aerostatic
简明释义
adj. 航空的;空气静力学的
英英释义
Relating to or denoting the study of gases at rest, particularly the behavior of gases under pressure. | 与气体静止状态的研究有关,特别是气体在压力下的行为。 |
单词用法
空气静压轴承;空气静力轴承 |
同义词
| 浮力的 | 浮力使气球上升。 | ||
| 空气的 | 航空调查是通过飞机进行的。 | ||
| 大气的 | 大气压力影响天气模式。 |
反义词
例句
1.As the precision and ultra-precision technologies are developing in leaps and bounds, continuous improvements are also required in the stiffness, accuracy and stability of aerostatic bearings.
随着精密、超精密技术的飞速发展,对气体静压轴承的刚度、精度及稳定性的要求也不断地提高。
2.Porous material can supply millions of micro-hole regarded as countless throttle, therefore porous aerostatic bearings have high load capacity and static stiffness.
由于多孔质材料的特殊性,可以提供成千上万的微孔作为轴承节流器,因而多孔质气体静压轴承具有很高的承载能力和静态刚度。
3.Since uncertain conditions of bridge structure and the wind circumstance should be accounted for, occurrence of flutter and aerostatic instability is therefor uncertain.
由于桥梁本身及其所处风环境的不确定性,桥梁颤振与气静力失稳的发生也是不确定的。
4.The aerostatic guide way is a sort of thrust bearing, and is applied to linear air guide way widely.
空气静压导轨是空气静压止推轴承的一种,在直线气浮导轨中被广泛采用。
5.The conclusions of this paper gave some certain practical significance to the design and manufacture of aerostatic cylindricalbearings.
本文的结论对气体静压轴承的设计与制造。具有一定的实际意义。
6.The loading capacity is an important index of the aerostatic guide way.
承载能力是静压气浮导轨的一个重要的静态性能指标。
7.An aerostatic 气静力学 balance helps in measuring the lifting force of gases.
一种aerostatic 气静力学 平衡装置有助于测量气体的升力。
8.The balloon's flight is governed by aerostatic 气静力学 principles that determine its buoyancy.
气球的飞行受制于aerostatic 气静力学 原理,这决定了它的浮力。
9.The study of aerostatic 气静力学 is crucial for understanding how lighter-than-air crafts operate.
研究aerostatic 气静力学 对于理解比空气轻的飞行器如何运作至关重要。
10.Engineers must consider aerostatic 气静力学 forces when designing airships.
工程师在设计飞艇时必须考虑aerostatic 气静力学 力。
11.Understanding aerostatic 气静力学 is essential for anyone pursuing a career in aviation.
理解aerostatic 气静力学 对于任何追求航空事业的人来说都是必不可少的。
作文
The concept of buoyancy has fascinated humans for centuries, leading to the development of various technologies that utilize the principles of air and gas. One such principle is known as aerostatic, which refers to the study of gases at rest and their behavior under different conditions. Understanding aerostatic forces is essential for the design and operation of lighter-than-air vehicles, such as balloons and airships. These vehicles rely on the ability of a gas, typically helium or hot air, to lift them against the force of gravity, demonstrating the practical applications of aerostatic principles.In the realm of physics, aerostatic pressure plays a crucial role in determining how these vehicles operate. When a balloon is filled with a gas that is less dense than the surrounding air, it creates an upward force known as buoyancy. This force is a direct result of the difference in pressure between the inside of the balloon and the outside atmosphere. The aerostatic pressure can be calculated using the ideal gas law, which relates the pressure, volume, and temperature of a gas. By manipulating these variables, engineers can design balloons that can rise, hover, or descend at will.Moreover, the principles of aerostatic equilibrium are not limited to balloons; they also apply to various other fields, including meteorology and engineering. For instance, meteorologists study aerostatic forces to understand weather patterns and phenomena such as clouds and storms. The balance of atmospheric pressure can lead to significant weather changes, affecting everything from local climates to global weather systems.In engineering, particularly in the design of aircraft and spacecraft, aerostatic principles are vital. Engineers must account for the forces acting on an object at rest in a fluid (in this case, air) to ensure stability and safety during flight. This involves complex calculations and simulations to predict how a vehicle will respond to various aerostatic conditions. Furthermore, the study of aerostatic phenomena extends to the development of new technologies. For example, researchers are exploring the potential of using aerostatic principles in drone technology, where understanding the balance of forces can enhance flight efficiency and control. As drones become more prevalent in various industries, mastering aerostatic concepts will be crucial for innovation and safety.In conclusion, the term aerostatic encompasses a wide range of applications and implications in both science and technology. From the simple joy of watching a balloon float to the complexities of designing advanced flying machines, understanding aerostatic forces is fundamental. As we continue to explore the skies and develop new aerial technologies, the importance of aerostatic principles will only grow, providing exciting opportunities for future advancements in aviation and beyond.
浮力的概念几个世纪以来一直吸引着人类,促使我们开发出多种利用空气和气体原理的技术。其中一个原理被称为aerostatic,它指的是静止气体的研究及其在不同条件下的行为。理解aerostatic力对于设计和操作比空气轻的飞行器(如气球和飞艇)至关重要。这些飞行器依赖于气体(通常是氦气或热空气)能够抵抗重力将其提升的能力,展示了aerostatic原理的实际应用。在物理学领域,aerostatic压力在确定这些飞行器如何操作方面发挥着关键作用。当气球充满一种比周围空气密度小的气体时,它会产生一种称为浮力的向上力。这种力量直接源于气球内部与外部大气之间压力的差异。aerostatic压力可以使用理想气体定律进行计算,该定律将气体的压力、体积和温度联系起来。通过操控这些变量,工程师可以设计出可以随意上升、悬停或下降的气球。此外,aerostatic平衡的原理不仅限于气球;它们还适用于其他多个领域,包括气象学和工程学。例如,气象学家研究aerostatic力以理解天气模式和云层、风暴等现象。大气压力的平衡可能导致重大天气变化,影响从地方气候到全球天气系统的一切。在工程学中,特别是在飞机和航天器的设计中,aerostatic原理至关重要。工程师必须考虑在流体(此处为空气)中静止物体上作用的力,以确保飞行过程中的稳定性和安全性。这涉及复杂的计算和模拟,以预测物体在各种aerostatic条件下的反应。此外,aerostatic现象的研究还扩展到新技术的开发。例如,研究人员正在探索在无人机技术中使用aerostatic原理的潜力,理解力的平衡可以提高飞行效率和控制能力。随着无人机在各个行业的普及,掌握aerostatic概念对创新和安全至关重要。总之,术语aerostatic涵盖了科学和技术中广泛的应用和含义。从简单的观看气球漂浮的乐趣,到设计先进飞行器的复杂性,理解aerostatic力是基础。随着我们继续探索天空并开发新的航空技术,aerostatic原理的重要性只会增加,为未来在航空及其他领域的进步提供令人兴奋的机会。
