failure load

简明释义

破坏载荷

英英释义

例句

1.Engineers must calculate the failure load 失效载荷 to ensure safety in construction.

工程师必须计算失效载荷 failure load以确保施工安全。

2.The bridge was designed to withstand a maximum failure load 失效载荷 of 200 tons.

这座桥的设计最大可承受的失效载荷 failure load为200吨。

3.Understanding the failure load 失效载荷 helps in optimizing the design of structures.

理解失效载荷 failure load有助于优化结构设计。

4.The failure load 失效载荷 for this cable is critical for its application in elevators.

这条电缆的失效载荷 failure load对其在电梯中的应用至关重要。

5.In testing, the material broke under a failure load 失效载荷 of 1500 newtons.

在测试中，材料在1500牛顿的失效载荷 failure load下断裂。

作文

In engineering and structural design, understanding the concept of failure load is crucial for ensuring safety and reliability. The term failure load refers to the maximum load that a structure or material can withstand before it fails or collapses. This concept is not only fundamental in civil engineering but also plays a significant role in various fields such as aerospace, mechanical, and materials engineering. Engineers must accurately determine the failure load to design structures that can endure expected loads during their lifespan. To illustrate the importance of failure load, consider the construction of a bridge. Engineers must calculate the loads that the bridge will experience, including the weight of vehicles, pedestrians, and environmental factors like wind and earthquakes. The failure load helps them identify the maximum stress the bridge can handle without compromising its integrity. If the actual loads exceed the calculated failure load, the bridge risks catastrophic failure, which could lead to loss of life and significant economic repercussions.Moreover, understanding failure load is essential for material selection. Different materials have varying strengths and weaknesses, and knowing the failure load of each material allows engineers to choose the appropriate one for a specific application. For instance, steel has a higher failure load compared to wood, making it a preferred choice for high-rise buildings and bridges. However, the cost and availability of materials also play a role in this decision-making process.In addition to structural applications, the concept of failure load extends to product design. Manufacturers must ensure that products, whether they are consumer goods or industrial equipment, can withstand the forces they will encounter during use. By testing products to determine their failure load, companies can improve their designs, enhance safety, and avoid costly recalls or legal issues related to product failures.Furthermore, the failure load concept is vital in safety regulations and standards. Regulatory bodies often set guidelines that specify the minimum failure load requirements for various structures and products. Compliance with these standards not only protects public safety but also helps companies avoid legal liabilities. Engineers and designers must stay informed about these regulations to ensure their projects meet or exceed the required failure load criteria.In conclusion, the concept of failure load is integral to the fields of engineering and design. It encompasses the maximum load a structure or material can endure before failure occurs. Understanding and applying this concept is essential for creating safe, reliable, and efficient structures and products. As technology advances and new materials are developed, the methods for determining failure load will continue to evolve, further enhancing our ability to design safe and durable systems. Therefore, engineers must prioritize learning about failure load and its implications in their work to ensure the safety and effectiveness of their designs.

在工程和结构设计中，理解失效载荷的概念对于确保安全性和可靠性至关重要。术语失效载荷指的是结构或材料在失效或崩溃之前能够承受的最大载荷。这个概念不仅在土木工程中是基础性的，而且在航空航天、机械和材料工程等多个领域也发挥着重要作用。工程师必须准确确定失效载荷，以设计可以在其使用寿命内承受预期载荷的结构。为了说明失效载荷的重要性，考虑一下桥梁的建设。工程师必须计算桥梁将经历的载荷，包括车辆、行人以及风和地震等环境因素的重量。失效载荷帮助他们识别桥梁在不影响其完整性的情况下能够承受的最大应力。如果实际载荷超过计算出的失效载荷，桥梁就有可能面临灾难性的失败，这可能导致生命损失和重大的经济后果。此外，理解失效载荷对于材料选择至关重要。不同材料具有不同的强度和弱点，了解每种材料的失效载荷使工程师能够为特定应用选择合适的材料。例如，钢材的失效载荷高于木材，因此它成为高层建筑和桥梁的首选。然而，材料的成本和可用性在这一决策过程中也起着作用。除了结构应用外，失效载荷的概念还扩展到产品设计。制造商必须确保产品，无论是消费品还是工业设备，都能承受在使用过程中遇到的力量。通过测试产品以确定其失效载荷，公司可以改善设计，提高安全性，避免因产品故障而导致的昂贵召回或法律问题。此外，失效载荷的概念在安全法规和标准中至关重要。监管机构通常设定指南，规定各种结构和产品的最低失效载荷要求。遵守这些标准不仅保护公众安全，还帮助公司避免法律责任。工程师和设计师必须了解这些法规，以确保他们的项目符合或超过所需的失效载荷标准。总之，失效载荷的概念是工程和设计领域不可或缺的一部分。它涵盖了结构或材料在发生失效之前能够承受的最大载荷。理解和应用这一概念对于创建安全、可靠和高效的结构和产品至关重要。随着技术的进步和新材料的发展，确定失效载荷的方法将继续演变，进一步增强我们设计安全和耐用系统的能力。因此，工程师必须优先学习失效载荷及其在工作中的影响，以确保他们的设计的安全性和有效性。