compression failure

简明释义

压缩破坏

英英释义

例句

1.The system encountered a compression failure while trying to save the large video file.

系统在尝试保存大型视频文件时遇到了压缩失败。

2.After the update, users reported a compression failure when uploading images to the server.

更新后，用户在将图像上传到服务器时报告了压缩失败。

3.Our team is investigating the compression failure that occurred during the data transfer.

我们的团队正在调查在数据传输过程中发生的压缩失败。

4.The application crashed because of a compression failure while processing files.

应用程序在处理文件时由于压缩失败而崩溃。

5.The backup process was interrupted due to a compression failure in the data stream.

由于数据流中的压缩失败，备份过程被中断。

作文

In the realm of engineering and materials science, understanding the concept of compression failure is crucial for designing safe and reliable structures. Compression failure refers to the loss of structural integrity that occurs when a material is subjected to compressive forces beyond its capacity. This phenomenon can lead to catastrophic results, making it imperative for engineers to recognize the signs and implications of compression failure during the design and construction phases. To illustrate this point, consider the case of a concrete column used in a high-rise building. Concrete is a material that excels under compression; however, it has its limits. When the load applied to the column exceeds the compressive strength of the concrete, compression failure can occur. This might manifest as cracking, crushing, or buckling of the column, which could ultimately compromise the stability of the entire structure. Therefore, engineers must conduct thorough analyses to ensure that all components are adequately designed to withstand expected loads without experiencing compression failure.Moreover, compression failure is not limited to concrete. It can also affect metals, plastics, and other materials. For instance, in the automotive industry, the design of car frames must account for potential compression failure during collisions. If the frame cannot absorb the compressive forces generated during an impact, it may crumple, leading to severe damage and increased risk of injury to passengers. This highlights the importance of rigorous testing and material selection to prevent compression failure in critical applications.The implications of compression failure extend beyond individual components to the overall safety of structures. In civil engineering, buildings, bridges, and dams must be designed with factors of safety that account for unexpected loads and material degradation over time. Failure to do so could result in structural collapse, endangering lives and causing significant economic loss. Engineers employ various methods, such as finite element analysis and load testing, to predict and mitigate the risks associated with compression failure.In conclusion, compression failure is a fundamental concept that engineers must understand to ensure the safety and reliability of their designs. By recognizing the potential for compression failure in various materials and structures, engineers can take proactive measures to enhance performance and prevent disasters. As technology advances, the tools and techniques for analyzing and mitigating compression failure will continue to evolve, further improving the resilience of our built environment. Understanding this concept is not just a technical necessity; it is a critical component of responsible engineering practice that prioritizes safety and sustainability in our ever-growing infrastructure.

在工程和材料科学领域，理解“压缩失效”这一概念对于设计安全可靠的结构至关重要。“压缩失效”是指当材料承受超过其承载能力的压缩力时，失去结构完整性的现象。这种现象可能导致灾难性的后果，因此工程师必须在设计和施工阶段识别“压缩失效”的迹象和影响。为了说明这一点，考虑一个用于高层建筑的混凝土柱的案例。混凝土是一种在压缩下表现出色的材料；然而，它有其极限。当施加在柱子上的负荷超过混凝土的抗压强度时，就可能发生“压缩失效”。这可能表现为裂缝、破碎或柱子的屈曲，这最终可能危及整个结构的稳定性。因此，工程师必须进行全面分析，以确保所有组件都能充分设计，以承受预期负荷而不发生“压缩失效”。此外，“压缩失效”并不限于混凝土。它也可以影响金属、塑料和其他材料。例如，在汽车工业中，汽车框架的设计必须考虑在碰撞期间可能发生的“压缩失效”。如果框架无法吸收碰撞产生的压缩力，它可能会变形，从而导致严重损坏，并增加乘客受伤的风险。这突显了严格测试和材料选择的重要性，以防止在关键应用中发生“压缩失效”。“压缩失效”的影响不仅限于单个组件，还涉及结构的整体安全性。在土木工程中，建筑物、桥梁和大坝必须设计具有安全系数，以应对意外负荷和材料随时间的退化。如果不这样做，可能会导致结构倒塌，危及生命并造成重大经济损失。工程师采用各种方法，如有限元分析和负载测试，以预测和减轻与“压缩失效”相关的风险。总之，“压缩失效”是工程师必须理解的基本概念，以确保他们设计的安全性和可靠性。通过认识到各种材料和结构中发生“压缩失效”的潜力，工程师可以采取主动措施来提高性能，防止灾难。随着技术的进步，分析和减轻“压缩失效”的工具和技术将继续发展，从而进一步提高我们建成环境的韧性。理解这一概念不仅是技术上的必要性；它是优先考虑安全和可持续性的负责任工程实践的关键组成部分，适用于我们不断增长的基础设施。