engineering casualty

简明释义

技术装备损管

英英释义

例句

1.Preventing engineering casualties 工程事故 is crucial for maintaining safety standards.

防止工程事故 engineering casualties对维护安全标准至关重要。

2.The project was delayed due to an engineering casualty 工程事故 that required immediate attention.

由于发生了一起需要立即处理的工程事故 engineering casualty，项目被延迟了。

3.Training programs are essential to reduce the risk of engineering casualties 工程事故 in construction.

培训项目对于减少建筑中发生的工程事故 engineering casualties风险至关重要。

4.After the engineering casualty 工程事故, the team conducted a thorough investigation.

在发生工程事故 engineering casualty后，团队进行了彻底调查。

5.The report highlighted several factors that contributed to the engineering casualty 工程事故.

报告强调了导致工程事故 engineering casualty的几个因素。

作文

In the field of engineering, safety is of paramount importance. Engineers are tasked with designing structures and systems that not only meet functional requirements but also ensure the safety of users and the environment. However, despite rigorous planning and execution, there are instances where failures occur, leading to what is termed as an engineering casualty. An engineering casualty refers to an event where a failure in engineering design or execution results in damage, injury, or loss of life. Understanding the implications of such casualties is crucial for improving engineering practices and enhancing safety protocols.One of the most notable examples of an engineering casualty can be seen in the collapse of the Tacoma Narrows Bridge in 1940. This incident highlighted the importance of aerodynamics in bridge design. The bridge, which was nicknamed 'Galloping Gertie,' swayed excessively due to wind forces, ultimately leading to its collapse. The engineers involved did not fully account for the effects of wind on the structure, resulting in a catastrophic failure. This incident serves as a stark reminder of how neglecting certain engineering principles can lead to serious engineering casualties.Another significant case is the Challenger Space Shuttle disaster in 1986. The failure of O-ring seals in cold weather conditions led to the explosion of the shuttle shortly after launch, resulting in the loss of all seven crew members. This tragedy underscored the critical need for thorough testing and consideration of environmental factors in engineering designs. The aftermath of this engineering casualty prompted changes in NASA’s engineering protocols and emphasized the necessity of prioritizing safety over schedules and budgets.The consequences of engineering casualties extend beyond immediate physical harm. They can lead to legal repercussions, loss of public trust, and significant financial costs. For instance, the BP Deepwater Horizon oil spill in 2010, which was caused by a series of engineering failures, resulted in devastating environmental damage and billions of dollars in fines and cleanup costs. Such incidents highlight the importance of accountability and the need for engineers to adhere to ethical standards in their work.To mitigate the risk of engineering casualties, it is essential for engineering professionals to adopt a proactive approach to safety. This includes continuous education, rigorous testing, and a culture of open communication regarding potential hazards. Implementing advanced technologies such as computer simulations and predictive analytics can also help identify risks before they manifest into real-world problems.Moreover, fostering collaboration among engineers, stakeholders, and regulatory bodies can lead to better-informed decisions and safer engineering practices. By learning from past engineering casualties, the industry can evolve and improve its standards, ultimately leading to safer environments for everyone.In conclusion, engineering casualties serve as critical lessons in the engineering field. They remind us of the importance of safety, thorough analysis, and ethical responsibility in engineering practices. As we continue to innovate and push the boundaries of technology, it is imperative that we remain vigilant and prioritize the safety of our designs, ensuring that the mistakes of the past do not repeat themselves. The future of engineering relies on our ability to learn from these incidents and implement changes that will prevent further engineering casualties.

在工程领域，安全至关重要。工程师的任务是设计满足功能要求的结构和系统，同时确保用户和环境的安全。然而，尽管经过严格的规划和执行，仍然会发生故障，导致所谓的工程事故。工程事故指的是工程设计或执行中的失败导致损害、伤害或生命损失的事件。理解此类事故的影响对改善工程实践和增强安全协议至关重要。一个最显著的工程事故例子是1940年塔科马海峡大桥的坍塌。这一事件突显了空气动力学在桥梁设计中的重要性。由于风力的影响，这座桥剧烈摇摆，最终导致坍塌。这座桥被称为“摇摆的格尔蒂”，参与的工程师没有充分考虑风对结构的影响，导致了灾难性的失败。这个事件提醒我们，忽视某些工程原则可能导致严重的工程事故。另一个重要案例是1986年的挑战者航天飞机灾难。由于寒冷天气条件下O形圈密封件的失效，航天飞机在发射后不久发生爆炸，导致七名机组成员全部遇难。这场悲剧强调了在工程设计中进行彻底测试和考虑环境因素的关键需要。这次工程事故的后果促使NASA改变其工程协议，并强调将安全置于时间表和预算之上的必要性。工程事故的后果超出了直接的身体伤害。它们可能导致法律后果、公众信任的丧失以及巨大的经济成本。例如，由一系列工程失误造成的2010年BP深水地平线石油泄漏事件，导致了毁灭性的环境损害以及数十亿美元的罚款和清理成本。这类事件突显了问责制的重要性，以及工程师在工作中遵循伦理标准的必要性。为了降低工程事故的风险，工程专业人员必须采取主动的安全措施。这包括持续教育、严格测试以及对潜在危险的开放沟通文化。实施先进技术，如计算机模拟和预测分析，也可以帮助在实际问题出现之前识别风险。此外，促进工程师、利益相关者和监管机构之间的合作，可以导致更明智的决策和更安全的工程实践。通过从过去的工程事故中学习，行业可以发展并改善其标准，最终为每个人创造更安全的环境。总之，工程事故在工程领域中提供了关键的教训。它们提醒我们在工程实践中安全、全面分析和伦理责任的重要性。随着我们继续创新并推动技术的边界，我们必须保持警惕，并优先考虑设计的安全性，确保过去的错误不会重演。工程的未来依赖于我们学习这些事件并实施防止进一步工程事故的变革的能力。