hinged rudder

简明释义

悬式舵

英英释义

例句

1.The maintenance team inspected the hinged rudder for any signs of wear and tear.

维修团队检查了铰接舵是否有磨损迹象。

2.The boat navigated smoothly through the narrow channel thanks to its efficient hinged rudder.

由于高效的铰接舵，船只顺利地穿过狭窄的航道。

3.Adjusting the angle of the hinged rudder can significantly improve the steering response.

调整铰接舵的角度可以显著改善操控反应。

4.The design of the hinged rudder allows for more precise maneuvering in tight spaces.

该铰接舵的设计允许在狭小空间内进行更精准的操控。

5.During the storm, the captain relied heavily on the hinged rudder to maintain control of the vessel.

在暴风雨中，船长非常依赖铰接舵来保持船只的控制。

作文

The world of naval engineering is filled with intricate designs and innovative technologies that enhance the performance of vessels. One such design element is the hinged rudder, a crucial component that plays a significant role in steering and maneuvering ships. A hinged rudder is essentially a type of rudder that is attached to the hull of a ship with a hinge mechanism, allowing it to pivot at various angles. This design enables more effective control over the vessel's direction, especially during complex maneuvers or when navigating through tight spaces.The importance of a hinged rudder cannot be overstated. In maritime operations, precise navigation is essential for safety and efficiency. As ships grow larger and more complex, the need for advanced steering mechanisms becomes increasingly critical. The hinged rudder provides enhanced responsiveness compared to traditional fixed rudders, allowing for quicker turns and better handling in rough waters.One of the key advantages of a hinged rudder is its ability to reduce drag. When a ship is moving through water, the rudder creates resistance, which can slow down the vessel. However, by utilizing a hinged design, the rudder can be adjusted to minimize this drag, thereby improving fuel efficiency and overall performance. This is particularly beneficial for commercial shipping companies that are constantly seeking ways to cut operational costs while maintaining high levels of service.Moreover, the hinged rudder is often used in conjunction with other advanced steering technologies, such as azimuth thrusters and dynamic positioning systems. These systems work together to provide a comprehensive solution for vessel maneuverability. For instance, in situations where precise positioning is required, such as offshore drilling or docking operations, the combination of a hinged rudder and thruster systems allows for exceptional control and accuracy.In addition to its practical benefits, the hinged rudder also represents a fascinating aspect of engineering design. Engineers must carefully consider factors such as material strength, hydrodynamics, and the overall weight distribution of the vessel when designing a rudder system. The challenge lies in creating a rudder that is both lightweight and strong enough to withstand the forces exerted by the water, especially during high-speed maneuvers.As technology continues to advance, we can expect to see further innovations in rudder design, including the development of smarter, more efficient hinged rudder systems. These advancements may incorporate sensors and automated systems that can adjust the rudder's position in real-time based on environmental conditions and the ship’s speed. Such innovations will not only improve navigational capabilities but also contribute to the sustainability of maritime operations by reducing fuel consumption and emissions.In conclusion, the hinged rudder is a vital component of modern naval architecture, offering significant advantages in terms of maneuverability, efficiency, and safety. As the maritime industry continues to evolve, the role of the hinged rudder will undoubtedly remain critical in ensuring that vessels can navigate the world's waters with precision and reliability. Understanding the mechanics and benefits of this innovative design will help us appreciate the complexities of naval engineering and its impact on global trade and transportation.

海军工程领域充满了复杂的设计和创新技术，这些技术提升了船舶的性能。其中一个设计元素是铰接舵，它在船只的操控和机动中发挥着重要作用。铰接舵本质上是一种舵，它通过铰链机制连接到船体上，允许它以不同的角度旋转。这种设计使得在复杂的操作或在狭窄空间内航行时，能够更有效地控制船只的方向。铰接舵的重要性不容小觑。在海事操作中，精确导航对安全和效率至关重要。随着船只越来越大、结构越来越复杂，对先进操控机制的需求变得愈加迫切。与传统固定舵相比，铰接舵提供了更好的响应能力，使得船只可以更快地转向，在恶劣海况下的操控性更强。铰接舵的一个关键优势是能够减少阻力。当船只在水中移动时，舵会产生阻力，这可能会减缓船只的速度。然而，通过采用铰接设计，舵可以调整以最小化这种阻力，从而提高燃油效率和整体性能。这对于商业航运公司尤其有利，因为他们不断寻求降低运营成本的方法，同时保持高水平的服务。此外，铰接舵通常与其他先进的操控技术结合使用，例如旋转推进器和动态定位系统。这些系统共同工作，为船只的机动性提供全面的解决方案。例如，在需要精确定位的情况下，如海上钻探或停靠操作，铰接舵与推进器系统的组合可以实现卓越的控制和准确性。除了实用性，铰接舵还代表了工程设计的一个迷人方面。工程师在设计舵系统时必须仔细考虑材料强度、水动力学以及船只的整体重量分布等因素。挑战在于创造出既轻便又足够坚固的舵，以承受水流施加的力量，尤其是在高速机动时。随着技术的不断进步，我们可以期待在舵设计方面出现进一步的创新，包括开发更智能、更高效的铰接舵系统。这些进步可能会结合传感器和自动系统，根据环境条件和船速实时调整舵的位置。这种创新不仅将改善导航能力，还将通过减少燃油消耗和排放来促进海事操作的可持续性。总之，铰接舵是现代海军建筑的重要组成部分，在机动性、效率和安全性方面提供了显著优势。随着海事行业的不断发展，铰接舵的作用无疑将继续在确保船只能够精确可靠地航行于全球水域中发挥关键作用。理解这种创新设计的机制和好处将帮助我们欣赏海军工程的复杂性及其对全球贸易和运输的影响。