compressible

简明释义

英[kəmˈpresəb(ə)l]美[kəmˈpresəb(ə)l]

adj. 可压缩的；可压榨的

英英释义

单词用法

同义词

反义词

例句

1.But plain old bzip2 on the original XML file does 11 bytes better at generating a compressible structure than do my attempts.

原始xml文件上普通的旧bzip2在生成可压缩的结构上比我的尝试好11个字节。

2.The Vortex Dynamics Equation is developed for compressible flow and its characteristics are analyzed.

推导了可压缩流动旋涡动力学基本方程，并分析了其基本性质。

3.In the numerical simulation, a weakly compressible flow model and the body fitted grid technique are used.

在数值模拟中，采用了弱压缩流的控制方程，用贴体坐标技术进行了网格生成。

4.Thermal protection with down insulation for extreme cold: ultra light, ultra compressible.

超轻保温羽绒衣，适合寒冷地方使用，超轻，可压缩收藏。

5.This paper presents a new method of calculating depth of compressible stratum, in which a viscoelastic-plastic model was adopted.

本文采用粘弹塑性模型，提出计算地基变形及有效压缩层深度的新方法。

6.Effect of compressible term and that of viscous term are different in different time.

压缩项和粘性项的影响则随时间的不同而不同。

7.An implicit time-marching method is presented for computing the three-dimensional steady inviscid compressible flow fields.

本文提出了求解三维定常无粘可压缩流场问题的一种隐式时间推进法。

8.Compressible, since text files such as SQL or properties are highly redundant.

可压缩，因为文本文件，如SQL或配置文件压缩率很高。

9.In aerodynamics, understanding compressible 可压缩的 flow is crucial for designing efficient aircraft.

在空气动力学中，理解可压缩的流动对于设计高效的飞机至关重要。

10.The compressible 可压缩的 nature of gases affects how they behave under varying temperatures.

气体的可压缩的特性影响它们在不同温度下的行为。

11.When designing hydraulic systems, engineers must consider whether the fluid is compressible 可压缩的 or incompressible.

在设计液压系统时，工程师必须考虑流体是可压缩的还是不可压缩的。

12.Some materials are compressible 可压缩的, allowing them to absorb shock and reduce impact forces.

一些材料是可压缩的，允许它们吸收冲击并减少冲击力。

13.Air is a compressible 可压缩的 fluid, which means it can be reduced in volume under pressure.

空气是一种可压缩的流体，这意味着它在压力下可以减小体积。

作文

In the field of physics and engineering, the concept of compressible materials plays a crucial role in understanding how substances behave under various conditions. A compressible medium is one that can change its volume when subjected to pressure. This property is essential for many applications, ranging from fluid dynamics to material science. Understanding the behavior of compressible materials allows engineers to design systems that can withstand varying pressures and forces without failing.For instance, gases are often considered compressible because they can be easily compressed into a smaller volume when pressure is applied. This characteristic is in stark contrast to liquids and solids, which are generally regarded as incompressible. The compressible nature of gases is what enables the functioning of various technologies, such as internal combustion engines and pneumatic systems.When we talk about compressible fluids, we often refer to the compressibility factor, which measures how much a substance deviates from being incompressible. In engineering applications, especially in aerodynamics, understanding the compressibility of air at different speeds is vital. At subsonic speeds, air behaves as a compressible fluid, and engineers must account for changes in density and pressure. However, at supersonic speeds, the behavior of air becomes significantly more complex due to shock waves and other phenomena related to compressible flow.One of the most fascinating aspects of compressible materials is their application in everyday life. For example, when you inflate a balloon, you are dealing with a compressible gas. As you blow air into the balloon, the gas molecules move closer together, increasing the pressure inside the balloon and causing it to expand. This simple act demonstrates the fundamental principles of compressible behavior in a very tangible way.Moreover, the study of compressible materials extends beyond gases. Certain types of foams and elastomers are also compressible, allowing them to absorb impacts and provide cushioning. This property is particularly important in the design of safety equipment, such as helmets and padding in sports gear. By utilizing compressible materials, manufacturers can create products that enhance safety and comfort for users.In conclusion, the term compressible encompasses a wide range of materials and phenomena that are fundamental to both scientific understanding and practical applications. From the behavior of gases under pressure to the design of safety equipment, the principles underlying compressible materials are integral to various fields. As we continue to explore and innovate, the importance of understanding compressible properties will only grow, paving the way for advancements in technology and engineering that can better serve our needs. Whether in the realm of aerospace, automotive, or everyday consumer products, the knowledge of compressible materials will remain a cornerstone of modern science and engineering.

在物理和工程领域，compressible材料的概念在理解物质在各种条件下的行为方面发挥着至关重要的作用。compressible介质是指在施加压力时可以改变其体积的材料。这一特性对于许多应用至关重要，从流体动力学到材料科学。理解compressible材料的行为使工程师能够设计出能够承受不同压力和力量而不发生故障的系统。例如，气体通常被认为是compressible的，因为在施加压力时它们可以很容易地被压缩到更小的体积。这一特性与液体和固体形成鲜明对比，后者通常被视为incompressible。气体的compressible特性使得各种技术的运作成为可能，例如内燃机和气动系统。当我们谈论compressible流体时，我们通常指的是压缩因子，它衡量一种物质在多大程度上偏离了incompressible的状态。在工程应用中，尤其是在空气动力学中，理解空气在不同速度下的可压缩性至关重要。在亚音速下，空气表现为compressible流体，工程师必须考虑密度和压力的变化。然而，在超音速下，空气的行为变得复杂得多，因为涉及到冲击波和其他与compressible流动相关的现象。compressible材料最迷人的一个方面是它们在日常生活中的应用。例如，当你给气球充气时，你正在处理一种compressible气体。当你向气球吹气时，气体分子相互靠近，增加了气球内部的压力，使其膨胀。这一简单的行为以非常直观的方式展示了compressible行为的基本原理。此外，compressible材料的研究不仅限于气体。某些类型的泡沫和弹性体也是compressible的，使它们能够吸收冲击并提供缓冲。这一特性在安全设备的设计中尤为重要，例如头盔和运动装备中的衬垫。通过利用compressible材料，制造商可以创建出增强用户安全性和舒适性的产品。总之，compressible这个术语涵盖了一系列基本的材料和现象，这些现象对科学理解和实际应用至关重要。从气体在压力下的行为到安全设备的设计，compressible材料背后的原理是各个领域的基础。随着我们继续探索和创新，理解compressible特性的意义将愈加重要，为科技和工程的进步铺平道路，以更好地服务于我们的需求。无论是在航空航天、汽车还是日常消费品领域，了解compressible材料将始终是现代科学和工程的基石。