engineered safety system

简明释义

外设安全系统

英英释义

例句

1.The construction site implemented an engineered safety system to minimize accidents.

建筑工地实施了一个工程安全系统以减少事故。

2.The engineered safety system in the chemical plant helps prevent hazardous spills.

化工厂中的工程安全系统有助于防止危险泄漏。

3.The factory upgraded its engineered safety system to comply with new regulations.

工厂升级了其工程安全系统以符合新的法规。

4.In the aerospace industry, an engineered safety system is crucial for ensuring passenger safety during flights.

在航空航天行业，工程安全系统对于确保乘客在飞行期间的安全至关重要。

5.Each vehicle is equipped with an engineered safety system to protect occupants in case of an accident.

每辆车都配备了一个工程安全系统以保护乘员在事故发生时的安全。

作文

In today's rapidly advancing technological landscape, the importance of an engineered safety system cannot be overstated. These systems are meticulously designed to prevent accidents and mitigate risks in various environments, from industrial facilities to everyday consumer products. An engineered safety system (工程安全系统) is a comprehensive approach that integrates multiple components, including design, materials, processes, and operational protocols, all aimed at ensuring safety and reliability.One of the primary functions of an engineered safety system is to identify potential hazards before they can cause harm. This proactive approach involves thorough risk assessments and the implementation of safety measures during the design phase of a project. For instance, in the aerospace industry, engineers employ sophisticated modeling techniques to predict how different materials and designs will perform under extreme conditions. By doing so, they can create an engineered safety system that not only meets regulatory standards but also provides an additional layer of protection for both the crew and passengers.Moreover, an engineered safety system often includes fail-safes and redundancies to ensure that if one component fails, others can take over to prevent catastrophic outcomes. In electrical engineering, for example, circuit breakers are a crucial part of an engineered safety system. They automatically shut off power when a fault is detected, protecting both equipment and users from potential dangers such as electric shocks or fires.In the realm of construction, the application of engineered safety systems is vital. Building codes and regulations are established to ensure that structures can withstand environmental stresses such as earthquakes, wind, and flooding. Engineers use advanced simulations to test their designs against these forces, creating buildings that not only comply with safety standards but also enhance the overall resilience of communities.Another critical aspect of an engineered safety system is the incorporation of user feedback and continuous improvement. After a product or system is deployed, real-world performance data is collected to identify any shortcomings. This information is invaluable for refining existing systems and developing new ones. For example, automotive manufacturers analyze crash data to improve the design of safety features such as airbags and seat belts, ensuring that each new model is safer than its predecessors.Furthermore, training and education play a significant role in the effectiveness of an engineered safety system. No matter how advanced a safety system may be, it requires knowledgeable personnel to operate and maintain it. Regular training sessions help ensure that employees understand the safety protocols and can respond effectively in emergency situations. This human factor is often the most crucial element in the success of any safety system.In conclusion, the concept of an engineered safety system is essential across various industries. By combining innovative design, rigorous testing, and ongoing evaluation, these systems provide a framework for minimizing risks and enhancing safety. As technology continues to evolve, so too will the methods used to engineer safety systems, ultimately leading to a safer world for all. Investing in these systems not only protects lives but also fosters trust in the technologies we rely on daily. The future of safety lies in our ability to engineer it effectively, ensuring that we can navigate the complexities of modern life with confidence and security.

在当今快速发展的技术环境中，工程安全系统的重要性不容小觑。这些系统经过精心设计，以防止事故并减轻各种环境中的风险，从工业设施到日常消费品。工程安全系统（engineered safety system）是一种综合方法，整合了多个组件，包括设计、材料、工艺和操作协议，旨在确保安全和可靠性。工程安全系统的主要功能之一是识别潜在危害，以便在造成伤害之前采取措施。这种主动的方法涉及全面的风险评估，并在项目设计阶段实施安全措施。例如，在航空航天行业，工程师采用复杂的建模技术来预测不同材料和设计在极端条件下的表现。通过这样做，他们可以创建一个工程安全系统，不仅满足监管标准，还为机组人员和乘客提供额外的保护层。此外，工程安全系统通常包括故障安全和冗余机制，以确保如果一个组件发生故障，其他组件可以接管以防止灾难性后果。在电气工程中，例如，断路器是工程安全系统的重要组成部分。当检测到故障时，它们会自动切断电源，保护设备和用户免受电击或火灾等潜在危险。在建筑领域，工程安全系统的应用至关重要。建筑规范和法规的建立是为了确保结构能够承受地震、风和洪水等环境压力。工程师使用先进的模拟技术对其设计进行测试，以应对这些力量，从而创建不仅符合安全标准，而且提高社区整体韧性的建筑。工程安全系统的另一个关键方面是用户反馈和持续改进的结合。在产品或系统投入使用后，收集实际性能数据以识别任何缺陷。这些信息对完善现有系统和开发新系统至关重要。例如，汽车制造商分析碰撞数据，以改善安全功能的设计，如安全气囊和安全带，确保每个新型号的安全性都优于其前身。此外，培训和教育在工程安全系统的有效性中也发挥着重要作用。无论安全系统有多先进，都需要知识渊博的人员来操作和维护它。定期的培训课程有助于确保员工了解安全协议，并能在紧急情况下有效应对。这一人因素往往是任何安全系统成功的最关键因素。总之，工程安全系统的概念在各个行业中都是至关重要的。通过结合创新设计、严格测试和持续评估，这些系统提供了一个框架，以最小化风险并增强安全性。随着技术的不断发展，工程安全系统的方法也将不断演变，最终为所有人创造一个更安全的世界。投资这些系统不仅保护生命，还增强了我们对日常依赖技术的信任。安全的未来在于我们有效地工程化它，确保我们能够自信和安全地驾驭现代生活的复杂性。