plastic range

简明释义

塑性范围

英英释义

例句

1.Understanding the plastic range 塑性范围 is crucial for predicting how the material will behave under stress.

理解塑性范围 塑性范围对于预测材料在应力下的表现至关重要。

2.When designing the product, we need to consider the plastic range 塑性范围 of the materials used.

在设计产品时，我们需要考虑所用材料的塑性范围 塑性范围。

3.The research focused on expanding the plastic range 塑性范围 of the composite materials used in construction.

研究集中在扩展用于建筑的复合材料的塑性范围 塑性范围。

4.The engineer explained that the material has a wide plastic range 塑性范围, allowing it to be molded into various shapes.

工程师解释说，该材料具有广泛的塑性范围 塑性范围，可以被模制成各种形状。

5.The plastic range 塑性范围 of this polymer makes it suitable for both high and low-temperature applications.

这种聚合物的塑性范围 塑性范围使其适合高温和低温应用。

作文

The term plastic range refers to the specific range of deformation that a material can undergo without returning to its original shape once the stress is removed. This concept is crucial in various fields, especially in materials science and engineering. Understanding the plastic range of a material allows engineers and designers to predict how it will behave under different forces and conditions. For instance, metals such as steel exhibit a certain plastic range when subjected to tensile stress. When the applied force exceeds this range, the metal will deform permanently, which is an essential consideration in construction and manufacturing.In everyday life, we encounter materials with different plastic ranges. For example, clay is a material that can be molded easily within its plastic range. Artists and potters exploit this characteristic to shape their creations. Once the clay dries and hardens, it loses its plastic range and cannot be reshaped without breaking or cracking. This property highlights the importance of understanding the plastic range in both artistic and practical applications.Moreover, the plastic range is not limited to just solid materials. In the realm of polymers and plastics, the plastic range plays a significant role in determining how these materials can be processed and utilized. For instance, thermoplastics can be heated and reshaped multiple times within their plastic range, making them highly versatile for manufacturing various products, from containers to automotive parts. On the other hand, thermosetting plastics have a defined plastic range that, once exceeded, leads to irreversible changes in their structure, making them rigid and heat-resistant.Understanding the plastic range also has implications in safety. In engineering applications, knowing the limits of a material's plastic range can prevent catastrophic failures. For example, in bridge construction, engineers must account for the loads that the materials will endure throughout their lifespan. If a material is pushed beyond its plastic range, it may lead to structural failure, posing risks to public safety.In conclusion, the concept of plastic range is vital across various disciplines, from engineering to art. It helps us understand how materials behave under stress and guides us in making informed decisions about material selection and application. Whether it's creating a beautiful sculpture from clay or ensuring the safety and reliability of a bridge, the plastic range remains a fundamental aspect of material science that shapes our world. By grasping the significance of the plastic range, we can harness the potential of materials more effectively, leading to innovations and advancements in technology and design.

“塑性范围”一词指的是材料在去除应力后能够经历而不恢复到其原始形状的特定变形范围。这个概念在各个领域都至关重要，特别是在材料科学和工程中。理解材料的“塑性范围”使工程师和设计师能够预测它在不同力量和条件下的行为。例如，钢等金属在受到拉伸应力时会表现出一定的“塑性范围”。当施加的力超过这个范围时，金属将永久变形，这在建筑和制造中是一个重要的考虑因素。在日常生活中，我们会遇到具有不同“塑性范围”的材料。例如，粘土是一种可以在其“塑性范围”内轻松成型的材料。艺术家和陶艺家利用这一特性来塑造他们的作品。一旦粘土干燥并硬化，它就失去了“塑性范围”，无法在不破裂或开裂的情况下重新塑形。这一特性突显了在艺术和实际应用中理解“塑性范围”的重要性。此外，“塑性范围”不仅限于固体材料。在聚合物和塑料领域，“塑性范围”在确定这些材料如何加工和利用方面起着重要作用。例如，热塑性塑料可以在其“塑性范围”内多次加热和重塑，使其在制造各种产品（从容器到汽车零件）方面具有高度的灵活性。另一方面，热固性塑料具有明确的“塑性范围”，一旦超过，就会导致其结构不可逆转的变化，使其变得坚硬且耐热。理解“塑性范围”在安全方面也有影响。在工程应用中，了解材料“塑性范围”的极限可以防止灾难性的故障。例如，在桥梁建设中，工程师必须考虑材料在其使用寿命内所承受的负载。如果材料被推超出其“塑性范围”，可能导致结构失效，给公众安全带来风险。总之，“塑性范围”这一概念在各个学科中都至关重要，从工程到艺术。它帮助我们理解材料在应力下的行为，并指导我们在材料选择和应用方面做出明智的决定。无论是用粘土创造美丽的雕塑，还是确保桥梁的安全性和可靠性，“塑性范围”始终是塑造我们世界的材料科学的基本方面。通过掌握“塑性范围”的重要性，我们可以更有效地利用材料的潜力，从而推动技术和设计的创新与进步。