absolute deformation

简明释义

绝对变形

英英释义

例句

1.The engineer calculated the absolute deformation 绝对变形 of the bridge to ensure it could withstand heavy loads.

工程师计算了桥梁的绝对变形 absolute deformation，以确保其能够承受重载。

2.During the test, the absolute deformation 绝对变形 of the sample was recorded to assess its durability.

在测试过程中，记录了样本的绝对变形 absolute deformation 以评估其耐用性。

3.The technician measured the absolute deformation 绝对变形 of the metal after it was subjected to high temperatures.

技术员在金属经历高温后测量了其绝对变形 absolute deformation。

4.The absolute deformation 绝对变形 of the rubber material was significantly higher than expected.

橡胶材料的绝对变形 absolute deformation 明显高于预期。

5.In material science, understanding absolute deformation 绝对变形 is crucial for predicting how substances will behave under stress.

在材料科学中，理解绝对变形 absolute deformation 对于预测物质在应力下的行为至关重要。

作文

In the field of materials science and engineering, understanding the behavior of materials under various conditions is crucial. One important concept that often arises in this context is absolute deformation. This term refers to the total change in shape or size of an object when subjected to external forces. It encompasses both elastic and plastic deformations, providing a comprehensive view of how materials respond to stress. Absolute deformation can be observed in various applications, from construction materials like concrete and steel to biological tissues. When we apply a force to a material, it may initially deform elastically, meaning that it will return to its original shape once the force is removed. However, if the force exceeds a certain threshold, the material may undergo plastic deformation, leading to permanent changes in its structure. The study of absolute deformation helps engineers predict how materials will behave under different loading conditions, ensuring safety and functionality in design.For instance, consider the construction of a bridge. Engineers must account for the absolute deformation of the materials used, as they will experience significant loads from vehicles, wind, and other environmental factors. If the materials do not perform as expected, the bridge could suffer from structural failure. Therefore, understanding the absolute deformation of the materials involved is essential for making informed decisions during the design phase.Moreover, absolute deformation is also relevant in the field of biomechanics. For example, when analyzing human tissues, researchers examine how muscles and ligaments deform under stress. This understanding can lead to better treatments for injuries and improved designs for prosthetics. By studying the absolute deformation of biological materials, scientists can develop solutions that mimic natural movements and provide support to individuals with mobility challenges.In addition to practical applications, the concept of absolute deformation also has theoretical implications. It allows scientists to explore the fundamental properties of materials, such as their strength, ductility, and resilience. By examining how materials deform under various conditions, researchers can gain insights into their molecular structure and the mechanisms that govern their behavior. This knowledge can lead to the development of new materials with enhanced properties, paving the way for innovations in technology and industry.In conclusion, absolute deformation is a vital concept in materials science and engineering that describes the total change in shape or size of an object due to external forces. Its significance spans various fields, from construction to biomechanics, highlighting the importance of understanding material behavior in real-world applications. By studying absolute deformation, engineers and scientists can ensure safety, improve designs, and innovate new materials that meet the demands of modern society.

在材料科学和工程领域，理解材料在各种条件下的行为至关重要。一个经常出现的重要概念是绝对变形。这个术语指的是当物体受到外力作用时，其形状或大小的总变化。它包括弹性变形和塑性变形，为材料在应力下的响应提供了全面的视角。绝对变形可以在各种应用中观察到，从建筑材料如混凝土和钢铁到生物组织。当我们对材料施加力时，它可能最初会弹性变形，这意味着一旦去除力，它将恢复到原来的形状。然而，如果力超过某个阈值，材料可能会经历塑性变形，导致其结构的永久性变化。研究绝对变形有助于工程师预测材料在不同加载条件下的表现，确保设计的安全性和功能性。例如，考虑桥梁的建造。工程师必须考虑所用材料的绝对变形，因为它们将承受来自车辆、风和其他环境因素的显著负荷。如果材料的表现未达到预期，桥梁可能会遭受结构失效。因此，理解所涉及材料的绝对变形对于设计阶段做出明智决策至关重要。此外，绝对变形在生物力学领域也相关。例如，在分析人体组织时，研究人员检查肌肉和韧带在应力下的变形方式。这种理解可以导致更好的伤害治疗和改进假肢设计。通过研究生物材料的绝对变形，科学家可以开发出模仿自然运动并为行动障碍者提供支持的解决方案。除了实际应用之外，绝对变形的概念还有理论意义。它允许科学家探索材料的基本特性，如强度、延展性和韧性。通过检查材料在各种条件下的变形，研究人员可以深入了解其分子结构和支配其行为的机制。这些知识可以导致新材料的开发，具有增强的性能，为技术和工业的创新铺平道路。总之，绝对变形是材料科学和工程中的一个重要概念，描述了物体因外力作用而发生的形状或大小的总变化。它的重要性跨越多个领域，从建筑到生物力学，突显了理解材料行为在现实应用中的重要性。通过研究绝对变形，工程师和科学家可以确保安全性、改善设计，并创新满足现代社会需求的新材料。