failure mechanism

简明释义

破坏机理

英英释义

例句

1.The research focused on identifying the failure mechanism 故障机制 in the new material under stress.

研究集中在识别新材料在应力下的故障机制 failure mechanism。

2.The engineer analyzed the failure mechanism 故障机制 of the bridge to ensure its safety.

工程师分析了桥梁的故障机制 failure mechanism以确保其安全。

3.Understanding the failure mechanism 故障机制 is crucial for improving product reliability.

理解故障机制 failure mechanism对于提高产品可靠性至关重要。

4.Engineers must document the failure mechanism 故障机制 when a component fails during testing.

当组件在测试中失败时，工程师必须记录故障机制 failure mechanism。

5.The team developed a model to predict the failure mechanism 故障机制 of the electrical circuit.

团队开发了一个模型来预测电路的故障机制 failure mechanism。

作文

In the realm of engineering and science, understanding the failure mechanism (失效机制) is crucial for developing reliable systems and preventing catastrophic failures. A failure mechanism refers to the underlying processes or reasons that lead to the breakdown of a system or component. This concept is not limited to mechanical systems; it can also apply to biological, chemical, and even social systems. By studying these mechanisms, engineers and scientists can design better materials and structures, ultimately enhancing safety and efficiency.One common example of a failure mechanism is fatigue in metals. Over time, repeated stress can cause microscopic cracks to form in a metal component. As these cracks grow, they can lead to sudden failure, often without warning. Understanding this failure mechanism allows engineers to predict when a component might fail and to implement maintenance schedules or choose more durable materials.Another important failure mechanism is corrosion, which affects many structures, especially those exposed to harsh environmental conditions. Corrosion can weaken materials over time, leading to structural failures in bridges, pipelines, and buildings. By studying the failure mechanism of corrosion, engineers can develop protective coatings and select materials that are more resistant to degradation, thus prolonging the lifespan of critical infrastructure.In addition to physical systems, failure mechanisms can also be observed in software engineering. Bugs and vulnerabilities in software can lead to system crashes or security breaches. Understanding the failure mechanism behind these issues is essential for developers to create robust applications. Techniques such as code reviews, testing, and debugging are employed to identify potential failure mechanisms before they can cause significant problems.Moreover, in the field of medicine, understanding the failure mechanism of diseases can lead to better treatments and preventative measures. For instance, researchers study the failure mechanism of cancer cells to develop targeted therapies that can inhibit their growth. By unraveling the complexities of these mechanisms, scientists can create more effective medications and improve patient outcomes.The study of failure mechanisms is not only about identifying problems but also about fostering innovation. When engineers and scientists understand how things fail, they can think creatively about solutions. This proactive approach can lead to the development of new technologies and materials that are less prone to failure, ultimately benefiting society as a whole.In conclusion, the concept of failure mechanism (失效机制) plays a vital role in various fields, from engineering to medicine. By comprehensively understanding these mechanisms, professionals can mitigate risks, enhance safety, and promote innovation. As we continue to advance technologically, the importance of studying failure mechanisms will only grow, ensuring that we build systems that are not only efficient but also resilient to failures. The pursuit of knowledge in this area is essential for a safer and more sustainable future.

在工程和科学领域，理解失效机制是开发可靠系统和防止灾难性故障的关键。失效机制指的是导致系统或组件故障的基本过程或原因。这个概念不仅限于机械系统；它也可以应用于生物、化学甚至社会系统。通过研究这些机制，工程师和科学家可以设计更好的材料和结构，从而增强安全性和效率。一个常见的失效机制例子是金属的疲劳。随着时间的推移，重复的应力可能导致金属组件中形成微观裂纹。随着这些裂纹的增长，它们可能导致突然的故障，通常没有警告。理解这一失效机制使工程师能够预测组件何时可能会失效，并实施维护计划或选择更耐用的材料。另一个重要的失效机制是腐蚀，这影响着许多结构，尤其是那些暴露在恶劣环境条件下的结构。腐蚀会随着时间的推移削弱材料，导致桥梁、管道和建筑物的结构故障。通过研究腐蚀的失效机制，工程师可以开发保护涂层并选择更耐降解的材料，从而延长关键基础设施的使用寿命。除了物理系统，失效机制也可以在软件工程中观察到。软件中的漏洞和缺陷可能导致系统崩溃或安全漏洞。理解这些问题的失效机制对于开发人员创建稳健的应用程序至关重要。代码审查、测试和调试等技术被用于识别潜在的失效机制，以便在它们造成重大问题之前加以解决。此外，在医学领域，了解疾病的失效机制可以导致更好的治疗和预防措施。例如，研究人员研究癌细胞的失效机制以开发能够抑制其生长的靶向疗法。通过揭示这些机制的复杂性，科学家可以创造出更有效的药物并改善患者的治疗效果。对失效机制的研究不仅仅是识别问题，还涉及促进创新。当工程师和科学家理解事物是如何失败的，他们就可以创造性地思考解决方案。这种主动的方法可以导致开发出不易失效的新技术和材料，从而最终惠及整个社会。总之，失效机制在各个领域（从工程到医学）中起着至关重要的作用。通过全面理解这些机制，专业人员可以降低风险、增强安全性并促进创新。随着我们技术的不断进步，研究失效机制的重要性只会增加，确保我们构建的系统不仅高效，而且能够抵御故障。在这一领域追求知识对实现更安全和可持续的未来至关重要。