turning speed

简明释义

回转速度

英英释义

例句

1.The boat's turning speed 转弯速度 was too slow for the tight channel, risking capsizing.

船的转弯速度 turning speed 对于狭窄的水道来说太慢，存在倾覆的风险。

2.In racing, a higher turning speed 转弯速度 can provide a competitive edge on the track.

在赛车中，更高的转弯速度 turning speed 可以为赛道上的竞争提供优势。

3.The car's turning speed 转弯速度 is impressive, allowing it to navigate sharp corners with ease.

这辆车的转弯速度 turning speed 令人印象深刻，使其能够轻松地通过急转弯。

4.Pilots must be aware of the aircraft's turning speed 转弯速度 to maintain control during maneuvers.

飞行员必须注意飞机的转弯速度 turning speed 以保持在机动中的控制。

5.Adjusting the turning speed 转弯速度 of the drone can help it make precise movements.

调整无人机的转弯速度 turning speed 可以帮助它进行精确的移动。

作文

In the world of engineering and mechanics, the term turning speed refers to the rate at which an object, typically a rotating body, can change its direction or orientation while in motion. This concept is crucial in various fields, including automotive design, aerospace engineering, and even robotics. Understanding turning speed allows engineers to optimize performance and safety in their designs. For instance, in the automotive industry, the turning speed of a vehicle plays a significant role in its handling characteristics. A car with a high turning speed can navigate sharp corners more effectively, providing a thrilling driving experience while also ensuring the safety of its passengers. Engineers must consider factors such as weight distribution, tire grip, and suspension design to achieve the desired turning speed. If these elements are not balanced correctly, the vehicle may experience understeer or oversteer, leading to potential accidents. Similarly, in aerospace engineering, aircraft must have an optimal turning speed to ensure stability during flight maneuvers. Pilots need to understand how to manage the turning speed of their aircraft to maintain control and prevent stalling. The design of wings, fuselage, and control surfaces all play a part in determining the effective turning speed of an aircraft. Engineers conduct extensive simulations and tests to find the best configurations that allow pilots to perform complex aerial maneuvers safely. Robotics is another area where turning speed is vital. Robots, especially those designed for tasks that require agility, must be able to turn quickly and efficiently. This is particularly important in fields like manufacturing and logistics, where robots are often required to navigate tight spaces and avoid obstacles. The turning speed of a robot can affect its productivity and effectiveness in completing tasks. Engineers must design robotic systems that can adjust their turning speed based on the environment and task requirements, ensuring optimal performance. Moreover, understanding turning speed extends beyond mechanical applications. In the realm of sports, athletes often need to master their turning speed to excel in their respective disciplines. For example, a sprinter must learn how to maintain speed while turning around a curve, as this can significantly impact their overall performance in races. Coaches and trainers focus on developing techniques that enhance an athlete’s ability to control their turning speed, allowing them to gain a competitive edge. In conclusion, the concept of turning speed is essential across various fields, from engineering to athletics. It encompasses the ability to change direction effectively while maintaining control and stability. By understanding and optimizing turning speed, professionals can improve safety, performance, and efficiency in their respective domains. Whether it’s designing a high-performance vehicle, piloting an aircraft, programming a robot, or coaching an athlete, the principles of turning speed play a critical role in achieving success.

在工程和机械领域，术语转向速度指的是一个物体（通常是旋转体）在运动中改变方向或朝向的速率。这个概念在多个领域中至关重要，包括汽车设计、航空航天工程，甚至机器人技术。理解转向速度使工程师能够优化他们设计中的性能和安全性。例如，在汽车工业中，车辆的转向速度在其操控特性中扮演着重要角色。一辆具有高转向速度的汽车可以更有效地通过急弯，提供令人兴奋的驾驶体验，同时确保乘客的安全。工程师必须考虑重量分布、轮胎抓地力和悬挂设计等因素，以达到所需的转向速度。如果这些元素没有正确平衡，车辆可能会出现推头或甩尾，从而导致潜在的事故。同样，在航空航天工程中，飞机必须具有最佳的转向速度以确保在飞行机动中的稳定性。飞行员需要了解如何管理飞机的转向速度以保持控制并防止失速。机翼、机身和控制面板的设计都对飞机的有效转向速度产生影响。工程师进行广泛的模拟和测试，以找到最佳配置，使飞行员能够安全执行复杂的空中机动。机器人技术是另一个转向速度至关重要的领域。特别是那些被设计用于需要灵活性的任务的机器人，必须能够快速高效地转向。这在制造和物流等领域尤为重要，因为机器人通常需要在狭小的空间内导航并避免障碍物。机器人的转向速度可能会影响其生产力和完成任务的有效性。工程师必须设计可以根据环境和任务要求调整其转向速度的机器人系统，以确保最佳性能。此外，理解转向速度超越了机械应用。在体育领域，运动员往往需要掌握他们的转向速度才能在各自的项目中表现出色。例如，短跑运动员必须学习如何在转弯时保持速度，因为这可能会显著影响他们在比赛中的整体表现。教练和训练师专注于发展提升运动员控制其转向速度能力的技巧，使他们获得竞争优势。总之，转向速度的概念在各个领域中都是必不可少的，从工程到体育。它涵盖了在保持控制和稳定的同时有效改变方向的能力。通过理解和优化转向速度，专业人士可以提高各自领域的安全性、性能和效率。无论是设计高性能车辆、驾驶飞机、编程机器人，还是训练运动员，转向速度的原则在实现成功中都扮演着关键角色。