twisting strength

简明释义

抗扭强度

英英释义

例句

1.In the construction of bridges, engineers must consider the 扭转强度 of the materials used.

在桥梁建设中，工程师必须考虑所用材料的扭转强度。

2.The rope is designed to withstand high 扭转强度, making it ideal for climbing.

这根绳索的设计可以承受高扭转强度，使其非常适合攀岩。

3.When testing the 扭转强度 of the cable, we found it exceeded our expectations.

在测试电缆的扭转强度时，我们发现它超出了我们的预期。

4.The 扭转强度 of the metal determines how much force it can handle before deforming.

金属的扭转强度决定了它在变形之前可以承受多少力。

5.The design of the new sports equipment focuses on enhancing 扭转强度 for better performance.

新运动器材的设计重点是提高扭转强度以获得更好的性能。

作文

The concept of twisting strength is crucial in various fields, particularly in engineering and material science. It refers to the ability of a material to withstand twisting forces without breaking or deforming. This property is essential for ensuring the durability and reliability of structures and components that are subjected to torsional loads. For instance, when designing a bridge, engineers must consider the twisting strength of the materials used to ensure that they can handle the stresses caused by wind, traffic, and other dynamic forces.One practical example of twisting strength can be seen in the production of cables and wires. These materials often undergo significant twisting during their manufacturing process and must maintain their integrity under such conditions. A cable with high twisting strength will not only last longer but also perform better in applications where flexibility and durability are required. For example, in the telecommunications industry, the performance of fiber optic cables largely depends on their twisting strength. If the cables cannot withstand the twists and turns during installation and use, they may break or fail, leading to costly repairs and downtime.In addition to practical applications, understanding twisting strength also has implications in biomechanics. The human body, particularly the muscles and bones, exhibits characteristics similar to materials in engineering. For instance, athletes often train to increase their muscle twisting strength, allowing them to perform better in sports that require rotational movements, such as gymnastics or figure skating. The ability to twist and turn effectively can make a significant difference in an athlete's performance, highlighting the importance of this property beyond just mechanical applications.Moreover, the study of twisting strength extends into the realm of natural materials. Scientists and researchers are continually exploring how different biological materials, such as wood and bone, exhibit unique twisting strength properties. For example, certain types of wood are known for their exceptional twisting strength, making them ideal for construction and furniture-making. Understanding these properties can lead to advancements in sustainable materials and eco-friendly building practices.In conclusion, the significance of twisting strength cannot be overstated. Whether in engineering, athletics, or natural sciences, this property plays a vital role in ensuring the functionality and longevity of various materials and structures. As we continue to innovate and explore new materials, a thorough understanding of twisting strength will remain essential in pushing the boundaries of what is possible in both technology and nature.

“扭曲强度”的概念在各个领域中都至关重要，特别是在工程和材料科学中。它指的是材料在不破裂或变形的情况下承受扭曲力的能力。这一属性对于确保在扭转载荷下结构和组件的耐久性和可靠性至关重要。例如，在设计桥梁时，工程师必须考虑所用材料的扭曲强度，以确保它们能够承受风、交通和其他动态力量造成的压力。一个实际的例子是电缆和导线的生产。这些材料在制造过程中经常经历显著的扭曲，并且必须在这种情况下保持其完整性。具有高扭曲强度的电缆不仅使用寿命更长，而且在需要灵活性和耐用性的应用中表现更好。例如，在电信行业，光纤电缆的性能在很大程度上取决于其扭曲强度。如果电缆无法承受安装和使用过程中的扭转，它们可能会断裂或失效，从而导致昂贵的维修和停机。除了实际应用外，理解扭曲强度在生物力学中也有重要意义。人体，特别是肌肉和骨骼，表现出与工程材料相似的特性。例如，运动员通常训练以增加他们的肌肉扭曲强度，使他们能够在需要旋转动作的运动中表现更好，如体操或花样滑冰。有效扭转和转动的能力可以显著影响运动员的表现，突显了这一属性在机械应用之外的重要性。此外，扭曲强度的研究还扩展到自然材料的领域。科学家和研究人员不断探索不同生物材料（如木材和骨骼）如何表现出独特的扭曲强度特性。例如，某些类型的木材因其卓越的扭曲强度而被认为非常适合用于建筑和家具制造。理解这些特性可以促进可持续材料和环保建筑实践的进步。总之，扭曲强度的重要性不容小觑。无论是在工程、体育还是自然科学中，这一属性在确保各种材料和结构的功能性和耐久性方面发挥着至关重要的作用。随着我们继续创新和探索新材料，对扭曲强度的透彻理解将始终是推动技术和自然可能性边界的重要因素。