complete bridge-control system

简明释义

全套驾驶室控制系统

英英释义

A complete bridge-control system refers to an integrated set of components and technologies designed to manage and operate the various functions of a bridge, including traffic control, structural monitoring, and safety systems.

完整的桥梁控制系统是指一套集成的组件和技术,旨在管理和操作桥梁的各种功能,包括交通控制、结构监测和安全系统。

例句

1.A modern complete bridge-control system can significantly reduce human error in maritime operations.

现代的完整的桥梁控制系统可以显著减少海运操作中的人为错误。

2.Training sessions are held to familiarize crew members with the complete bridge-control system.

培训课程旨在使船员熟悉完整的桥梁控制系统

3.The new vessel is equipped with a complete bridge-control system, ensuring optimal navigation and safety.

这艘新船配备了一个完整的桥梁控制系统,确保最佳的导航和安全。

4.The complete bridge-control system includes advanced radar and communication tools.

完整的桥梁控制系统包括先进的雷达和通信工具。

5.During the test, the engineers evaluated the complete bridge-control system for any potential malfunctions.

在测试期间,工程师评估了完整的桥梁控制系统是否存在潜在故障。

作文

In the modern world, infrastructure plays a crucial role in ensuring the smooth functioning of society. Among the various structures that support our daily lives, bridges stand out as vital components that connect different regions and facilitate transportation. However, the safety and efficiency of these bridges depend significantly on their management and monitoring systems. This is where a complete bridge-control system comes into play. A complete bridge-control system refers to an integrated network of technologies and processes designed to monitor, manage, and maintain bridges effectively. It encompasses various components, including sensors, data analytics, and control mechanisms, all working together to ensure that bridges remain safe for public use.The primary function of a complete bridge-control system is to provide real-time monitoring of the structural integrity of bridges. Sensors installed on the bridge can detect vibrations, temperature changes, and even potential cracks or weaknesses in the structure. This data is then transmitted to a central control unit, where advanced algorithms analyze the information to assess the bridge's condition. By continuously monitoring these factors, engineers can identify any issues before they escalate, ensuring timely maintenance and repairs.Moreover, a complete bridge-control system enhances the overall safety of bridges. In the event of extreme weather conditions, such as heavy rainfall or earthquakes, the system can automatically alert authorities about potential risks. This proactive approach allows for immediate action to be taken, such as closing the bridge to traffic until it is deemed safe for use. Such measures not only protect public safety but also prolong the lifespan of the bridge itself.In addition to safety, a complete bridge-control system contributes to optimizing traffic flow. By integrating traffic management systems, the control system can monitor vehicle congestion and adjust traffic signals accordingly. For instance, if a bridge is experiencing heavy traffic, the system can implement strategies to redirect vehicles to alternative routes, thereby reducing congestion and improving overall travel times. This integration of technology not only benefits commuters but also enhances the efficiency of the transportation network as a whole.Furthermore, the implementation of a complete bridge-control system can lead to significant cost savings over time. By identifying maintenance needs early through continuous monitoring, municipalities can avoid costly repairs that result from neglect. Regular upkeep based on data-driven insights ensures that bridges remain in optimal condition, ultimately saving taxpayer money and resources.In conclusion, the significance of a complete bridge-control system cannot be overstated. As bridges continue to be essential arteries of transportation, the integration of advanced monitoring and management technologies is imperative. Not only does this system enhance safety and efficiency, but it also promotes sustainable infrastructure practices. As we move towards a more technologically advanced future, investing in complete bridge-control systems will undoubtedly yield long-term benefits for society as a whole, ensuring that our bridges remain safe and functional for generations to come.

在现代社会,基础设施在确保社会顺利运作方面发挥着至关重要的作用。在支持我们日常生活的各种结构中,桥梁作为连接不同地区并促进交通的重要组成部分,显得尤为突出。然而,这些桥梁的安全性和效率在很大程度上依赖于其管理和监控系统。这就是一个完整的桥梁控制系统派上用场的地方。完整的桥梁控制系统是指一个综合的技术和流程网络,旨在有效监控、管理和维护桥梁。它包括多个组件,包括传感器、数据分析和控制机制,所有这些都共同努力以确保桥梁对公众使用的安全。完整的桥梁控制系统的主要功能是提供桥梁结构完整性的实时监测。安装在桥梁上的传感器可以检测振动、温度变化,甚至潜在的裂缝或结构弱点。然后,这些数据被传输到中央控制单元,其中先进的算法分析信息以评估桥梁的状况。通过持续监测这些因素,工程师可以在问题升级之前识别出任何问题,从而确保及时的维护和修理。此外,完整的桥梁控制系统增强了桥梁的整体安全性。在极端天气条件下,例如暴雨或地震,系统可以自动向当局发出潜在风险的警报。这种主动的方法允许立即采取行动,例如在桥梁被认为安全之前关闭交通。这些措施不仅保护公众安全,还延长了桥梁本身的使用寿命。除了安全之外,完整的桥梁控制系统还有助于优化交通流量。通过集成交通管理系统,控制系统可以监控车辆拥堵情况并相应地调整交通信号。例如,如果一座桥正经历严重的交通,系统可以实施策略将车辆引导到替代路线,从而减少拥堵并改善整体旅行时间。这种技术的整合不仅使通勤者受益,而且提高了整个交通网络的效率。此外,实施完整的桥梁控制系统可以在长期内节省大量成本。通过持续监测及早识别维护需求,市政当局可以避免因忽视而导致的昂贵修理。基于数据驱动的见解进行的定期维护确保桥梁保持最佳状态,最终节省纳税人的资金和资源。总之,完整的桥梁控制系统的重要性不容小觑。随着桥梁继续成为交通的重要动脉,整合先进的监测和管理技术是必不可少的。这一系统不仅增强了安全性和效率,而且促进了可持续基础设施实践。随着我们迈向一个更具技术先进性的未来,投资于完整的桥梁控制系统无疑将为整个社会带来长期利益,确保我们的桥梁在未来几代人中保持安全和功能。