tension strength at break

简明释义

破断强度

英英释义

例句

1.The material was tested for its tension strength at break to determine its durability under stress.

该材料经过测试以确定其断裂时的抗拉强度，以评估其在压力下的耐用性。

2.The tension strength at break of this polymer is significantly higher than that of its competitors.

这种聚合物的断裂时的抗拉强度明显高于其竞争对手。

3.In the lab, we measured the tension strength at break of various fabrics to find the most resilient option.

在实验室中，我们测量了各种面料的断裂时的抗拉强度，以寻找最耐用的选项。

4.A higher tension strength at break indicates a stronger material that can withstand more force.

更高的断裂时的抗拉强度表明材料更强，可以承受更多的力量。

5.Engineers often consider the tension strength at break when selecting materials for construction projects.

工程师在选择建筑项目材料时，通常会考虑断裂时的抗拉强度。

作文

Understanding the concept of tension strength at break is crucial in various fields such as materials science, engineering, and manufacturing. This term refers to the maximum amount of tensile stress that a material can withstand before it fails or breaks. In simpler terms, it indicates how much pulling force a material can handle before it loses its structural integrity. For instance, when designing bridges or buildings, engineers must consider the tension strength at break of the materials they choose to ensure safety and stability.When materials are subjected to tensile forces, they experience deformation. Initially, they will stretch without any permanent change. However, as the force increases, there comes a point where the material reaches its elastic limit, beyond which it will not return to its original shape. The tension strength at break is the point at which the material can no longer withstand the applied stress and ultimately fractures.Different materials exhibit varying tension strength at break values. For example, metals like steel typically have high tensile strength, making them ideal for construction purposes. On the other hand, materials like rubber have lower tensile strength but offer flexibility, which is useful in different applications. Understanding these differences helps engineers and designers select the right materials for specific applications.Testing for tension strength at break is usually conducted through standardized methods such as tensile tests. In a typical tensile test, a sample of the material is pulled until it breaks. The force applied and the elongation of the material are measured and recorded. This data is then used to calculate the tensile strength, providing valuable information about the material's properties.The implications of knowing the tension strength at break extend beyond just engineering. In the textile industry, for example, understanding the tensile strength of fabrics is essential for producing durable clothing and other textile products. Similarly, in the production of ropes and cables, manufacturers must ensure that their products can withstand the required loads without breaking.In conclusion, the tension strength at break is a vital parameter that reflects a material’s ability to resist tensile forces. It plays an essential role in various industries, influencing design choices and ensuring safety. By comprehensively understanding this concept, professionals can make informed decisions that enhance the performance and reliability of their products. As technology advances, the importance of accurately determining the tension strength at break will only continue to grow, paving the way for innovations in material science and engineering practices.

理解断裂时的拉伸强度这一概念在材料科学、工程和制造等多个领域至关重要。这个术语指的是材料在破裂或断裂前能够承受的最大拉伸应力。简单来说，它表示材料在失去结构完整性之前可以承受多少拉伸力。例如，在设计桥梁或建筑物时，工程师必须考虑所选材料的断裂时的拉伸强度以确保安全和稳定。当材料受到拉伸力时，它们会经历变形。最初，它们会伸展而没有任何永久变化。然而，随着力量的增加，会出现一个点，材料达到其弹性极限，超过这个点它将无法恢复到原来的形状。断裂时的拉伸强度是材料无法再承受施加的应力并最终断裂的点。不同材料表现出不同的断裂时的拉伸强度值。例如，像钢这样的金属通常具有高拉伸强度，使它们非常适合用于建筑目的。另一方面，像橡胶这样的材料拉伸强度较低，但提供灵活性，这在不同应用中非常有用。理解这些差异有助于工程师和设计师为特定应用选择合适的材料。断裂时的拉伸强度的测试通常通过标准化的方法进行，如拉伸测试。在典型的拉伸测试中，材料样本被拉伸直至断裂。施加的力量和材料的延伸被测量和记录。然后使用这些数据计算拉伸强度，为材料的特性提供有价值的信息。了解断裂时的拉伸强度的意义超出了工程领域。在纺织行业，例如，了解面料的拉伸强度对于生产耐用的服装和其他纺织产品至关重要。同样，在绳索和电缆的生产中，制造商必须确保他们的产品能够承受所需的负载而不会断裂。总之，断裂时的拉伸强度是反映材料抵抗拉伸力能力的重要参数。它在各个行业中发挥着至关重要的作用，影响设计选择并确保安全。通过全面理解这一概念，专业人士可以做出明智的决策，从而提高其产品的性能和可靠性。随着技术的进步，准确确定断裂时的拉伸强度的重要性只会继续增长，为材料科学和工程实践中的创新铺平道路。