computed strength

简明释义

计算强度

英英释义

例句

1.The engineer calculated the computed strength of the materials used in the bridge design.

工程师计算了桥梁设计中使用材料的计算强度。

2.Before construction, we need to verify the computed strength of the foundation.

在施工之前，我们需要验证基础的计算强度。

3.The computed strength of the concrete was above the required standards for this project.

混凝土的计算强度超过了该项目的要求标准。

4.The software provides a detailed report on the computed strength of various components.

该软件提供了关于各种组件的计算强度的详细报告。

5.In structural analysis, the computed strength helps ensure safety under load conditions.

在结构分析中，计算强度有助于确保在载荷条件下的安全性。

作文

In the field of engineering and materials science, the term computed strength refers to the calculated ability of a material to withstand applied forces without failure. This concept is crucial for ensuring the safety and reliability of structures, such as bridges, buildings, and various mechanical components. Engineers utilize various methods and mathematical models to determine the computed strength of materials, taking into account factors such as stress, strain, and environmental conditions.The process begins with selecting the appropriate material for a specific application. Each material possesses unique properties that affect its computed strength. For example, steel has a high tensile strength, making it ideal for construction, while materials like rubber have lower strength but excellent elasticity. By understanding these properties, engineers can make informed decisions about which materials to use in their designs.Once the material is chosen, engineers perform tests to gather data on its behavior under different loads. These tests may include tensile testing, compression testing, and fatigue testing. The results from these experiments provide valuable information that can be used to calculate the computed strength of the material. Advanced software tools and finite element analysis (FEA) are often employed to simulate how materials will behave under various conditions, allowing for accurate predictions of their performance.The significance of computed strength extends beyond just theoretical calculations; it has real-world implications. For instance, when designing a bridge, engineers must ensure that the computed strength of the materials used can support not only the weight of the structure itself but also the dynamic loads imposed by vehicles and environmental factors such as wind and earthquakes. Failure to accurately compute this strength can lead to catastrophic failures, resulting in loss of life and property.Moreover, the computed strength of materials can vary based on their treatment and processing. For example, heat treatment can enhance the strength of metals, while the addition of certain alloys can improve the overall performance of a material. Engineers must consider these factors when calculating the computed strength to ensure that they account for all variables that could impact the material's performance.In recent years, advancements in technology have allowed for more precise calculations and simulations regarding computed strength. With the advent of machine learning and artificial intelligence, engineers can now predict material behavior with greater accuracy than ever before. This not only streamlines the design process but also leads to safer and more efficient structures.In conclusion, understanding computed strength is essential for engineers and designers working in various fields. It involves a comprehensive approach that combines material science, mathematics, and practical testing to ensure that structures can withstand the forces they encounter. As technology continues to evolve, the methods for calculating and applying computed strength will undoubtedly become even more sophisticated, enhancing the safety and durability of our built environment.

在工程和材料科学领域，术语计算强度指的是材料在不发生失效的情况下承受施加力的计算能力。这个概念对于确保结构的安全性和可靠性至关重要，例如桥梁、建筑物和各种机械部件。工程师利用各种方法和数学模型来确定材料的计算强度，考虑到应力、应变和环境条件等因素。这一过程始于为特定应用选择合适的材料。每种材料具有独特的特性，影响其计算强度。例如，钢具有高拉伸强度，使其非常适合用于建筑，而橡胶等材料则强度较低，但具有优良的弹性。通过理解这些特性，工程师可以就在设计中使用哪些材料做出明智的决策。一旦选择了材料，工程师会进行测试，以收集其在不同负载下行为的数据。这些测试可能包括拉伸测试、压缩测试和疲劳测试。这些实验的结果提供了宝贵的信息，可以用于计算材料的计算强度。先进的软件工具和有限元分析（FEA）通常被用来模拟材料在各种条件下的行为，从而准确预测其性能。计算强度的重要性不仅仅体现在理论计算上；它还具有现实世界的影响。例如，在设计桥梁时，工程师必须确保所用材料的计算强度能够支持结构自身的重量，以及车辆和风、地震等环境因素施加的动态负载。如果未能准确计算这种强度，可能会导致灾难性的失败，造成生命和财产的损失。此外，材料的计算强度可能会因其处理和加工而有所不同。例如，热处理可以增强金属的强度，而某些合金的加入可以改善材料的整体性能。工程师在计算计算强度时必须考虑这些因素，以确保他们考虑到所有可能影响材料性能的变量。近年来，技术的进步使得关于计算强度的计算和模拟更为精确。随着机器学习和人工智能的出现，工程师现在可以比以往任何时候都更准确地预测材料行为。这不仅简化了设计过程，还提高了结构的安全性和效率。总之，理解计算强度对在各个领域工作的工程师和设计师至关重要。它涉及一种综合的方法，结合材料科学、数学和实用测试，以确保结构能够承受它们所遇到的力量。随着技术的不断发展，计算和应用计算强度的方法无疑会变得更加复杂，提高我们建成环境的安全性和耐久性。