controlled radial steering gear

简明释义

可调径向操舵仪

英英释义

例句

1.With the implementation of controlled radial steering gear, the truck can now navigate through urban environments more efficiently.

通过实施受控径向转向装置，这辆卡车现在可以更高效地在城市环境中导航。

2.In construction equipment, the controlled radial steering gear provides better control when maneuvering heavy loads.

在建筑设备中，受控径向转向装置在操作重载时提供了更好的控制。

3.During the test drive, the engineer noted how the controlled radial steering gear improved the car's handling on sharp turns.

在试驾过程中，工程师注意到受控径向转向装置如何改善汽车在急转弯时的操控性。

4.The controlled radial steering gear allows for precise adjustments, making it ideal for racing applications.

该受控径向转向装置允许进行精确调整，非常适合赛车应用。

5.The new vehicle model features a state-of-the-art controlled radial steering gear, which enhances maneuverability in tight spaces.

这款新车型配备了先进的受控径向转向装置，提高了在狭小空间内的机动性。

作文

In the world of engineering and automotive design, the term controlled radial steering gear refers to a sophisticated mechanism that allows for precise control over the direction in which a vehicle moves. This technology is particularly significant in modern vehicles, where the demand for enhanced maneuverability and safety is paramount. The controlled radial steering gear system operates by adjusting the angle of the wheels relative to the chassis, enabling drivers to navigate tight corners and challenging terrains with ease.One of the primary advantages of a controlled radial steering gear system is its ability to provide better feedback to the driver. Traditional steering systems often lack the responsiveness needed for high-performance driving. In contrast, a controlled radial steering gear offers real-time adjustments based on the driver’s input, enhancing the overall driving experience. This responsiveness is crucial not only for performance vehicles but also for everyday cars that require a balance between comfort and control.Moreover, the implementation of a controlled radial steering gear can significantly improve vehicle stability. By allowing for finer control of the steering angle, this system helps to reduce the risk of oversteering or understeering, which are common issues that can lead to accidents. For instance, during sudden maneuvers or when driving on slippery surfaces, a controlled radial steering gear can make quick adjustments to maintain optimal traction and control.In addition to safety and performance benefits, the controlled radial steering gear also contributes to fuel efficiency. By optimizing the steering response, vehicles can navigate more efficiently, reducing unnecessary strain on the engine. This not only leads to lower fuel consumption but also minimizes wear and tear on the vehicle components, ultimately extending the lifespan of the car.The development of controlled radial steering gear technology is a testament to the advancements in automotive engineering. As vehicles become more complex, integrating sophisticated systems like this one is essential for meeting consumer expectations. Manufacturers are continually investing in research and development to refine these systems, ensuring they are both reliable and effective.Furthermore, the potential applications of controlled radial steering gear extend beyond traditional vehicles. In the realm of robotics and automated systems, similar steering mechanisms can be employed to enhance maneuverability and precision. For example, autonomous vehicles rely heavily on advanced steering technologies to navigate through various environments safely.In conclusion, the controlled radial steering gear represents a significant leap forward in steering technology, offering numerous benefits in terms of control, safety, and efficiency. As we continue to push the boundaries of automotive engineering, it is clear that systems like the controlled radial steering gear will play a crucial role in shaping the future of transportation. With ongoing innovations and improvements, we can expect to see even more advanced steering solutions that will enhance our driving experiences and revolutionize the way we interact with our vehicles.

在工程和汽车设计的世界中，术语控制径向转向齿轮指的是一种复杂的机制，它允许对车辆移动方向进行精确控制。这项技术在现代车辆中尤为重要，因为对增强机动性和安全性的需求至关重要。控制径向转向齿轮系统通过调整车轮相对于底盘的角度来运作，使驾驶者能够轻松地在狭窄的弯道和具有挑战性的地形中导航。控制径向转向齿轮系统的主要优势之一是能够为驾驶者提供更好的反馈。传统的转向系统往往缺乏高性能驾驶所需的响应能力。相比之下，控制径向转向齿轮提供基于驾驶者输入的实时调整，增强整体驾驶体验。这种响应能力对于高性能车辆至关重要，同时也适用于需要在舒适性和控制之间取得平衡的日常汽车。此外，实施控制径向转向齿轮可以显著提高车辆的稳定性。通过允许对转向角进行更精细的控制，该系统有助于减少过度转向或不足转向的风险，这些都是可能导致事故的常见问题。例如，在突然的操控或在滑溜的路面行驶时，控制径向转向齿轮可以快速调整，以保持最佳的牵引力和控制。除了安全性和性能优势外，控制径向转向齿轮还对燃油效率产生积极影响。通过优化转向响应，车辆可以更高效地导航，减少对发动机的不必要压力。这不仅导致燃油消耗降低，而且最小化了车辆组件的磨损，从而最终延长了汽车的使用寿命。控制径向转向齿轮技术的发展证明了汽车工程的进步。随着车辆变得越来越复杂，集成像这样的复杂系统对于满足消费者期望至关重要。制造商不断投资于研发，以完善这些系统，确保它们既可靠又有效。此外，控制径向转向齿轮的潜在应用超越了传统车辆。在机器人和自动化系统领域，类似的转向机制可以被用来增强机动性和精确度。例如，无人驾驶汽车在安全导航各种环境时严重依赖先进的转向技术。总之，控制径向转向齿轮代表了转向技术的重要飞跃，在控制、安全和效率方面提供了众多好处。随着我们不断推动汽车工程的边界，显然像控制径向转向齿轮这样的系统将在塑造交通运输的未来中发挥关键作用。随着持续的创新和改进，我们可以预期会看到更多先进的转向解决方案，这将增强我们的驾驶体验并彻底改变我们与车辆的互动方式。