pitched buoyancy

简明释义

纵摇浮力

英英释义

例句

1.Understanding pitched buoyancy is crucial for designing aircraft that can handle turbulence effectively.

理解倾斜浮力对于设计能够有效应对湍流的飞机至关重要。

2.The engineer calculated the pitched buoyancy to ensure the boat would remain stable in rough waters.

工程师计算了倾斜浮力以确保船只在波涛汹涌的水域中保持稳定。

3.In the sailing competition, the team focused on optimizing their pitched buoyancy for better performance.

在帆船比赛中，团队专注于优化他们的倾斜浮力以获得更好的表现。

4.The research paper discussed the effects of pitched buoyancy on the stability of floating structures.

研究论文讨论了倾斜浮力对浮动结构稳定性的影响。

5.During the simulation, we observed how pitched buoyancy affected the vessel's maneuverability.

在模拟过程中，我们观察到倾斜浮力如何影响船舶的机动性。

作文

In the realm of physics, particularly in fluid mechanics, the concept of buoyancy plays a crucial role in understanding how objects behave when placed in a fluid. One intriguing aspect of this phenomenon is what is known as pitched buoyancy. This term refers to the specific orientation and stability of an object floating in a fluid, influenced by its shape, weight distribution, and the characteristics of the fluid itself. To grasp the significance of pitched buoyancy, we must first explore the fundamental principles of buoyancy. Buoyancy is the upward force exerted by a fluid on an object submerged in it. This force counteracts the weight of the object, allowing it to float or remain suspended in the fluid. The classic example is a ship floating on water; the ship displaces a volume of water equal to its weight, resulting in a stable floating condition. However, when the ship tilts or pitches, the dynamics change, leading us to the notion of pitched buoyancy. The term pitched buoyancy implies that the object is not just floating but also oriented at an angle, which can affect its stability. For instance, consider a sailboat. When it sails, the wind causes the boat to tilt, creating a situation where the center of gravity shifts. This shift can either enhance or diminish the pitched buoyancy depending on how well the boat is designed to handle such changes. A well-designed sailboat will have its pitched buoyancy optimized, allowing it to glide smoothly through the water even when tilted, while a poorly designed one may capsize. Understanding pitched buoyancy is essential not only for naval architecture but also for various applications in engineering and design. For example, engineers must consider pitched buoyancy when designing offshore platforms, submarines, and even underwater drones. Each of these objects must maintain stability in different orientations to function effectively. Moreover, pitched buoyancy has implications beyond engineering. In sports like sailing and surfing, athletes must be acutely aware of how their equipment interacts with water. A surfer, for instance, needs to understand how their board's shape affects its pitched buoyancy to catch waves effectively. Similarly, sailors must know how to adjust their sails and weight distribution to optimize their vessel's pitched buoyancy for speed and maneuverability. In conclusion, the concept of pitched buoyancy is a fascinating intersection of physics, engineering, and practical application. It illustrates how the orientation of an object in a fluid can significantly impact its stability and performance. Whether in the design of boats, the operation of submarines, or the enjoyment of water sports, understanding pitched buoyancy is vital for achieving success. As we continue to explore the complexities of fluid dynamics, the importance of this concept will undoubtedly remain at the forefront of both scientific inquiry and practical innovation.

在物理学领域，特别是在流体力学中，浮力的概念在理解物体在液体中行为时起着至关重要的作用。这个现象中一个引人入胜的方面是被称为倾斜浮力的概念。这个术语指的是当一个物体漂浮在液体中时，其特定的方向和稳定性，这受到物体的形状、重量分布以及液体本身的特性影响。要理解倾斜浮力的重要性，我们首先必须探索浮力的基本原理。浮力是液体对浸没在其中的物体施加的向上力。这种力量抵消了物体的重量，使其能够漂浮或保持在液体中悬浮。经典的例子是船只在水面上漂浮；船只排开一个等于其重量的水量，从而形成一种稳定的漂浮状态。然而，当船只倾斜或倾斜时，动态会发生变化，这就引出了倾斜浮力的概念。术语倾斜浮力意味着物体不仅仅是漂浮的，而且还以一个角度定向，这可以影响其稳定性。例如，考虑一艘帆船。当它航行时，风会使船倾斜，造成重心的移动。这种移动可能增强或削弱倾斜浮力，具体取决于船的设计如何处理这种变化。一艘设计良好的帆船将优化其倾斜浮力，即使在倾斜时也能平稳滑行，而一艘设计不佳的帆船可能会翻覆。理解倾斜浮力不仅对船舶建筑至关重要，而且对工程和设计中的各种应用也至关重要。例如，工程师在设计海上平台、潜艇甚至水下无人机时必须考虑倾斜浮力。每一个物体都必须在不同的方向上保持稳定，以有效运作。此外，倾斜浮力在运动中也有影响，如帆船和冲浪，运动员必须敏锐地意识到他们的设备与水的互动。冲浪者，例如，需要理解他们的板的形状如何影响其倾斜浮力以有效捕捉波浪。类似地，水手必须知道如何调整他们的帆和重量分布，以优化他们的船只的倾斜浮力以获得速度和机动性。总之，倾斜浮力的概念是物理学、工程学和实际应用之间的迷人交集。它说明了物体在液体中的方向如何显著影响其稳定性和性能。无论是在船只设计、潜艇操作还是水上运动的乐趣中，理解倾斜浮力对取得成功至关重要。随着我们继续探索流体动力学的复杂性，这一概念的重要性无疑将始终处于科学研究和实际创新的前沿。