degree of deformation

简明释义

变形度

英英释义

例句

1.During the experiment, we observed the degree of deformation 变形程度 of the rubber under different temperatures.

在实验中，我们观察了橡胶在不同温度下的变形程度。

2.The engineers measured the degree of deformation 变形程度 in the metal after it was subjected to stress.

工程师们测量了金属在承受压力后其变形程度。

3.The degree of deformation 变形程度 of the bridge was assessed to ensure safety for vehicles.

对桥梁的变形程度进行了评估，以确保车辆安全通过。

4.A higher degree of deformation 变形程度 can indicate a material's failure point.

更高的变形程度可能表明材料的失效点。

5.In geological studies, the degree of deformation 变形程度 of rocks can reveal tectonic activity.

在地质研究中，岩石的变形程度可以揭示构造活动。

作文

The study of materials and their properties is a crucial aspect of engineering and physics. One of the essential concepts in this field is the degree of deformation, which refers to the extent to which a material changes shape or size under applied forces. Understanding the degree of deformation is vital for predicting how materials will behave when subjected to stress, which is particularly important in construction, manufacturing, and various scientific applications.When a force is applied to an object, it can cause the object to deform. This deformation can be elastic, meaning the object returns to its original shape once the force is removed, or plastic, indicating that the object will retain its new shape even after the force has ceased. The degree of deformation helps engineers determine whether a material will behave elastically or plastically under certain conditions.For example, consider a metal beam used in a building structure. When weight is applied to the beam, it experiences stress. If the degree of deformation is within the elastic limit of the material, the beam will bend slightly but will return to its original position once the weight is removed. However, if the weight exceeds the material's capacity, the degree of deformation may lead to permanent bending or even breaking. Thus, knowing the degree of deformation is essential for ensuring safety and stability in engineering designs.In addition to structural applications, the degree of deformation is also significant in manufacturing processes such as forging and molding. During these processes, materials are intentionally deformed to achieve desired shapes and properties. Engineers must carefully control the degree of deformation to ensure that the final product meets quality standards and performs as expected in its intended application.Moreover, the degree of deformation can vary significantly between different materials. For instance, rubber exhibits a high degree of deformation when stretched, making it an ideal choice for applications requiring flexibility. Conversely, ceramics typically have a low degree of deformation and can fracture easily under stress. Understanding these differences allows engineers to select appropriate materials for specific applications based on the required degree of deformation and other mechanical properties.The concept of degree of deformation is also relevant in fields such as geology and biology. In geology, the degree of deformation of rocks can provide insights into tectonic movements and the history of the Earth’s crust. In biology, understanding how cells deform under various conditions can inform research in areas such as tissue engineering and regenerative medicine.In conclusion, the degree of deformation is a fundamental concept that plays a critical role in various fields, including engineering, manufacturing, geology, and biology. By understanding how materials respond to applied forces and the implications of their degree of deformation, professionals can make informed decisions that enhance safety, functionality, and innovation in their respective disciplines. As technology continues to evolve, the importance of accurately measuring and predicting the degree of deformation will only increase, paving the way for advancements in material science and engineering practices.

材料及其特性的研究是工程和物理学的重要方面。在这个领域中，一个基本概念是变形程度，它指的是材料在施加力的情况下形状或大小变化的程度。理解变形程度对于预测材料在应力下的表现至关重要，这在建筑、制造和各种科学应用中尤为重要。当一个力施加到物体上时，它可能会导致物体变形。这种变形可以是弹性的，意味着物体在去除力后会恢复到原来的形状，或者是塑性的，表示物体在力停止后将保持新的形状。变形程度帮助工程师确定材料在某些条件下是弹性行为还是塑性行为。例如，考虑用于建筑结构的金属梁。当重量施加到梁上时，它会经历应力。如果变形程度在材料的弹性极限之内，梁会稍微弯曲，但在去除重量后会恢复到原来的位置。然而，如果重量超过材料的承载能力，变形程度可能导致永久性弯曲甚至断裂。因此，了解变形程度对于确保工程设计的安全性和稳定性至关重要。除了结构应用，变形程度在锻造和成型等制造过程中也很重要。在这些过程中，材料被故意变形以实现所需的形状和性能。工程师必须仔细控制变形程度，以确保最终产品符合质量标准，并在预期应用中按预期性能表现。此外，不同材料之间的变形程度可能有显著差异。例如，橡胶在拉伸时表现出高变形程度，使其成为需要灵活性的应用的理想选择。相反，陶瓷通常具有低变形程度，在应力下容易断裂。理解这些差异使工程师能够根据所需的变形程度和其他机械属性选择适合特定应用的材料。变形程度的概念在地质学和生物学等领域也相关。在地质学中，岩石的变形程度可以提供有关构造运动和地球地壳历史的见解。在生物学中，理解细胞在各种条件下如何变形可以为组织工程和再生医学等领域的研究提供信息。总之，变形程度是一个基本概念，在工程、制造、地质学和生物学等各个领域发挥着关键作用。通过理解材料对施加力的响应及其变形程度的影响，专业人士可以做出明智的决策，从而增强其各自学科的安全性、功能性和创新性。随着技术的不断发展，准确测量和预测变形程度的重要性只会增加，为材料科学和工程实践的进步铺平道路。