after perpendicular to center of buoyancy

简明释义

尾垂线至浮心

英英释义

例句

1.To ensure stability, the engineer calculated the forces acting after perpendicular to center of buoyancy.

为了确保稳定性，工程师计算了作用于浮心垂直后的力。

2.The ship tilted slightly, causing the hull to align after perpendicular to center of buoyancy.

船只轻微倾斜，导致船体在与浮心垂直后对齐。

3.During the test, the model was observed to behave differently after perpendicular to center of buoyancy.

在测试过程中，模型在浮心垂直后的表现有所不同。

4.The stability analysis showed that the vessel would capsize if it tilted after perpendicular to center of buoyancy.

稳定性分析表明，如果船只倾斜到浮心垂直后，将会翻覆。

5.The design of the vessel must account for changes after perpendicular to center of buoyancy during rough seas.

船只设计必须考虑在恶劣海况下浮心垂直后的变化。

作文

In the study of fluid mechanics and naval architecture, understanding the principles of buoyancy is crucial for designing vessels that can float and remain stable in water. One important concept related to buoyancy is the center of buoyancy, which is defined as the point in a floating object where the buoyant force, or the upward force exerted by the fluid, acts. The position of this center can shift depending on the shape and orientation of the vessel. When analyzing the stability of a ship or boat, it is essential to consider how the center of buoyancy interacts with other forces acting on the vessel. This interaction can be described using the phrase after perpendicular to center of buoyancy (与浮心垂直之后). This phrase refers to the orientation of the vessel in relation to its center of buoyancy after certain movements, such as tilting or rolling. When a vessel tilts, the center of buoyancy moves, and the stability of the ship is affected. If the center of gravity is above the center of buoyancy, the vessel may become unstable and capsize. Therefore, naval architects must ensure that the design of the vessel keeps the center of gravity below the center of buoyancy during operation. This is where the concept of after perpendicular to center of buoyancy becomes significant. It helps in determining the right angles and positions that will maintain stability. For example, when a ship is heeled over by wind or waves, the center of buoyancy shifts to the side, creating a righting moment that tries to bring the vessel back to an upright position. The angle at which this occurs is critical, and engineers often calculate it using the principles of geometry and physics. Understanding how the vessel behaves after perpendicular to center of buoyancy (与浮心垂直之后) allows designers to predict how the vessel will respond to external forces. Moreover, the phrase also applies to various scenarios in marine engineering. For instance, when considering the effects of cargo loading, the distribution of weight can affect the center of gravity and subsequently the center of buoyancy. By analyzing the vessel's behavior after perpendicular to center of buoyancy (与浮心垂直之后), engineers can make informed decisions about load distribution to enhance stability and safety. In conclusion, the phrase after perpendicular to center of buoyancy (与浮心垂直之后) encapsulates a fundamental aspect of naval architecture and fluid dynamics. It highlights the relationship between a vessel's center of buoyancy and its stability under various conditions. By mastering this concept, engineers and naval architects can design safer, more efficient vessels that perform well in challenging maritime environments. Understanding these principles not only contributes to the success of naval projects but also ensures the safety of those who navigate the seas.

在流体力学和船舶设计的研究中，理解浮力原理对于设计能够漂浮并在水中保持稳定的船只至关重要。与浮力相关的一个重要概念是浮心，它被定义为在漂浮物体中，浮力（即流体施加的向上力）作用的点。这个浮心的位置会根据船只的形状和方向而变化。在分析船舶或小艇的稳定性时，考虑浮心与作用于船只的其他力之间的相互作用是必不可少的。这种相互作用可以用短语与浮心垂直之后来描述。这个短语指的是船只在经历某些运动（如倾斜或滚动）后，相对于其浮心的方向。当船只倾斜时，浮心会移动，船舶的稳定性受到影响。如果重心高于浮心，船只可能变得不稳定并翻覆。因此，船舶设计师必须确保船只的设计在操作过程中保持重心低于浮心。这就是与浮心垂直之后概念的重要性所在。它有助于确定维持稳定所需的正确角度和位置。例如，当船只因风或波浪而倾斜时，浮心会向一侧移动，产生试图将船只恢复到直立位置的复位力矩。这种情况发生的角度至关重要，工程师通常利用几何和物理原理进行计算。理解船只在与浮心垂直之后的行为使设计师能够预测船只对外力的反应。此外，这个短语还适用于海洋工程中的各种场景。例如，在考虑货物装载的影响时，重量的分布会影响重心，进而影响浮心。通过分析船只在与浮心垂直之后的表现，工程师可以就负载分配做出明智的决策，以增强稳定性和安全性。总之，短语与浮心垂直之后概括了船舶设计和流体动力学的一个基本方面。它突出了船舶的浮心与在各种条件下的稳定性之间的关系。通过掌握这一概念，工程师和船舶设计师可以设计出更安全、更高效的船只，使其在充满挑战的海洋环境中表现良好。理解这些原理不仅有助于海军项目的成功，还确保了航行者的安全。