基于WSN的舰船液舱监控系统网络设计开发
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摘要
在舰船处于海上航行的状态下,为确保其安全行驶并完成航行任务,不仅要保证舰船燃油、润滑油以及淡水等液舱装载的液位、液量以及液温与航行需求相适应,舰船同样要具备较强的稳性。基于此,本文将WSN作为主要技术,科学合理地设计并开发舰船液舱监控系统网络,进一步优化系统的自动化特征,全面提升舰船行驶可靠性以及安全性,尽量降低人力资源实际消耗量,增强工作质量与效率,借助舰船液舱监控系统网络,有效规避液体外溢而严重污染海洋环境现象的发生。
In recent years, the development speed of the shipbuilding industry has been significantly accelerated. In order to ensure safe driving and complete navigation tasks, ships must be loaded with fuel, lubricating oil and fresh water tanks. The liquid level, liquid volume and liquid temperature are compatible with the navigation requirements, and the ship must also have strong stability. Based on this, the article uses WSN as the main technology to scientifically and rationally design and develop the network of ship tank monitoring system, further optimize the automation characteristics of the system, comprehensively improve the reliability and safety of the ship, and minimize the actual consumption of human resources. Enhance the quality and efficiency of work, and use the network of ship tank monitoring system to effectively avoid the liquid spill and seriously pollute the marine environment.
In recent years, the development speed of the shipbuilding industry has been significantly accelerated. In order to ensure safe driving and complete navigation tasks, ships must be loaded with fuel, lubricating oil and fresh water tanks. The liquid level, liquid volume and liquid temperature are compatible with the navigation requirements, and the ship must also have strong stability. Based on this, the article uses WSN as the main technology to scientifically and rationally design and develop the network of ship tank monitoring system, further optimize the automation characteristics of the system, comprehensively improve the reliability and safety of the ship, and minimize the actual consumption of human resources. Enhance the quality and efficiency of work, and use the network of ship tank monitoring system to effectively avoid the liquid spill and seriously pollute the marine environment.
引文
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[3]夏讨饭.新型极地模块运输船总体设计综述[J].船舶标准化工程师, 2018, 51(04):34–38.
[4]金键,侯海量,陈鹏宇,等.水下接触爆炸下液舱前置型防雷舱的动响应分析[J].国防科技大学学报, 2018, 40(03):142–147.
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