direct-connected sterring gear

简明释义

直接传动操舵装置

英英释义

例句

1.The new boat design features a direct-connected steering gear, which enhances responsiveness during maneuvers.

新船的设计采用了直接连接的舵机，提高了在操作过程中的响应能力。

2.The engineer explained that the direct-connected steering gear allows for more precise control of the vehicle.

工程师解释说，直接连接的舵机使得车辆的控制更加精确。

3.In heavy machinery, a direct-connected steering gear is essential for navigating tight spaces effectively.

在重型机械中，直接连接的舵机对于有效地在狭窄空间中导航至关重要。

4.For optimal performance, the racing car is equipped with a direct-connected steering gear that reduces any lag in steering input.

为了获得最佳性能，这辆赛车配备了一个直接连接的舵机，减少了转向输入的延迟。

5.The maintenance manual highlights the importance of checking the direct-connected steering gear regularly to ensure safety.

维护手册强调定期检查直接连接的舵机的重要性，以确保安全。

作文

The world of engineering is filled with intricate mechanisms that work together to create efficient systems. One such mechanism is the direct-connected steering gear, a crucial component in various vehicles and machinery. Understanding how this system functions not only enhances our knowledge of engineering principles but also highlights the importance of precision in design and execution.The direct-connected steering gear refers to a type of steering mechanism where the steering wheel is directly linked to the steering system without any intermediary components. This direct connection allows for immediate feedback and responsiveness, making it an essential feature in sports cars and other high-performance vehicles. Unlike traditional systems that may involve several linkages, the direct connection minimizes play and increases control, allowing drivers to maneuver with greater accuracy.In modern automotive design, the implementation of a direct-connected steering gear can significantly improve the driving experience. For instance, when a driver turns the steering wheel, the direct connection means that the wheels respond almost instantaneously. This responsiveness is vital for safety, especially at high speeds or during sharp turns. Engineers must consider factors such as weight distribution, material strength, and the geometry of the steering system to ensure that the direct-connected steering gear performs optimally under various conditions.Moreover, the evolution of technology has led to innovations in the design and functionality of direct-connected steering gears. With the advent of electric power steering systems, engineers can now integrate advanced sensors and electronic controls that enhance the performance of these steering mechanisms. This integration allows for features such as variable steering ratios, which adjust the responsiveness based on speed, providing a more comfortable driving experience.In addition to automotive applications, direct-connected steering gears are also utilized in marine and aerospace engineering. In ships, for example, a direct connection between the helm and the rudder allows for precise navigation, crucial for maneuvering in tight spaces or during adverse weather conditions. Similarly, in aircraft, direct connections in control surfaces ensure that pilots have immediate control over their flight path, enhancing safety and performance.Understanding the significance of direct-connected steering gears extends beyond merely appreciating their mechanical properties. It invites us to consider the broader implications of engineering design, including safety, efficiency, and user experience. As we continue to innovate and improve these systems, we must remain mindful of the fundamental principles that govern their operation.In conclusion, the direct-connected steering gear stands as a testament to the ingenuity of engineering design. Its direct linkage provides unparalleled responsiveness and control, making it a preferred choice in various high-performance applications. As technology advances, the potential for further enhancements in steering systems remains vast, promising an exciting future for both engineers and drivers alike. By understanding and mastering the principles behind direct-connected steering gears, we can appreciate the intricate dance of mechanics that keeps our vehicles and machines operating smoothly and safely.

工程学的世界充满了复杂的机制，这些机制共同作用，以创造高效的系统。其中一个机制是直接连接的转向齿轮，这是各种车辆和机械中的关键组件。理解这个系统的功能不仅增强了我们对工程原理的知识，还突显了设计和执行精确性的重要性。直接连接的转向齿轮指的是一种转向机制，其中方向盘与转向系统直接连接，没有任何中介组件。这种直接连接允许即时反馈和响应，使其成为跑车及其他高性能车辆中的重要特征。与可能涉及多个连杆的传统系统不同，直接连接最小化了间隙并增加了控制，使驾驶者能够更准确地操控。在现代汽车设计中，实施直接连接的转向齿轮可以显著改善驾驶体验。例如，当驾驶员转动方向盘时，直接连接意味着车轮几乎瞬间响应。这种响应性对于安全至关重要，特别是在高速或急转弯时。工程师必须考虑重量分布、材料强度和转向系统的几何形状等因素，以确保直接连接的转向齿轮在各种条件下表现最佳。此外，技术的进步导致了直接连接的转向齿轮设计和功能的创新。随着电动助力转向系统的出现，工程师现在可以集成先进的传感器和电子控制，增强这些转向机制的性能。这种集成允许诸如可变转向比等功能，根据速度调整响应性，提供更舒适的驾驶体验。除了汽车应用外，直接连接的转向齿轮也被用于海洋和航空工程。在船只中，例如，舵和舵轮之间的直接连接允许精确导航，对于在狭窄空间或恶劣天气条件下的机动至关重要。同样，在飞机中，控制表面的直接连接确保飞行员对飞行路径有即时控制，从而增强安全性和性能。理解直接连接的转向齿轮的重要性超出了单纯欣赏其机械特性。这让我们思考工程设计的更广泛影响，包括安全性、效率和用户体验。随着我们不断创新和改进这些系统，我们必须时刻关注支配其操作的基本原理。总之，直接连接的转向齿轮是工程设计智慧的证明。它的直接连接提供了无与伦比的响应性和控制，使其成为各种高性能应用的首选。随着技术的进步，转向系统进一步增强的潜力仍然巨大，为工程师和驾驶者带来了激动人心的未来。通过理解和掌握直接连接的转向齿轮背后的原理，我们可以欣赏到保持我们的车辆和机器顺畅、安全运行的复杂机械舞蹈。