air stabilization

简明释义

空气稳定系统(回转时

英英释义

例句

1.Using air stabilization techniques, the team was able to create a more stable environment for the experiment.

通过使用空气稳定技术，团队能够为实验创造一个更稳定的环境。

2.The new drone features advanced air stabilization technology that ensures smooth flight even in windy conditions.

这款新型无人机采用了先进的空气稳定技术，即使在风大的条件下也能确保平稳飞行。

3.The air stabilization feature on the new smartphone camera allows for clearer nighttime photos.

新智能手机相机上的空气稳定功能允许拍摄更清晰的夜间照片。

4.The engineers designed a system for air stabilization in the aircraft to improve passenger comfort during turbulence.

工程师们设计了一套用于飞机的空气稳定系统，以提高乘客在颠簸期间的舒适度。

5.In photography, air stabilization can help reduce motion blur caused by camera shake.

在摄影中，空气稳定可以减少由于相机抖动引起的运动模糊。

作文

Air travel has revolutionized the way we connect with the world, enabling us to traverse vast distances in a matter of hours. However, one of the challenges faced by aircraft is turbulence, which can lead to uncomfortable experiences for passengers and pose risks to safety. This is where the concept of air stabilization comes into play. 空气稳定性 refers to the methods and technologies used to enhance the stability of an aircraft during flight, especially when encountering turbulent air currents. The importance of air stabilization cannot be overstated. For commercial airlines, maintaining passenger comfort is paramount. Turbulence can cause sudden jolts and drops that may lead to anxiety among travelers. By employing advanced air stabilization techniques, airlines can minimize these disturbances, ensuring a smoother ride. Additionally, this technology contributes to the overall safety of the flight, as it helps maintain control of the aircraft under varying atmospheric conditions.There are several ways in which air stabilization is achieved. One common method involves the use of wing designs that are specifically engineered to counteract the effects of turbulence. Modern aircraft often feature winglets, which are small vertical fins at the tips of the wings. These winglets help reduce drag and improve lift, thus enhancing the aircraft's stability. Furthermore, advancements in computer technology have led to the development of sophisticated autopilot systems that can automatically adjust the aircraft's controls in response to changing air conditions, providing an additional layer of air stabilization. Another aspect of air stabilization involves the use of sensors that detect turbulence ahead of time. These sensors can provide pilots with real-time data about the air conditions, allowing them to make informed decisions about altitude changes or flight paths. By anticipating turbulence, pilots can take proactive measures to ensure a smoother flight experience. This not only enhances passenger comfort but also reduces wear and tear on the aircraft, leading to lower maintenance costs over time.The aviation industry continues to invest in research and development aimed at improving air stabilization technologies. Innovations such as active control systems and adaptive wing designs are being explored to further enhance aircraft performance. These advancements promise to make flying even more comfortable and safe in the future.In conclusion, air stabilization plays a crucial role in modern aviation, impacting both passenger comfort and flight safety. As technology continues to evolve, we can expect to see even more effective solutions for managing turbulence and enhancing the overall flying experience. The ongoing commitment to improving air stabilization will undoubtedly shape the future of air travel, making it an even more reliable mode of transportation for people around the globe.

航空旅行彻底改变了我们与世界的联系，使我们能够在几小时内跨越广阔的距离。然而，飞机面临的挑战之一是颠簸，这可能导致乘客的不适体验并对安全构成风险。这就是空气稳定性概念发挥作用的地方。空气稳定性是指用于增强飞机在飞行过程中稳定性的方法和技术，尤其是在遇到气流颠簸时。空气稳定性的重要性不容小觑。对于商业航空公司而言，保持乘客舒适至关重要。颠簸可能会导致突然的震动和下降，从而引发旅客的焦虑。通过采用先进的空气稳定性技术，航空公司可以最小化这些干扰，确保更平稳的飞行。此外，这项技术有助于提高飞行的整体安全性，因为它有助于在各种大气条件下保持飞机的控制。实现空气稳定性有几种方法。一种常见的方法涉及使用专门设计的机翼，以抵消颠簸的影响。现代飞机通常配备翼尖小翼，即机翼尖端的小垂直鳍。这些翼尖小翼有助于减少阻力并改善升力，从而增强飞机的稳定性。此外，计算机技术的进步导致开发出复杂的自动驾驶系统，可以根据变化的空气条件自动调整飞机的控制，从而提供额外的空气稳定性。空气稳定性的另一个方面涉及使用传感器来提前检测颠簸。这些传感器可以向飞行员提供关于空气条件的实时数据，使他们能够就高度变化或飞行路径做出明智的决策。通过预测颠簸，飞行员可以采取主动措施以确保更平稳的飞行体验。这不仅提高了乘客的舒适度，还减少了飞机的磨损，从而降低了长期的维护成本。航空业继续投资于旨在改善空气稳定性技术的研究和开发。正在探索主动控制系统和自适应机翼设计等创新，以进一步增强飞机性能。这些进展承诺使未来的飞行更加舒适和安全。总之，空气稳定性在现代航空中扮演着至关重要的角色，影响着乘客的舒适度和飞行安全。随着技术的不断发展，我们可以期待看到更有效的解决方案来管理颠簸并提升整体飞行体验。对改善空气稳定性的持续承诺无疑将塑造未来的空中旅行，使其成为全球人们更可靠的交通方式。