yawing moment

简明释义

偏航力矩

英英释义

例句

1.In naval architecture, understanding the yawing moment 偏航力矩 is crucial for designing stable ships.

在船舶设计中，理解yawing moment 偏航力矩对于设计稳定的船只至关重要。

2.The drone experienced a sudden yawing moment 偏航力矩 that caused it to veer off course.

无人机经历了突然的yawing moment 偏航力矩，导致它偏离了航线。

3.The vehicle's yawing moment 偏航力矩 increased when it took a sharp turn at high speed.

当车辆以高速急转弯时，yawing moment 偏航力矩增加了。

4.Engineers must calculate the yawing moment 偏航力矩 when simulating the aircraft's behavior during turbulence.

工程师在模拟飞机在颠簸中的行为时，必须计算yawing moment 偏航力矩。

5.The pilot had to adjust the controls to counteract the yawing moment 偏航力矩 caused by the strong winds.

飞行员必须调整控制以抵消强风造成的yawing moment 偏航力矩。

作文

Understanding the concept of a yawing moment is crucial for anyone involved in the fields of engineering, aviation, or marine navigation. A yawing moment refers to the rotational force that causes an object to rotate around its vertical axis. This phenomenon is particularly significant in the design and operation of aircraft and ships, where maintaining stability and control is essential. When an aircraft experiences a yawing moment, it can lead to changes in direction, which must be managed carefully by the pilot to ensure safe flight. Similarly, in maritime operations, a yawing moment can affect a ship's course and stability, making it vital for navigators to understand how to counteract these forces.In aviation, the yawing moment is often influenced by factors such as wind conditions, the distribution of weight within the aircraft, and the design of the wings and tail surfaces. For instance, if an aircraft encounters a sudden gust of wind from the side, it may experience a strong yawing moment that pushes the nose of the plane off its intended flight path. Pilots are trained to respond to such situations by applying corrective measures, such as adjusting the rudder or altering thrust on one engine. This ability to manage the yawing moment is critical for maintaining control and ensuring passenger safety.On the other hand, in naval architecture, the yawing moment is equally important. Ships are designed with hull shapes and stabilizing features to minimize unwanted yawing. When a ship turns, the forces acting on it can create a yawing moment that affects its trajectory. Navigators must account for these moments when plotting a course, especially in rough seas where waves can exacerbate the effects of yawing. Understanding the yawing moment allows engineers to develop better designs for both ships and aircraft, leading to improved safety and efficiency.Moreover, the study of yawing moments extends beyond just aviation and maritime contexts. In the automotive industry, for example, the dynamics of a vehicle can also involve yawing moments. When a car turns, it experiences forces that can cause it to rotate around its vertical axis, potentially leading to loss of control if not managed properly. Engineers consider these forces when designing vehicle stability systems, ensuring that cars can safely navigate turns without veering off course.In conclusion, the yawing moment is a fundamental concept that impacts various modes of transportation. Whether in the skies, on the seas, or on the roads, understanding how to manage yawing moments is essential for safety and control. As technology advances, the methods for predicting and counteracting these moments continue to improve, leading to safer and more reliable means of transport. Therefore, a thorough grasp of the yawing moment is indispensable for professionals in engineering and related fields, as it plays a pivotal role in the design and operation of vehicles across all platforms.

理解偏航力矩的概念对任何从事工程、航空或海洋导航领域的人来说都是至关重要的。偏航力矩是指使物体绕其垂直轴旋转的旋转力。这种现象在飞机和船舶的设计和操作中尤为重要，因为保持稳定性和控制力是至关重要的。当飞机经历偏航力矩时，会导致方向的变化，飞行员必须仔细管理以确保安全飞行。同样，在海洋操作中，偏航力矩会影响船只的航向和稳定性，因此导航员必须了解如何抵消这些力量。在航空中，偏航力矩通常受风速、飞机内部重量分布以及机翼和尾部设计等因素的影响。例如，如果一架飞机遇到来自侧面的突风，可能会经历强烈的偏航力矩，使飞机的机头偏离预定航线。飞行员经过训练，在这种情况下会采取纠正措施，例如调整方向舵或改变一台发动机的推力。管理偏航力矩的能力对保持控制和确保乘客安全至关重要。另一方面，在船舶建筑中，偏航力矩同样重要。船舶的设计包括船体形状和稳定特征，以最小化不必要的偏航。当船只转弯时，作用在其上的力量可能会产生偏航力矩，影响其轨迹。导航员在绘制航线时必须考虑这些力，尤其是在波涛汹涌的海面上，波浪可能会加剧偏航的影响。理解偏航力矩使工程师能够开发出更好的船舶和飞机设计，从而提高安全性和效率。此外，偏航力矩的研究不仅限于航空和海洋背景。在汽车工业中，车辆的动态也可能涉及偏航力矩。当汽车转弯时，会经历可以导致其围绕垂直轴旋转的力量，如果不加以管理，可能会导致失控。工程师在设计车辆稳定系统时考虑这些力量，确保汽车在转弯时能够安全行驶，而不会偏离路线。总之，偏航力矩是影响各种交通方式的基本概念。无论是在天空、海洋还是公路上，理解如何管理偏航力矩对安全和控制至关重要。随着技术的进步，预测和抵消这些力矩的方法不断改善，从而导致更安全、更可靠的交通工具。因此，全面掌握偏航力矩对于工程和相关领域的专业人士来说是不可或缺的，因为它在各种平台的交通工具设计和操作中发挥着关键作用。