plane of buoyancy

简明释义

浮面

英英释义

例句

1.When the boat tilts, the plane of buoyancy 浮力面 shifts, affecting how it floats.

当船倾斜时，浮力面 plane of buoyancy 会发生变化，影响它的漂浮状态。

2.The ship's design ensures that the plane of buoyancy 浮力面 is always below the waterline, providing stability.

这艘船的设计确保了浮力面 plane of buoyancy 始终低于水线，从而提供稳定性。

3.The plane of buoyancy 浮力面 determines how much weight a boat can carry without sinking.

浮力面 plane of buoyancy 决定了船只在不沉没的情况下可以承载多少重量。

4.Understanding the plane of buoyancy 浮力面 is crucial for naval architects when designing vessels.

理解浮力面 plane of buoyancy 对于船舶设计师来说至关重要。

5.In calm waters, the plane of buoyancy 浮力面 remains stable, allowing for a smooth ride.

在平静的水面上，浮力面 plane of buoyancy 保持稳定，使乘坐体验平稳。

作文

Understanding the concept of buoyancy is essential in various fields, such as physics, engineering, and even everyday life. One of the key terms associated with buoyancy is the plane of buoyancy, which refers to an imaginary horizontal plane within a fluid where the upward buoyant force acts on an object submerged in that fluid. This concept plays a crucial role in determining how objects float or sink in water or any other liquid. When we think about boats, for example, the plane of buoyancy is vital to their design and functionality. A boat must displace enough water to create a buoyant force that equals its weight; otherwise, it will sink. The plane of buoyancy helps engineers calculate the necessary dimensions and shapes of hulls to ensure stability and safety at sea.In addition to maritime applications, the plane of buoyancy is also relevant in other areas, such as aerodynamics. For aircraft, understanding how buoyancy works in the air can lead to better designs and improved performance. The principles governing the plane of buoyancy can be applied to understand lift, which is crucial for an aircraft to ascend and maintain altitude. Engineers must consider the forces acting on an airplane, including gravity and buoyancy, to achieve optimal flight conditions.Moreover, the plane of buoyancy is not just a theoretical concept; it has practical implications in our daily lives. For instance, when we go swimming, we experience the effects of buoyancy firsthand. The sensation of floating is a direct result of the buoyant force acting on our bodies, which can be understood through the plane of buoyancy. Understanding this principle can help swimmers improve their techniques and enhance their overall experience in the water.Furthermore, the plane of buoyancy can also be observed in nature. Many animals, such as fish and whales, have evolved adaptations that allow them to navigate through water effortlessly. These adaptations often involve modifications in body shape and density, which directly relate to the concept of buoyancy. By studying these creatures, scientists can gain insights into the plane of buoyancy and how it affects their movement and survival in aquatic environments.In conclusion, the plane of buoyancy is a fundamental principle that underpins many aspects of physics and engineering. Its applications range from designing ships and airplanes to understanding natural phenomena and enhancing recreational activities like swimming. By grasping the significance of the plane of buoyancy, we can appreciate the intricate balance of forces that govern our interactions with fluids, whether in a controlled environment or the vastness of nature. This knowledge not only enriches our understanding of the physical world but also equips us with the tools to innovate and solve real-world challenges related to buoyancy and fluid dynamics.

理解浮力的概念在物理学、工程学甚至日常生活中都是至关重要的。与浮力相关的一个关键术语是浮力平面，它指的是在流体中一个想象的水平面，在这个面内，向上浮力作用于沉浸在该流体中的物体。这个概念在确定物体在水或任何其他液体中漂浮或下沉的方式中起着关键作用。当我们考虑船只时，浮力平面对其设计和功能至关重要。船只必须排开足够的水以产生一个等于其重量的浮力；否则，它将下沉。浮力平面帮助工程师计算必要的船体尺寸和形状，以确保在海上的稳定性和安全性。除了海事应用外，浮力平面在其他领域也同样相关，例如空气动力学。对于飞机来说，理解浮力在空气中的工作原理可以导致更好的设计和改进的性能。 governing the 浮力平面的原理可以应用于理解升力，这是飞机上升和保持高度的关键。工程师必须考虑施加在飞机上的力量，包括重力和浮力，以实现最佳飞行条件。此外，浮力平面不仅是一个理论概念；它在我们日常生活中也有实际的影响。例如，当我们游泳时，我们亲身体验到浮力的效果。漂浮的感觉直接是由于浮力作用在我们身体上的结果，这可以通过浮力平面来理解。理解这一原理可以帮助游泳者改善他们的技巧，并增强他们在水中的整体体验。此外，浮力平面还可以在自然中观察到。许多动物，如鱼和鲸，已经进化出适应性，使它们能够轻松地在水中导航。这些适应通常涉及身体形状和密度的变化，这与浮力的概念直接相关。通过研究这些生物，科学家可以深入了解浮力平面及其如何影响它们在水生环境中的运动和生存。总之，浮力平面是支撑物理学和工程学许多方面的基本原理。它的应用范围从设计船只和飞机到理解自然现象以及增强游泳等休闲活动。通过掌握浮力平面的重要性，我们可以欣赏到控制环境或自然广阔空间中流体作用力之间复杂的平衡。这一知识不仅丰富了我们对物理世界的理解，还为我们提供了创新和解决与浮力和流体动力学相关的现实挑战的工具。