The Modeling and Optimal Control of a Hybrid Propulsion System for an Ice-Capable Tanker

IF 1.3 4区 工程技术 Q3 ENGINEERING, CIVIL Journal of Ship Research Pub Date : 2021-10-11 DOI:10.5957/josr.11200059
Yi Zhou, K. Pazouki, R. Norman
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Abstract

With the effects of global warming, the North Sea Route has become an economic option for cargo transportation because of the shorter distance between East Asia and Europe. Generally, conventional mechanical propulsion systems installed in ice-capable tankers suffer from significant drawbacks because of poor fuel efficiency when sailing at low speed, therefore, advanced technologies have been applied such as diesel electric and nuclear-powered propulsion; however, drawbacks still exist. Hybrid propulsion is a more environmental-friendly, economical solution for ships with icebreaking capability, which can address the drawbacks in both diesel electric and nuclear power systems. In this paper, modeling of system components is presented and implemented in MATLAB Simulink. A primary control strategy is applied to the system to ensure system stability, and an advanced secondary strategy is developed and applied to the power sources to minimize fuel consumption. Given two scenarios, the simulation results of the hybrid propulsion system developed in this research and those of diesel electric propulsion systems with DC and AC distribution systems are compared and indicate that the hybrid system can offer up to 22.4% fuel savings over ice-loading condition, and 39.5% fuel reduction over the particular voyage of varying speed in open water is applied in this paper. In recent years, some sea routes that were previously blocked by ice have become increasingly accessible in the warmest months of the year due to the effects of global warming. Researchers have estimated that, by 2030, the percentage of Arctic shipping will have increased to 25% of cargo trade between Europe and Asia (Lasserre 2019). Northern Sea Route (NSR) shipping provides benefits for international trade, but challenges still exist. Increasing carbon emissions have seriously impacted the Arctic environment (Hassol & Corell 2006). Table 1 shows the total number of ships using Heavy Fuel Oil (HFO) in Arctic waters in 2015, and associated black carbon emissions, as published by the IMO (Comer et al. 2017). As it is shown, oil tankers made up just 4.5% of all ships entering Arctic waters but despite their low proportion, they were responsible for 17% of black carbon emissions. Thus, an environmentally friendly and fuel-efficient propulsion system to reduce these emissions from tankers trading in Arctic waters is required.
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破冰油轮混合动力推进系统的建模与优化控制
随着全球变暖的影响,由于东亚和欧洲之间的距离较短,北海航线已成为货物运输的经济选择。通常,安装在破冰油轮上的传统机械推进系统在低速航行时由于燃料效率低而存在显著缺陷,因此,已经应用了先进的技术,如柴电和核动力推进;然而,缺点仍然存在。对于具有破冰能力的船舶来说,混合动力推进是一种更环保、更经济的解决方案,可以解决柴电和核能系统的缺点。本文介绍了系统组件的建模方法,并在MATLAB Simulink中实现。将一级控制策略应用于系统以确保系统稳定性,并开发高级二级策略并将其应用于电源以最大限度地减少燃料消耗。在两种情况下,将本研究开发的混合动力推进系统与具有直流和交流配电系统的柴电推进系统的仿真结果进行了比较,结果表明,在冰载条件下,混合动力系统可以节省高达22.4%的燃料,在开放水域变速的特定航程中,燃料减少了39.5%。近年来,由于全球变暖的影响,在一年中最温暖的几个月里,一些以前被冰阻断的海上航线变得越来越容易到达。研究人员估计,到2030年,北极航运在欧洲和亚洲货物贸易中的比例将增至25%(Lasserre 2019)。北海航线(NSR)航运为国际贸易带来了好处,但挑战仍然存在。不断增加的碳排放严重影响了北极环境(Hassol&Corell,2006年)。表1显示了国际海事组织发布的2015年在北极水域使用重燃料油(HFO)的船只总数以及相关的黑碳排放量(Comer等人,2017)。如图所示,油轮仅占进入北极水域的所有船只的4.5%,但尽管比例较低,它们还是造成了17%的黑碳排放。因此,需要一个环境友好、节能的推进系统来减少在北极水域交易的油轮的这些排放。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Ship Research
Journal of Ship Research 工程技术-工程:海洋
CiteScore
2.80
自引率
0.00%
发文量
12
审稿时长
6 months
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 economic, and safety. Each issue contains a well-rounded selection of technical papers relevant to marine professionals.
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