maneuverability trial

简明释义

操纵性试验机动性试验

英英释义

例句

1.A successful maneuverability trial can lead to increased confidence in the product's performance.

成功的机动性试验可以增强对产品性能的信心。

2.During the maneuverability trial, the vehicle demonstrated excellent cornering performance.

在机动性试验中，该车辆展现了出色的转弯性能。

3.The new drone underwent a series of maneuverability trials to assess its flight capabilities.

这款新无人机进行了系列的机动性试验以评估其飞行能力。

4.The military conducted maneuverability trials on the new tank to evaluate its combat readiness.

军方对新坦克进行了机动性试验以评估其作战准备情况。

5.The engineers analyzed the data collected from the maneuverability trials to improve the design.

工程师们分析了从机动性试验中收集的数据，以改进设计。

作文

In the realm of engineering and vehicle design, the term maneuverability trial holds significant importance. A maneuverability trial refers to a series of tests conducted to evaluate how well a vehicle can change direction, speed, and position in various conditions. The effectiveness of this trial is crucial for ensuring that vehicles, whether they are cars, aircraft, or naval vessels, can perform optimally in real-world scenarios. The primary goal of a maneuverability trial is to assess the responsiveness of a vehicle to the driver's or pilot's commands. During these trials, engineers observe how quickly and accurately a vehicle can navigate through obstacles, make sharp turns, and maintain stability at different speeds. For example, a race car must exhibit high levels of maneuverability to navigate tight corners on a track, while a military aircraft must demonstrate agility to evade threats during combat. To conduct a maneuverability trial, specific metrics are established. These may include turning radius, acceleration time, and braking distance. Engineers often use specialized equipment to gather data during these tests, including sensors and cameras that record the vehicle's performance under various conditions. This data is then analyzed to identify any weaknesses in the design or performance of the vehicle. Safety is another critical aspect of maneuverability trials. Vehicles must not only be able to maneuver effectively but also do so without compromising the safety of the occupants and other road users. For instance, during a maneuverability trial for a new SUV, engineers will test its ability to handle sudden stops and emergency maneuvers, ensuring that it can safely avoid potential accidents. Moreover, the results of a maneuverability trial can influence the overall design of a vehicle. If a particular model fails to meet the desired standards of agility and control, engineers may need to revisit the design, making adjustments to the suspension system, weight distribution, or even the engine. This iterative process is essential for developing vehicles that not only perform well but also meet regulatory standards and consumer expectations. In addition to traditional vehicles, the concept of maneuverability trials has expanded into the realm of robotics and autonomous systems. As technology advances, the need for robots and drones to navigate complex environments has become increasingly important. Conducting maneuverability trials for these machines involves testing their ability to adapt to changing conditions, avoid obstacles, and execute precise movements. In conclusion, the significance of maneuverability trials cannot be overstated. They play a vital role in ensuring that vehicles are not only functional but also safe and efficient. As we continue to innovate in the fields of automotive and aerospace engineering, the importance of these trials will only grow, paving the way for advancements that enhance the performance and safety of vehicles across all sectors. Understanding and mastering the principles behind maneuverability trials is essential for engineers and designers who aim to create the next generation of vehicles that can meet the demands of an ever-evolving world.

在工程和车辆设计领域，术语机动性试验具有重要意义。机动性试验是指进行一系列测试，以评估车辆在各种条件下改变方向、速度和位置的能力。这项试验的有效性对于确保车辆（无论是汽车、飞机还是海军舰艇）在现实世界场景中能够最佳表现至关重要。机动性试验的主要目标是评估车辆对驾驶员或飞行员指令的响应能力。在这些试验中，工程师观察车辆在障碍物之间导航、急转弯和在不同速度下保持稳定的速度和准确性。例如，赛车必须表现出高水平的机动性，以便在赛道上穿过紧急弯道，而军用飞机则必须展示出灵活性，以在战斗中避开威胁。为进行机动性试验，需要建立特定的指标。这些指标可能包括转弯半径、加速时间和制动距离。工程师通常使用专门设备在这些测试过程中收集数据，包括传感器和摄像头，记录车辆在各种条件下的性能。然后分析这些数据，以识别设计或性能中的任何弱点。安全性是机动性试验的另一个关键方面。车辆不仅必须能够有效机动，还必须在不危及乘客和其他道路使用者安全的情况下进行。例如，在新SUV的机动性试验中，工程师将测试其处理突然停车和紧急机动的能力，确保其能够安全地避免潜在事故。此外，机动性试验的结果可能会影响车辆的整体设计。如果某个特定型号未能达到所需的敏捷性和控制标准，工程师可能需要重新审视设计，对悬挂系统、重量分配甚至发动机进行调整。这一迭代过程对于开发不仅性能良好而且符合监管标准和消费者期望的车辆至关重要。除了传统车辆，机动性试验的概念已经扩展到机器人和自主系统的领域。随着技术的进步，机器人和无人机在复杂环境中导航的需求变得越来越重要。对这些机器进行机动性试验涉及测试它们适应变化条件、避免障碍物和执行精确运动的能力。总之，机动性试验的重要性不容小觑。它们在确保车辆不仅功能齐全，而且安全高效方面发挥着至关重要的作用。随着我们在汽车和航空航天工程领域的不断创新，这些试验的重要性只会增加，为提高各个行业车辆的性能和安全性铺平道路。理解和掌握机动性试验背后的原则对于那些旨在创造下一代能够满足不断变化的世界需求的车辆的工程师和设计师来说至关重要。