chance failure

简明释义

意外故障;

英英释义

例句

1.The company implemented new protocols to minimize chance failure in production.

公司实施了新协议，以尽量减少生产中的偶然故障。

2.A chance failure during testing led to unexpected results.

测试期间的偶然故障导致了意外结果。

3.The project was delayed due to a chance failure in the software system.

由于软件系统中的偶然故障，项目被延迟。

4.Engineers must account for chance failure when designing safety systems.

工程师在设计安全系统时必须考虑到偶然故障。

5.In critical systems, chance failure can have severe consequences.

在关键系统中，偶然故障可能会造成严重后果。

作文

In the world of technology and engineering, the term chance failure refers to unexpected and random failures that occur without any identifiable cause. These failures can happen in various systems, from software applications to complex machinery. Understanding chance failure is crucial for engineers and developers as it helps them design more robust systems that can withstand unforeseen circumstances.One of the primary challenges with chance failure is its unpredictability. Unlike systematic failures, which can be traced back to a specific error or oversight in the design or implementation process, chance failure can strike at any moment and often without warning. This randomness poses significant risks, especially in critical applications such as aerospace, medical devices, and automotive systems, where a single failure can have catastrophic consequences.To mitigate the risks associated with chance failure, engineers employ various strategies. One common approach is redundancy, where multiple components perform the same function. For example, in an aircraft, multiple engines ensure that if one fails unexpectedly, the others can maintain flight. This strategy significantly reduces the likelihood of a total system failure due to chance failure.Another important aspect of dealing with chance failure is rigorous testing. Engineers conduct extensive simulations and stress tests to identify potential weak points in their designs. By pushing systems to their limits, they can uncover hidden vulnerabilities that may lead to chance failure. Additionally, real-world testing allows for the observation of how systems behave under various conditions, further informing design improvements.Moreover, statistical analysis plays a vital role in understanding and predicting chance failure. By collecting data on past failures, engineers can develop models that estimate the probability of future failures. This information is invaluable for risk assessment and management, allowing teams to prioritize their efforts on the most critical components that are susceptible to chance failure.Despite these efforts, it is essential to accept that chance failure can never be entirely eliminated. Therefore, creating a culture of safety and preparedness is crucial. Organizations must train their teams to respond effectively to unexpected failures, ensuring that they have protocols in place to minimize the impact of chance failure. This includes having contingency plans and providing ongoing education about best practices in failure management.In conclusion, the concept of chance failure is a critical consideration in the fields of engineering and technology. Its unpredictable nature requires engineers to adopt proactive measures, including redundancy, rigorous testing, and statistical analysis, to minimize risks. While it is impossible to eliminate chance failure entirely, fostering a culture of safety and preparedness can help organizations navigate the challenges it presents. As technology continues to evolve, understanding and addressing chance failure will remain a priority for engineers and developers alike.

在技术和工程领域，术语chance failure指的是意外且随机的故障，这些故障发生时没有任何可识别的原因。这些故障可以发生在各种系统中，从软件应用程序到复杂的机械设备。理解chance failure对工程师和开发人员至关重要，因为这有助于他们设计出更强大的系统，以应对不可预见的情况。与chance failure相关的主要挑战之一是其不可预测性。与可以追溯到特定错误或设计或实施过程中的失误的系统性故障不同，chance failure可以在任何时刻发生，通常没有警告。这种随机性带来了重大风险，特别是在航空航天、医疗设备和汽车系统等关键应用中，单一故障可能会导致灾难性后果。为了减轻与chance failure相关的风险，工程师采用多种策略。一种常见的方法是冗余，即多个组件执行相同的功能。例如，在飞机中，多个引擎确保如果一个意外故障，其他引擎可以维持飞行。这种策略显著降低了由于chance failure导致的总系统故障的可能性。处理chance failure的另一个重要方面是严格的测试。工程师进行广泛的模拟和压力测试，以识别设计中的潜在弱点。通过将系统推向极限，他们可以发现可能导致chance failure的隐藏漏洞。此外，现实世界的测试使得观察系统在各种条件下的行为成为可能，进一步为设计改进提供信息。此外，统计分析在理解和预测chance failure中发挥着至关重要的作用。通过收集过去故障的数据，工程师可以开发模型来估算未来故障的概率。这些信息对于风险评估和管理非常宝贵，使团队能够优先考虑最关键的易受chance failure影响的组件。尽管采取了这些措施，但必须接受的是，chance failure永远无法完全消除。因此，创建安全和准备文化至关重要。组织必须培训其团队有效应对意外故障，确保他们有应急计划来最小化chance failure的影响。这包括制定应急计划并提供关于故障管理最佳实践的持续教育。总之，chance failure的概念在工程和技术领域是一个关键考虑因素。其不可预测的特性要求工程师采取主动措施，包括冗余、严格测试和统计分析，以最小化风险。虽然不可能完全消除chance failure，但培养安全和准备文化可以帮助组织应对其带来的挑战。随着技术的不断发展，理解和应对chance failure将始终是工程师和开发人员的优先事项。