cardanic suspension

简明释义

万向悬架

英英释义

例句

1.In the design of the drone, engineers implemented a cardanic suspension system to reduce vibration.

在无人机的设计中，工程师们实施了一个万向悬挂系统以减少振动。

2.The use of cardanic suspension in this racing car allows for improved handling at high speeds.

在这辆赛车中使用的万向悬挂允许在高速行驶时改善操控性。

3.The engineer explained how the cardanic suspension helps in reducing wear on the vehicle's tires.

工程师解释了万向悬挂如何帮助减少车辆轮胎的磨损。

4.A cardanic suspension is essential for maintaining the position of the camera during aerial shots.

在航拍过程中，万向悬挂对于保持相机位置至关重要。

5.The vehicle's cardanic suspension provides better stability on rough terrain.

这辆车的万向悬挂在崎岖地形上提供了更好的稳定性。

作文

The concept of cardanic suspension is essential in the field of mechanics and engineering, particularly when it comes to understanding the dynamics of vehicles and machinery. The term refers to a type of suspension system that allows for rotational movement in multiple directions. This is crucial for ensuring stability and comfort in various applications, from automobiles to aerospace engineering. In essence, a cardanic suspension (万向悬挂) enables components to move freely while maintaining their connection to the main structure, which is vital for performance and safety.To delve deeper into the significance of cardanic suspension, we can look at its application in automobiles. Vehicles are subjected to various forces during operation, including bumps on the road, turns, and acceleration. A traditional suspension system may struggle to absorb these forces effectively, leading to a rough ride or even loss of control. However, with a cardanic suspension (万向悬挂), the vehicle's wheels can adjust independently, allowing for improved traction and stability. This independent movement is achieved through a series of joints and linkages that create a flexible yet sturdy connection between the wheels and the car body.Moreover, the cardanic suspension mechanism is not limited to ground vehicles. In aviation, for instance, the principles of this suspension system are applied to ensure that aircraft can navigate turbulent air currents smoothly. By allowing parts of the aircraft to pivot and rotate freely, engineers can enhance the overall aerodynamics and safety of the flight. This adaptability is what makes cardanic suspension (万向悬挂) a cornerstone of modern engineering.In addition to vehicles and aircraft, cardanic suspension systems are also found in various industrial machines. For example, cranes and excavators utilize this technology to maintain balance and precision while lifting heavy loads. The ability to rotate and tilt without compromising stability is essential in these scenarios, where even the slightest imbalance can lead to accidents or equipment failure. Thus, the integration of cardanic suspension (万向悬挂) in such machinery showcases its versatility and importance across different fields.Furthermore, the development of cardanic suspension systems has evolved over time, incorporating advanced materials and technologies. Modern innovations include the use of lightweight composites and electronic controls that enhance the responsiveness of the suspension. These advancements not only improve performance but also contribute to fuel efficiency and lower emissions in vehicles, aligning with contemporary environmental standards.In conclusion, understanding the principles and applications of cardanic suspension (万向悬挂) is vital for anyone involved in engineering, automotive design, or aeronautics. This suspension system plays a critical role in enhancing the safety, stability, and overall performance of various machines and vehicles. As technology continues to advance, the importance of cardanic suspension will likely grow, paving the way for even more innovative solutions in the future.