effective elongation

简明释义

实际伸长

英英释义

例句

1.In rubber manufacturing, the effective elongation 有效延伸 is crucial for determining the product's durability.

在橡胶制造中，有效延伸 有效延伸 对于确定产品的耐用性至关重要。

2.The testing results revealed that the effective elongation 有效延伸 of the polymer was higher than expected.

测试结果显示，该聚合物的有效延伸 有效延伸 超出了预期。

3.Engineers must account for the effective elongation 有效延伸 of cables when designing suspension bridges.

工程师在设计悬索桥时必须考虑电缆的有效延伸 有效延伸。

4.The material showed an impressive effective elongation 有效延伸 under tensile testing, indicating its flexibility.

该材料在拉伸测试中显示出令人印象深刻的有效延伸 有效延伸，表明其灵活性。

5.Understanding the effective elongation 有效延伸 helps in selecting the right materials for construction projects.

理解有效延伸 有效延伸 有助于为建筑项目选择合适的材料。

作文

In the realm of materials science and engineering, the term effective elongation refers to a critical property that indicates how much a material can stretch before it breaks. Understanding this concept is essential for engineers and designers who work with various materials, as it directly impacts the durability and performance of products. 有效延伸不仅仅是材料的物理特性，它还反映了材料在承受负荷时的行为和反应。When we talk about effective elongation, we are often considering the strain experienced by a material under stress. This property is particularly important in industries such as construction, automotive, and aerospace. For example, metals used in building structures must have a high effective elongation to withstand forces without fracturing, ensuring safety and longevity. Similarly, in the automotive industry, components like suspension springs are designed with effective elongation in mind to absorb shocks and provide comfort to passengers.Moreover, the effective elongation can vary significantly between different materials. For instance, rubber exhibits a high effective elongation, allowing it to stretch and compress easily, which is why it is commonly used in seals and gaskets. On the other hand, materials like glass or ceramics have low effective elongation and are more prone to breaking under tension. This variance necessitates careful selection of materials based on their effective elongation properties to ensure they meet specific application requirements.Testing for effective elongation typically involves applying a tensile force to a sample material until it reaches its breaking point. The elongation at this point provides valuable data for engineers. This information is crucial not only for selecting materials but also for predicting how they will perform over time under various conditions. For instance, if a material has a low effective elongation, it may be unsuitable for applications where flexibility and resilience are required.Additionally, the implications of effective elongation extend beyond just the physical properties of materials. It also plays a role in sustainability and environmental considerations. As industries strive to develop more sustainable practices, understanding the effective elongation of materials can lead to better recycling processes and the creation of more durable products, ultimately reducing waste.In conclusion, the concept of effective elongation is fundamental to the field of materials science and engineering. It serves as a key indicator of a material's ability to endure stress and deformation, influencing design decisions across various industries. By prioritizing materials with optimal effective elongation properties, engineers can create safer, more efficient, and sustainable products that meet the demands of modern society. As we continue to innovate and advance technologically, the importance of understanding effective elongation will only increase, shaping the future of material selection and application.

在材料科学和工程领域，术语有效延伸指的是一个关键特性，表明材料在断裂之前能够拉伸多少。理解这个概念对于工程师和设计师来说至关重要，因为它直接影响到产品的耐用性和性能。有效延伸不仅仅是材料的物理特性，它还反映了材料在承受负荷时的行为和反应。当我们谈论有效延伸时，我们通常考虑的是材料在应力下经历的应变。这个特性在建筑、汽车和航空航天等行业中尤为重要。例如，用于建筑结构的金属必须具有高有效延伸以承受力而不破裂，从而确保安全和耐久性。同样，在汽车行业，像悬挂弹簧这样的组件在设计时也考虑到了有效延伸，以吸收冲击并为乘客提供舒适感。此外，有效延伸在不同材料之间可能有显著差异。例如，橡胶表现出高有效延伸，允许其轻松拉伸和压缩，这就是它常用于密封件和垫圈的原因。另一方面，玻璃或陶瓷等材料的有效延伸较低，更容易在拉伸下破裂。这种差异要求根据材料的有效延伸特性仔细选择材料，以确保它们满足特定的应用要求。测试有效延伸通常涉及对样本材料施加拉伸力，直到达到断裂点。此时的延伸提供了对工程师非常有价值的数据。这些信息不仅对选择材料至关重要，还对预测它们在各种条件下随时间的表现至关重要。例如，如果一种材料的有效延伸较低，则可能不适合需要灵活性和韧性的应用。此外，有效延伸的影响不仅限于材料的物理特性。它还在可持续性和环境考虑方面发挥作用。随着各行业努力发展更可持续的实践，理解材料的有效延伸可以导致更好的回收过程和更耐用产品的创造，最终减少浪费。总之，有效延伸的概念对材料科学和工程领域至关重要。它作为材料承受应力和变形能力的关键指标，影响着各个行业的设计决策。通过优先选择具有最佳有效延伸特性的材料，工程师可以创造出更安全、更高效和更可持续的产品，以满足现代社会的需求。随着我们不断创新和技术进步，理解有效延伸的重要性只会增加，塑造材料选择和应用的未来。