active roll-resisting fin

简明释义

可操纵减摇鳍

英英释义

例句

1.The new sports car features an advanced active roll-resisting fin, which enhances stability during sharp turns.

这款新运动汽车配备了先进的主动抗倾斜鳍片，在急转弯时提高了稳定性。

2.The use of an active roll-resisting fin in this aircraft design allows for smoother flights during turbulence.

在这种飞机设计中使用主动抗倾斜鳍片可以使飞行在颠簸中更加平稳。

3.During the test drive, I noticed how the active roll-resisting fin improved the vehicle's handling on uneven roads.

在试驾过程中，我注意到主动抗倾斜鳍片如何改善车辆在不平路面上的操控性。

4.Engineers are developing a new type of active roll-resisting fin that can adapt to changing weather conditions.

工程师们正在开发一种新型的主动抗倾斜鳍片，可以适应变化的天气条件。

5.The yacht is equipped with an active roll-resisting fin to minimize rolling in rough seas.

这艘游艇配备了主动抗倾斜鳍片，以减少在恶劣海况下的倾斜。

作文

In the world of modern engineering, particularly in the field of aerospace and marine design, the term active roll-resisting fin plays a crucial role in enhancing stability and control. These fins are sophisticated devices that actively respond to changes in the vehicle's orientation and external conditions, providing a dynamic solution to the challenges posed by roll movements. The concept of roll resistance is essential, especially for vehicles that operate in environments where turbulence or sudden shifts can occur, such as aircraft during flight or ships navigating rough seas. The active roll-resisting fin is designed to counteract unwanted rolling motions by adjusting its position and angle based on real-time data. This adaptability allows for improved handling and safety, making it an invaluable component in modern vehicle design. For example, in aviation, maintaining stability during flight is paramount. An aircraft equipped with active roll-resisting fins can respond to gusts of wind or sudden maneuvers more effectively than traditional designs, leading to a smoother ride for passengers and crew alike.In marine applications, the importance of active roll-resisting fins cannot be overstated. Ships and boats often face the challenge of rolling due to waves and currents, which can affect both performance and safety. By integrating these fins into the design, engineers can significantly reduce roll, improving the vessel's stability and making it easier to navigate through turbulent waters. This technology not only enhances safety but also contributes to fuel efficiency, as a more stable vessel requires less energy to maintain its course.The technology behind active roll-resisting fins involves sensors, actuators, and advanced control systems that work together to monitor and adjust the fins' positions in real time. This level of sophistication marks a significant advancement over passive systems, which rely solely on fixed surfaces that do not adapt to changing conditions. The ability to actively control the fins allows for finer adjustments and greater responsiveness, which is critical in high-speed or unpredictable environments.Moreover, the implementation of active roll-resisting fins is not limited to just aircraft and ships. The automotive industry is also exploring similar technologies to enhance vehicle stability during high-speed maneuvers or adverse weather conditions. By applying principles from aerospace and marine engineering, car manufacturers are developing systems that can automatically adjust the vehicle's dynamics, providing a safer driving experience.In conclusion, the active roll-resisting fin represents a significant innovation in the fields of vehicle design and engineering. Its ability to dynamically counteract roll movements enhances stability and safety across various modes of transportation. As technology continues to evolve, we can expect to see even more advanced applications of this concept, leading to safer and more efficient vehicles in the air, on the water, and on the road. The future of transportation looks promising with the integration of such intelligent systems, paving the way for a new era of engineering excellence.

在现代工程领域，特别是在航空和海洋设计领域，术语主动抗滚鳍在增强稳定性和控制方面起着至关重要的作用。这些鳍是复杂的装置，可以主动响应车辆方向和外部条件的变化，为应对滚动运动所带来的挑战提供动态解决方案。滚动阻力的概念尤为重要，尤其对于在气流或突发变化中运行的车辆，如飞行中的飞机或在波涛汹涌的海洋中航行的船只。主动抗滚鳍的设计旨在通过根据实时数据调整其位置和角度来抵消不必要的滚动运动。这种适应性使得改善操控性和安全性成为可能，使其成为现代车辆设计中不可或缺的组成部分。例如，在航空领域，保持飞行中的稳定性至关重要。配备有主动抗滚鳍的飞机可以比传统设计更有效地应对风的冲击或突然的机动，从而为乘客和机组人员提供更平稳的飞行体验。在海洋应用中，主动抗滚鳍的重要性更是不可低估。船只和快艇经常面临由于波浪和水流引起的滚动挑战，这会影响性能和安全。通过将这些鳍集成到设计中，工程师可以显著减少滚动，提高船舶的稳定性，使其更容易在波涛汹涌的水域中导航。这项技术不仅提高了安全性，还促进了燃油效率，因为更稳定的船舶需要更少的能量来维持航向。主动抗滚鳍背后的技术涉及传感器、执行器和先进的控制系统，这些系统共同工作以实时监测和调整鳍的位置。这种复杂程度标志着相较于被动系统的重大进步，后者仅依靠固定表面，不会适应变化的条件。主动控制鳍的能力允许更细微的调整和更大的响应性，这在高速或不可预测的环境中至关重要。此外，主动抗滚鳍的应用并不仅限于飞机和船舶。汽车工业也在探索类似的技术，以增强高速度驾驶或恶劣天气条件下的车辆稳定性。通过应用航空和海洋工程的原理，汽车制造商正在开发可以自动调整车辆动态的系统，从而提供更安全的驾驶体验。总之，主动抗滚鳍代表了车辆设计和工程领域的一项重要创新。其动态抵消滚动运动的能力增强了各种交通方式的稳定性和安全性。随着技术的不断发展，我们可以期待看到这一概念的更先进应用，从而在空中、水上和陆地上创造出更安全、更高效的车辆。随着这种智能系统的整合，交通的未来显得光明，铺平了工程卓越新时代的道路。