derived working limit

简明释义

导出工撰限

英英释义

例句

1.The derived working limit 推导工作极限 was adjusted after conducting further stress tests.

在进行进一步的应力测试后，推导工作极限被调整。

2.In our latest project, we established a derived working limit 推导工作极限 based on previous test results.

在我们最新的项目中，我们根据之前的测试结果建立了一个推导工作极限。

3.Before finalizing the design, we need to verify the derived working limit 推导工作极限 of the components.

在最终确定设计之前，我们需要验证组件的推导工作极限。

4.The engineer calculated the derived working limit 推导工作极限 for the new material to ensure safety during operation.

工程师计算了新材料的推导工作极限，以确保在操作过程中的安全。

5.The derived working limit 推导工作极限 helps us determine the maximum load that can be safely applied.

该推导工作极限帮助我们确定可以安全施加的最大负载。

作文

In engineering and design, the concept of a derived working limit is crucial for ensuring safety and reliability. The derived working limit refers to the maximum load or stress that a material or structure can withstand during its intended use, derived from various tests and calculations. Understanding this limit is essential for engineers when designing components that will be subjected to forces and pressures in real-world applications.For instance, consider the construction of a bridge. Engineers must calculate the derived working limit of the materials used, such as steel and concrete, to ensure that the structure can support not only its own weight but also the weight of vehicles and pedestrians. This involves rigorous testing under controlled conditions to determine how much stress the materials can handle before failing. By establishing a derived working limit, engineers can create safety margins that protect against unexpected loads, such as those caused by heavy traffic or extreme weather.Moreover, the derived working limit is not static; it can change based on several factors including temperature, humidity, and the age of the materials. As materials age, their strength can diminish, which is why regular inspections and maintenance are critical in long-term infrastructure projects. Engineers must continually assess whether the derived working limit remains adequate throughout the lifespan of the structure.In addition to civil engineering, the concept of derived working limit is also applicable in other fields such as aerospace and automotive engineering. For example, an aircraft’s wings are designed with a specific derived working limit to ensure they can handle the aerodynamic forces during flight. If the wings were to exceed this limit, it could lead to catastrophic failure, endangering passengers and crew.Furthermore, the derived working limit plays a significant role in product safety. Manufacturers must adhere to strict guidelines that dictate the derived working limit for consumer products, ensuring they do not pose risks to users. This is particularly important in industries like electronics, where devices must withstand certain electrical loads without overheating or causing fires.In conclusion, understanding the derived working limit is fundamental across various engineering disciplines. It ensures that structures and products are designed with safety and reliability in mind, ultimately protecting lives and investments. Engineers must rely on empirical data and thorough analysis to establish these limits, which in turn allows them to innovate and push the boundaries of design while maintaining a commitment to safety. As technology advances, the methods for determining the derived working limit will continue to evolve, leading to even safer and more efficient designs in the future.

在工程和设计中，衍生工作极限的概念对于确保安全和可靠性至关重要。衍生工作极限指的是材料或结构在其预期使用过程中能够承受的最大载荷或应力，这一极限是通过各种测试和计算得出的。理解这一极限对于工程师在设计将承受现实应用中力量和压力的部件时至关重要。例如，考虑桥梁的建设。工程师必须计算所用材料（如钢材和混凝土）的衍生工作极限，以确保结构不仅能支撑自身重量，还能支撑车辆和行人的重量。这涉及在控制条件下进行严格的测试，以确定材料在失效前可以承受多少应力。通过建立衍生工作极限，工程师可以创建保护措施，以防止由于意外负载（如重型交通或极端天气）而导致的问题。此外，衍生工作极限并不是静态的；它会根据温度、湿度和材料老化等多种因素而变化。随着材料的老化，其强度可能会降低，这就是为什么定期检查和维护在长期基础设施项目中至关重要的原因。工程师必须不断评估衍生工作极限是否在结构的整个生命周期内保持足够。除了土木工程，衍生工作极限的概念在航空航天和汽车工程等其他领域也适用。例如，飞机的机翼设计有特定的衍生工作极限，以确保它们能够承受飞行过程中的空气动力学力量。如果机翼超过这一极限，可能会导致灾难性故障，危及乘客和机组人员的安全。此外，衍生工作极限在产品安全中也扮演着重要角色。制造商必须遵循严格的指南，规定消费产品的衍生工作极限，确保它们不会对用户构成风险。这在电子行业尤为重要，因为设备必须在不发生过热或引发火灾的情况下承受一定的电负荷。总之，理解衍生工作极限在各个工程学科中都是基础。它确保结构和产品的设计考虑到安全性和可靠性，最终保护生命和投资。工程师必须依靠实证数据和全面分析来建立这些极限，从而使他们能够创新并推动设计的边界，同时保持对安全的承诺。随着技术的发展，确定衍生工作极限的方法将继续演变，未来将出现更安全、更高效的设计。