dimensional deformation

简明释义

外部变形

英英释义

例句

1.The designer had to account for potential dimensional deformation 尺寸变形 when creating the product specifications.

设计师在制定产品规格时必须考虑潜在的尺寸变形。

2.In the manufacturing process, dimensional deformation 尺寸变形 can lead to parts not fitting together properly.

在制造过程中，尺寸变形可能导致零件无法正确配合。

3.The team conducted tests to measure the dimensional deformation 尺寸变形 of the material under stress.

团队进行了测试，以测量材料在应力下的尺寸变形。

4.The engineer noted that the component showed significant dimensional deformation 尺寸变形 after being subjected to high temperatures.

工程师注意到该部件在经历高温后出现了显著的尺寸变形。

5.After the earthquake, many buildings exhibited dimensional deformation 尺寸变形 that compromised their structural integrity.

地震后，许多建筑物显示出尺寸变形，这影响了它们的结构完整性。

作文

The concept of dimensional deformation refers to the change in shape or size of an object due to various forces acting upon it. This phenomenon is crucial in fields such as engineering, physics, and materials science, where understanding how materials respond to stress and strain is essential for designing durable structures and products. Dimensional deformation can occur in many forms, including stretching, compressing, bending, and twisting. Each type of deformation has its own implications and applications, making it a vital area of study.In engineering, for instance, when designing a bridge, engineers must consider how the materials will react to the weight of vehicles and environmental factors such as wind and temperature changes. If the materials used do not have the appropriate strength or flexibility, they may undergo dimensional deformation, leading to structural failure. Therefore, selecting the right materials and understanding their properties is essential to ensure that the bridge remains safe and functional over time.Moreover, dimensional deformation is not limited to macroscopic objects. On a microscopic level, materials can also experience changes in their atomic structure when subjected to extreme conditions. For example, metals can become more malleable or brittle depending on the temperature and the forces applied to them. This behavior is critical in manufacturing processes, where materials are often shaped through techniques such as forging, casting, or machining. Understanding dimensional deformation at this level allows engineers to optimize these processes for better efficiency and product quality.In the realm of technology, dimensional deformation plays a significant role in the development of flexible electronics. As devices become thinner and more portable, the materials used must withstand bending and stretching without losing functionality. Researchers are continually exploring new materials and designs that can endure these stresses while maintaining performance. Innovations in this area could lead to advancements in wearable technology, flexible displays, and other applications that require materials to adapt to various shapes and movements.Furthermore, dimensional deformation is also a critical consideration in the field of geophysics. The Earth's crust is constantly undergoing stress due to tectonic movements, which can lead to phenomena such as earthquakes. Scientists study how the Earth's materials deform under pressure to better understand seismic activity and predict potential hazards. This knowledge is essential for developing building codes and safety measures in earthquake-prone regions.In conclusion, dimensional deformation is a multifaceted concept that impacts various industries and scientific disciplines. From construction and manufacturing to technology and geophysics, understanding how materials deform under different conditions is essential for innovation and safety. As research continues to advance, the insights gained from studying dimensional deformation will undoubtedly lead to new applications and improvements in the way we design and interact with the world around us.

“dimensional deformation”的概念是指物体因各种作用力而导致的形状或大小变化。这个现象在工程学、物理学和材料科学等领域至关重要，因为理解材料如何响应应力和应变对于设计耐用的结构和产品至关重要。“dimensional deformation”可以以多种形式发生，包括拉伸、压缩、弯曲和扭曲。每种类型的变形都有其自身的影响和应用，使其成为一个重要的研究领域。例如，在工程学中，当设计一座桥梁时，工程师必须考虑材料如何对车辆的重量和风、温度变化等环境因素作出反应。如果所使用的材料没有适当的强度或柔韧性，它们可能会经历“dimensional deformation”，导致结构失效。因此，选择合适的材料并理解其特性对于确保桥梁在长时间内保持安全和功能至关重要。此外，“dimensional deformation”不仅限于宏观物体。在微观层面上，材料在极端条件下也会经历其原子结构的变化。例如，金属在温度和施加的力量下可能变得更加延展或脆弱。这种行为在制造过程中至关重要，因为材料通常通过锻造、铸造或机械加工等技术成型。理解“dimensional deformation”在这一层面的表现使工程师能够优化这些过程，提高效率和产品质量。在技术领域，“dimensional deformation”在柔性电子产品的发展中发挥着重要作用。随着设备变得越来越薄和便携，所使用的材料必须承受弯曲和拉伸，而不会失去功能。研究人员不断探索新的材料和设计，以在保持性能的同时承受这些压力。这方面的创新可能会推动可穿戴技术、柔性显示器和其他需要材料适应各种形状和运动的应用的发展。此外，“dimensional deformation”在地球物理学领域也是一个关键考虑因素。地壳因构造运动而不断受到压力，这可能导致地震等现象。科学家研究地球材料在压力下如何变形，以更好地理解地震活动和预测潜在的危害。这些知识对于制定建筑规范和在易发生地震的地区采取安全措施至关重要。总之，“dimensional deformation”是一个多方面的概念，影响着各个行业和科学学科。从建筑和制造到技术和地球物理学，理解材料在不同条件下如何变形对于创新和安全至关重要。随着研究的不断推进，从研究“dimensional deformation”中获得的见解无疑将导致新的应用和我们设计及与周围世界互动方式的改进。