deformation

简明释义

英[ˌdiːfɔːˈmeɪʃn]美[ˌdiːfɔːrˈmeɪʃn]

n. 变形

复 数 d e f o r m a t i o n s

英英释义

单词用法

同义词

反义词

例句

1.The invariant space has to be as well a deformation of a classical space, a deformation that makes it noncommutative.

这些不变的空间同样也是经典空间的变形，它们通过这种变形成为非对易空间。

2.Oh, boy, look at that-- there's clear deformation now.

哦，看看这个-,它有了很明显的变形。

3.The experiment on bolt of compatibility and deformation is basilica for mechanics.

螺栓变形协调实验是机械类专业的一项重要实验。

4.We need to consider the deformation of only one strip parallel to generatrix of the cylinder.

我们只需要考虑一个平行于圆柱母线的窄条的变形。

5.The material itself in stamping, or transportation, that cause deformation.

素材本身在冲压时，或运输时，即造成变形。

6.And you will see after a while that you get permanent deformation, then it no longer comes back to its original length.

你会看到不久后，它会发生永久变形，它不会再回到，原长。

7.The engineer noted that the bridge showed signs of deformation due to the heavy load it was carrying.

工程师注意到这座桥因承载重物而出现了变形的迹象。

8.In geology, deformation refers to the changes in the shape or volume of rocks.

在地质学中，变形指的是岩石形状或体积的变化。

9.Metal can undergo deformation when subjected to high temperatures and pressures.

金属在高温和高压下可能会发生变形。

10.The artist used clay to demonstrate the deformation of figures in her sculpture.

艺术家用粘土展示她雕塑中人物的变形。

11.The deformation of the tire was evident after driving over the sharp object.

在驶过尖锐物体后，轮胎的变形显而易见。

作文

Deformation is a term that refers to the alteration of the shape or size of an object due to applied forces or environmental conditions. This concept is crucial in various fields, including engineering, geology, and materials science. Understanding deformation (变形) is essential for designing structures that can withstand external pressures without failing. For instance, when engineers design bridges, they must account for the potential deformation (变形) that may occur due to heavy traffic or natural forces such as wind and earthquakes. In the realm of geology, deformation (变形) plays a significant role in shaping the Earth's crust. Tectonic plates are constantly moving, and their interactions can lead to various forms of deformation (变形), including folding and faulting. These geological processes are responsible for the formation of mountains, valleys, and other landforms. By studying deformation (变形), geologists can better understand the history of our planet and predict future geological events. Materials science also heavily relies on the study of deformation (变形). When materials are subjected to stress, they can undergo elastic or plastic deformation (变形). Elastic deformation (变形) occurs when a material returns to its original shape after the stress is removed, while plastic deformation (变形) involves a permanent change in shape. Engineers must consider these properties when selecting materials for construction projects. For example, metals like steel can endure significant deformation (变形) before breaking, making them ideal for use in skyscrapers and bridges. In everyday life, we encounter deformation (变形) in various forms. A simple example is the bending of a rubber band when stretched. The rubber band experiences elastic deformation (变形) as it can return to its original shape once the force is removed. Conversely, if we stretch the rubber band too far, it may undergo plastic deformation (变形) and not return to its original form. This principle can be observed in many materials, from clay to metal, illustrating the importance of understanding deformation (变形) in both practical and theoretical contexts. Moreover, the concept of deformation (变形) extends beyond physical objects; it can also be applied to abstract ideas. In psychology, for instance, cognitive deformation (变形) refers to the distortion of thoughts and perceptions that can affect an individual's mental health. Recognizing these distortions is vital for effective therapy and personal development. In conclusion, deformation (变形) is a multifaceted concept that permeates various disciplines, from engineering to psychology. Its implications are vast, influencing how we design structures, understand geological processes, and even how we perceive our thoughts. By gaining a deeper understanding of deformation (变形), we can apply this knowledge to create more resilient structures, comprehend the Earth's dynamics, and foster healthier mental frameworks. As we continue to explore and learn about deformation (变形), we unlock new possibilities for innovation and improvement in both our physical and mental environments.

变形是一个术语，指的是由于施加的力或环境条件而改变物体的形状或大小。这个概念在工程、地质学和材料科学等多个领域中至关重要。理解deformation（变形）对于设计能够承受外部压力而不失效的结构至关重要。例如，当工程师设计桥梁时，他们必须考虑由于重型交通或自然力量（如风和地震）可能发生的deformation（变形）。在地质学领域，deformation（变形）在塑造地壳方面也起着重要作用。构造板块不断移动，它们的相互作用可能导致各种形式的deformation（变形），包括褶皱和断层。这些地质过程负责形成山脉、山谷和其他地貌。通过研究deformation（变形），地质学家可以更好地理解我们星球的历史，并预测未来的地质事件。 材料科学也严重依赖于对deformation（变形）的研究。当材料受到应力时，它们可能经历弹性或塑性deformation（变形）。弹性deformation（变形）发生在材料在去除应力后恢复到原始形状时，而塑性deformation（变形）则涉及形状的永久性变化。工程师在选择建筑项目的材料时必须考虑这些性质。例如，像钢这样的金属可以承受显著的deformation（变形），而不会断裂，使它们非常适合用于摩天大楼和桥梁。 在日常生活中，我们以各种形式遇到deformation（变形）。一个简单的例子是，当拉伸橡皮筋时，它会弯曲。橡皮筋经历弹性deformation（变形），因为一旦去除力，它可以恢复到其原始形状。相反，如果我们拉伸橡皮筋过远，它可能会经历塑性deformation（变形），并且不会返回到其原始形态。这一原理可以在许多材料中观察到，从粘土到金属，说明了在实际和理论背景下理解deformation（变形）的重要性。 此外，deformation（变形）的概念超越了物理对象；它也可以应用于抽象思想。例如，在心理学中，认知deformation（变形）指的是思维和感知的扭曲，这可能影响个体的心理健康。识别这些扭曲对有效治疗和个人发展至关重要。 总之，deformation（变形）是一个多方面的概念，渗透到各个学科，从工程到心理学。它的影响广泛，影响我们设计结构、理解地球动态，甚至影响我们感知思想的方式。通过深入理解deformation（变形），我们可以将这些知识应用于创造更具韧性的结构、理解地球的动态以及促进更健康的心理框架。随着我们继续探索和学习deformation（变形），我们为创新和改善我们物理和心理环境解锁了新的可能性。