actual breaking force

简明释义

实际破断力

英英释义

例句

1.The engineer calculated the actual breaking force 实际断裂力 of the material to ensure it meets safety standards.

工程师计算了材料的实际断裂力，以确保其符合安全标准。

2.The actual breaking force 实际断裂力 of the bridge materials was tested under extreme conditions.

桥梁材料的实际断裂力在极端条件下进行了测试。

3.During the test, the actual breaking force 实际断裂力 was lower than expected, indicating a potential flaw in the design.

在测试过程中，实际断裂力低于预期，这表明设计可能存在缺陷。

4.To avoid accidents, it's crucial to know the actual breaking force 实际断裂力 of the components used in construction.

为了避免事故，了解建筑中使用的组件的实际断裂力至关重要。

5.We need to measure the actual breaking force 实际断裂力 of this cable before installation.

在安装之前，我们需要测量这根电缆的实际断裂力。

作文

The concept of actual breaking force is crucial in various fields, particularly in engineering and materials science. It refers to the maximum load that a material can withstand before it fails or breaks. Understanding this force is essential for designing structures and products that are safe and reliable. For example, in construction, engineers must calculate the actual breaking force of materials like steel and concrete to ensure that buildings can support the weight of occupants, furniture, and environmental factors such as wind and earthquakes.In practical applications, the actual breaking force can vary depending on several factors, including the type of material, its condition, and how it is used. For instance, a steel beam may have a high actual breaking force, but if it is corroded or improperly installed, its ability to bear weight diminishes significantly. This highlights the importance of regular maintenance and inspection in ensuring that materials continue to perform at their expected levels.Moreover, the actual breaking force is not only relevant in construction but also in manufacturing processes. When creating products, manufacturers must consider the actual breaking force to prevent failures that could lead to accidents or product recalls. For example, in the automotive industry, the components of a vehicle must be designed to withstand forces during crashes. If a part fails due to exceeding its actual breaking force, it could result in severe consequences for passengers.Testing for actual breaking force typically involves applying increasing loads to a sample until it fails. This process helps engineers determine the limits of a material and ensures that safety standards are met. The results from these tests are often documented and used to inform future designs and material selections.In conclusion, understanding the actual breaking force is vital across numerous industries. It informs engineers and designers about the limitations and capabilities of materials, ensuring that structures and products are built to last. By considering the actual breaking force in their work, professionals can enhance safety, reliability, and performance, ultimately benefiting society as a whole. As technology advances, the methods for testing and improving materials will continue to evolve, making our world safer and more efficient. Therefore, the significance of actual breaking force cannot be overstated, as it plays a fundamental role in the integrity of our built environment and the products we use daily.

“实际破坏力”的概念在各个领域中至关重要，特别是在工程和材料科学中。它指的是材料在失效或断裂之前能够承受的最大负载。理解这一力量对于设计安全可靠的结构和产品至关重要。例如，在建筑中，工程师必须计算钢材和混凝土的“实际破坏力”，以确保建筑物能够支撑居民、家具以及风和地震等环境因素的重量。在实际应用中，“实际破坏力”可能会因多种因素而异，包括材料的类型、状态以及使用方式。例如，钢梁可能具有很高的“实际破坏力”，但如果它生锈或安装不当，其承重能力会显著降低。这突显了定期维护和检查在确保材料继续按预期性能运行中的重要性。此外，“实际破坏力”不仅与建筑有关，还与制造过程密切相关。在创建产品时，制造商必须考虑“实际破坏力”，以防止可能导致事故或产品召回的故障。例如，在汽车工业中，车辆的部件必须设计成能够承受碰撞时的力量。如果某个部件由于超过其“实际破坏力”而失效，可能会对乘客造成严重后果。测试“实际破坏力”通常涉及对样本施加逐渐增加的负载，直到其失效。这个过程帮助工程师确定材料的极限，并确保符合安全标准。这些测试的结果通常被记录下来，并用于指导未来的设计和材料选择。总之，理解“实际破坏力”在众多行业中至关重要。它为工程师和设计师提供了关于材料限制和能力的信息，确保结构和产品的耐用性。通过在工作中考虑“实际破坏力”，专业人员可以提高安全性、可靠性和性能，最终使整个社会受益。随着技术的进步，测试和改善材料的方法将继续发展，使我们的世界更加安全和高效。因此，“实际破坏力”的重要性不容小觑，因为它在我们建成环境和日常使用的产品的完整性中发挥着基础性作用。