够有效地在环境中导航，同时避免障碍物。机器人技术的这一方面强调了精确计算和实时调整以实现所需运动的重要性。此外，在体育领域，特别是在赛车中，运动员必须理解“转向速率”以优化他们的表现。无论是骑自行车的人在急转弯时，还是赛车手以高速通过弯道，知道如何管理“转向速率”可能意味着胜利和失败之间的差异。运动员通常训练以提高他们处理转向的技能，专注于在确保稳定性和控制的同时保持速度。总之，“转向速率”是一个多方面的概念，适用于多个领域，包括航空、海洋导航、机器人技术和体育。通过掌握“转向速率”，这些领域的专业人士可以提升他们的表现，确保安全并提高整体效率。理解这个术语不仅有助于实际应用，还有助于丰富我们对不同系统如何在动态环境中相互作用和运作的知识。随着技术的不断进步，“转向速率”的重要性无疑将继续成为车辆和机械设计与操作中的重要组成部分。