Design of Risk Prediction Assessment for Ship-Integrated Electric Propulsion System

IF 0.5 4区工程技术 Q4 ENGINEERING, MARINE

Journal of Ship Production and Design Pub Date : 2021-08-04 DOI:10.5957/jspd.12180058

Pengfei Zhi, Zhiyu Zhu, Wanlu Zhu, Qiu Haiyang

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引用次数: 0

Abstract

A design of risk prediction assessment is proposed to improve the safety and economy of ship-integrated electric propulsion system(SIEPS). Firstly, the article puts forward a multihidden Markov model (MHMM)–Viterbi algorithm to predict fault state probabilities of each component in the continuous time points in the future. Secondly, according to the influence of dynamic ocean condition, the fault states of the components of SIEPS are predicted by using the MHMM–Viterbi algorithm. Thirdly, the risk assessment system of network topology of SIEPS is designed, and power flow analysis under the abnormal condition is repeatedly calculated by using the MonteCarlo simulation. Finally, the article takes a SIEPS as an example and the risk prediction assessment results is given. With the establishment of increasingly stringent standards by the International Maritime Organization in terms of ship emissions and the increasing scarcity of petroleum resources, electric propulsion systems are gradually replacing internal combustion engines, which will become the future direction of ship power development. Electric propulsion ships do have many advantages such as high efficiency, high automation, environmental protection, energy saving, and emission reduction. However, ship-integrated electric propulsion system(SIEPS) is also the soft underbelly of electric propulsion ships. First of all, the complexity of the external environment factors such as high humidity and high salinity of ships (especially marine vessels) under long-term operating conditions, and the coupling of electromagnetic, thermal, and vibration signals of SIEPS will increase the failure rate of electrical equipment, thereby increasing the risk of SIEPS. Secondly, for electric propulsion ships, the SIEPS risk is likely to lead to chain failure of important systems such as power, control, navigation, resulting in the ship. Equipment and even personnel cause irreparable damage, causing fatal damage to electric propulsion ships. Therefore, in order to improve the safety, reliability, and economy of electric propulsion ships, it is necessary to carry out research on relevant technologies for SIEPS risk assessment (Wen et al. 2012; Guangfu et al. 2013).

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舰船综合电力推进系统风险预测评估设计

为提高船舶综合电力推进系统(SIEPS)的安全性和经济性，提出了一种风险预测评估设计。首先，提出了一种多隐马尔可夫模型(MHMM) -Viterbi算法来预测未来连续时间点各部件的故障状态概率。其次，根据海洋动态条件的影响，采用MHMM-Viterbi算法对SIEPS各分量的故障状态进行预测;再次，设计了SIEPS网络拓扑风险评估体系，利用MonteCarlo仿真反复计算了异常工况下的潮流分析。最后，本文以SIEPS为例，给出了风险预测评价结果。随着国际海事组织对船舶排放标准的日益严格以及石油资源的日益匮乏，电力推进系统正在逐步取代内燃机，成为未来船舶动力发展的方向。电力推进船舶确实具有效率高、自动化程度高、环保节能减排等诸多优点。然而，船舶综合电力推进系统(SIEPS)也是电力推进船舶的软肋。首先，船舶(特别是海船)在长期运行状态下的高湿、高盐度等外部环境因素的复杂性，以及SIEPS的电磁、热、振动信号的耦合，会增加电气设备的故障率，从而增加SIEPS的风险。其次，对于电力推进船舶而言，SIEPS风险可能导致动力、控制、导航等重要系统发生连锁故障，导致船舶沉没。设备甚至人员造成不可弥补的损害，对电力推进船舶造成致命损害。因此，为了提高电力推进船舶的安全性、可靠性和经济性，有必要开展SIEPS风险评估的相关技术研究(Wen et al. 2012;Guangfu et al. 2013)。

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来源期刊

Journal of Ship Production and Design ENGINEERING, MARINE-

CiteScore

1.10

自引率

0.00%

发文量

期刊介绍： Original and timely technical papers addressing problems of shipyard techniques and production of merchant and naval ships appear in this quarterly publication. Since its inception, the Journal of Ship Production and Design (formerly the Journal of Ship Production) has been a forum for peer-reviewed, professionally edited papers from academic and industry sources. As such it has influenced the worldwide development of ship production engineering as a fully qualified professional discipline. The expanded scope seeks papers in additional areas, specifically ship design, including design for production, plus other marine technology topics, such as ship operations, shipping economics, and safety. Each issue contains a well-rounded selection of technical papers relevant to marine professionals.