ultimate compressive strength

简明释义

极限抗压强度

英英释义

例句

1.To avoid structural failure, it’s crucial to select materials with an adequate ultimate compressive strength 极限抗压强度 for the intended load.

为了避免结构失效，选择具有足够ultimate compressive strength 极限抗压强度的材料以承受预期负载至关重要。

2.Testing the ultimate compressive strength 极限抗压强度 of different concrete mixes can help determine the best option for a specific project.

测试不同混凝土配比的ultimate compressive strength 极限抗压强度可以帮助确定特定项目的最佳选择。

3.The concrete used in this building has an ultimate compressive strength 极限抗压强度 of 40 MPa, making it suitable for high-rise structures.

这座建筑使用的混凝土具有40 MPa的ultimate compressive strength 极限抗压强度，使其适合高层建筑。

4.Engineers must consider the ultimate compressive strength 极限抗压强度 of materials when designing bridges to ensure safety and durability.

工程师在设计桥梁时必须考虑材料的ultimate compressive strength 极限抗压强度以确保安全和耐用性。

5.The ultimate compressive strength 极限抗压强度 of steel is significantly higher than that of wood, which is why it is often used in construction.

钢材的ultimate compressive strength 极限抗压强度明显高于木材，这就是为什么它常用于建筑中的原因。

作文

The concept of ultimate compressive strength is crucial in the fields of engineering and materials science. It refers to the maximum amount of compressive stress that a material can withstand before failing or deforming permanently. Understanding this property is essential for engineers when designing structures, as it helps ensure safety and stability under various loads. For instance, when constructing buildings, bridges, or any load-bearing structures, knowing the ultimate compressive strength of the materials used is vital to prevent catastrophic failures. Different materials exhibit different levels of ultimate compressive strength, which is influenced by factors such as composition, structure, and environmental conditions. Concrete, for example, is widely known for its high ultimate compressive strength, making it a preferred choice for construction projects. On the other hand, materials like wood have lower ultimate compressive strength values, which necessitates careful consideration during design processes to avoid overloading. To measure the ultimate compressive strength of a material, standardized tests are conducted, where samples are subjected to increasing loads until failure occurs. The results from these tests provide engineers with critical data that informs their decisions regarding material selection and structural design. This process not only ensures that the materials used can handle expected loads but also contributes to the longevity and durability of the structure. Moreover, understanding the ultimate compressive strength is not limited to just construction; it also plays a significant role in various industries, including aerospace, automotive, and manufacturing. For instance, components used in aircraft must possess high ultimate compressive strength to withstand the immense forces experienced during flight. Similarly, automotive parts must be designed to endure compressive stresses while maintaining safety and performance standards. In summary, the ultimate compressive strength of materials is a fundamental property that influences the design and safety of structures across multiple industries. Engineers must thoroughly understand this concept to make informed decisions that ensure the integrity and reliability of their creations. As technology advances, new materials with improved ultimate compressive strength characteristics are continually being developed, further enhancing the capabilities of modern engineering. Therefore, ongoing research and testing in this area remain essential for the future of safe and efficient design practices.

“极限抗压强度”这一概念在工程和材料科学领域至关重要。它指的是材料在发生破坏或永久变形之前能够承受的最大压应力。理解这一特性对于工程师在设计结构时至关重要，因为它有助于确保在各种载荷下的安全性和稳定性。例如，在建造建筑物、桥梁或任何承重结构时，了解所用材料的极限抗压强度是防止灾难性故障的关键。不同材料表现出不同水平的极限抗压强度，这受到成分、结构和环境条件等因素的影响。例如，混凝土因其高极限抗压强度而广为人知，使其成为建筑项目的首选材料。另一方面，木材的极限抗压强度值较低，这在设计过程中需要谨慎考虑，以避免超载。为了测量材料的极限抗压强度，会进行标准化测试，其中样本在加载逐渐增加的情况下，直到发生破坏。这些测试的结果为工程师提供了重要的数据，帮助他们做出关于材料选择和结构设计的决策。这个过程不仅确保所用材料能够承受预期载荷，而且有助于结构的耐久性和持久性。此外，理解极限抗压强度不仅限于建筑，它在航空航天、汽车和制造等多个行业中也发挥着重要作用。例如，飞机中使用的组件必须具有高极限抗压强度，以承受飞行过程中经历的巨大力。同样，汽车零件的设计也必须能够承受压应力，同时保持安全和性能标准。总之，材料的极限抗压强度是影响多个行业结构设计和安全性的基本属性。工程师必须深入理解这一概念，以便做出明智的决策，确保其创作的完整性和可靠性。随着技术的进步，具有更优越极限抗压强度特性的材料不断被开发出来，进一步提升现代工程的能力。因此，在这一领域的持续研究和测试对未来安全高效的设计实践至关重要。