lateral stability

简明释义

横稳性

英英释义

例句

1.During high-speed turns, a car's lateral stability is crucial for maintaining control.

在高速转弯时，汽车的横向稳定性对于保持控制至关重要。

2.Engineers must consider lateral stability when designing bridges to prevent swaying.

工程师在设计桥梁时必须考虑横向稳定性以防止摇晃。

3.A wider wheelbase can enhance a vehicle's lateral stability.

更宽的轴距可以增强车辆的横向稳定性。

4.In aviation, lateral stability refers to the aircraft's ability to resist rolling.

在航空中，横向稳定性指的是飞机抵抗翻滚的能力。

5.The design of the vehicle ensures that it has excellent lateral stability.

该车辆的设计确保其具有出色的横向稳定性。

作文

Lateral stability is a crucial concept in various fields, particularly in engineering, aviation, and marine navigation. It refers to the ability of an object, such as a vehicle or a structure, to maintain its position and orientation against lateral forces. In simpler terms, it is about how well something can resist tipping over or swaying from side to side when subjected to external pressures. Understanding lateral stability (侧向稳定性) is essential for ensuring safety and performance in many applications.In the realm of aviation, for example, lateral stability (侧向稳定性) is vital for the safe operation of aircraft. When a plane encounters turbulence or strong winds, its wings may experience uneven lift, which can cause the aircraft to roll or tilt. Engineers design wings and fuselage shapes to enhance lateral stability (侧向稳定性), allowing the aircraft to return to a level flight position more easily. This is achieved through careful consideration of the center of gravity and the distribution of weight within the aircraft.Similarly, in the field of marine engineering, lateral stability (侧向稳定性) plays a significant role in the design of ships and boats. A vessel must be able to withstand waves and wind without capsizing. The hull shape, ballast systems, and overall weight distribution are all factors that contribute to a ship's lateral stability (侧向稳定性). By ensuring that a boat has adequate lateral stability (侧向稳定性), engineers can help prevent accidents and ensure a smoother sailing experience for passengers.In civil engineering, lateral stability (侧向稳定性) is also relevant when designing buildings and bridges. Structures must be able to endure lateral loads caused by wind, earthquakes, or other forces. Architects and engineers use various methods, such as shear walls and bracing systems, to enhance the lateral stability (侧向稳定性) of buildings. This ensures that they remain upright and secure during adverse conditions.Moreover, the concept of lateral stability (侧向稳定性) extends beyond physical structures to include dynamic systems, such as robotics and vehicles. For instance, self-driving cars must have advanced algorithms that allow them to maintain lateral stability (侧向稳定性) while navigating turns and responding to obstacles. Sensors and control systems work together to ensure that the vehicle remains balanced and does not veer off course.In conclusion, lateral stability (侧向稳定性) is a fundamental principle that underpins the safety and functionality of various systems and structures. Whether in aviation, marine engineering, civil construction, or robotics, understanding and enhancing lateral stability (侧向稳定性) is essential for preventing accidents and ensuring optimal performance. As technology continues to advance, the importance of maintaining lateral stability (侧向稳定性) will only grow, highlighting the need for ongoing research and innovation in this critical area.

侧向稳定性是一个在多个领域中至关重要的概念，特别是在工程、航空和海洋导航方面。它指的是物体（如车辆或结构）在受到侧向力的作用下保持其位置和方向的能力。简单来说，它是指某物在受到外部压力时抵抗倾覆或左右摆动的能力。理解lateral stability（侧向稳定性）对确保许多应用的安全性和性能至关重要。例如，在航空领域，lateral stability（侧向稳定性）对于飞机的安全操作至关重要。当飞机遇到湍流或强风时，其机翼可能会经历不均匀的升力，这可能导致飞机滚动或倾斜。工程师设计机翼和机身形状以增强lateral stability（侧向稳定性），使飞机更容易恢复水平飞行。这是通过仔细考虑重心和飞机内部重量分布来实现的。同样，在海洋工程领域，lateral stability（侧向稳定性）在船舶和小艇的设计中也起着重要作用。一艘船必须能够承受波浪和风而不倾覆。船体形状、压舱系统和整体重量分布都是影响船只lateral stability（侧向稳定性）的因素。通过确保船只具有足够的lateral stability（侧向稳定性），工程师可以帮助防止事故并确保乘客的航行体验更加平稳。在土木工程中，lateral stability（侧向稳定性）在设计建筑物和桥梁时也相关。结构必须能够承受由风、地震或其他力量引起的侧向荷载。建筑师和工程师使用各种方法，如剪力墙和支撑系统，以增强建筑物的lateral stability（侧向稳定性）。这确保了建筑物在不利条件下保持直立和安全。此外，lateral stability（侧向稳定性）的概念不仅限于物理结构，还包括动态系统，如机器人和车辆。例如，自驾车必须具备先进的算法，使其在转弯和应对障碍物时保持lateral stability（侧向稳定性）。传感器和控制系统共同工作，以确保车辆保持平衡，不偏离路线。总之，lateral stability（侧向稳定性）是支撑各种系统和结构安全性与功能性的基本原则。无论是在航空、海洋工程、土木建筑还是机器人领域，理解和增强lateral stability（侧向稳定性）对于防止事故和确保最佳性能至关重要。随着技术的不断进步，保持lateral stability（侧向稳定性）的重要性将愈加突出，这强调了在这一关键领域持续研究和创新的必要性。