Model-based Parametric Study for Comparison of System Configurations and Control of a Hydrogen Hybrid Cargo Vessel

Modelling and Optimisation of Ship Energy Systems 2023 Pub Date : 2024-01-03 DOI:10.59490/moses.2023.671

Foivos Mylonopoulos, Timon Kopka, Andrea Coraddu, Henk Polinder

{"title":"Model-based Parametric Study for Comparison of System Configurations and Control of a Hydrogen Hybrid Cargo Vessel","authors":"Foivos Mylonopoulos, Timon Kopka, Andrea Coraddu, Henk Polinder","doi":"10.59490/moses.2023.671","DOIUrl":null,"url":null,"abstract":"The current state of research in marine energy systems has concentrated on conventional diesel systems, while limited literature is available on the configuration and control of alternative energy sources such as hydrogen hybrid systems, which have attracted increasing interest recently owing to the energy transition. This paper presents a modelling and control study for conceptual retrofitting of a general cargo vessel to a hydrogen-hybrid version. Generic fuel cell, battery, and converter models are used, enabling easy adaptation to various powerplant sizes and ship types. A robustly coordinated Energy Management Strategy (EMS), which can be implemented for different vessel’s power profiles, was developed for power sharing, DC bus voltage control, and battery State of Charge (SoC) regulation. The total installed fuel cell power and battery capacity were heuristically selected from a range of power profiles of the ship. A database of fuel cells with stacks from different manufacturers was created to test different combinations in terms of fuel consumption, cost, and weight, based on the framework of the problem. Uncertainties in terms of fuel prices are presented using normal distribution graphs. The system configurations and control results are presented for one power profile of the vessel and the average fuel costs. It is demonstrated that with the proposed control method, the power losses are less than 1%, the DC bus voltage fluctuations are less than 0.5%, and the battery SoC remains between 35-65% for the entire duration of the analysed power profile. The configuration with eight stacks of 150 kW has the lowest total fuel cost (730 $) with an average difference of 7.1% from the other solutions, and the lowest total weight (10.54 tons) with an average difference of 15.4% from the other configurations. Overall, this study demonstrates the efficient configuration and control of hybrid energy systems using parameterized components.","PeriodicalId":513616,"journal":{"name":"Modelling and Optimisation of Ship Energy Systems 2023","volume":"4 6","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-01-03","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Modelling and Optimisation of Ship Energy Systems 2023","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.59490/moses.2023.671","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 0

Abstract

The current state of research in marine energy systems has concentrated on conventional diesel systems, while limited literature is available on the configuration and control of alternative energy sources such as hydrogen hybrid systems, which have attracted increasing interest recently owing to the energy transition. This paper presents a modelling and control study for conceptual retrofitting of a general cargo vessel to a hydrogen-hybrid version. Generic fuel cell, battery, and converter models are used, enabling easy adaptation to various powerplant sizes and ship types. A robustly coordinated Energy Management Strategy (EMS), which can be implemented for different vessel’s power profiles, was developed for power sharing, DC bus voltage control, and battery State of Charge (SoC) regulation. The total installed fuel cell power and battery capacity were heuristically selected from a range of power profiles of the ship. A database of fuel cells with stacks from different manufacturers was created to test different combinations in terms of fuel consumption, cost, and weight, based on the framework of the problem. Uncertainties in terms of fuel prices are presented using normal distribution graphs. The system configurations and control results are presented for one power profile of the vessel and the average fuel costs. It is demonstrated that with the proposed control method, the power losses are less than 1%, the DC bus voltage fluctuations are less than 0.5%, and the battery SoC remains between 35-65% for the entire duration of the analysed power profile. The configuration with eight stacks of 150 kW has the lowest total fuel cost (730 $) with an average difference of 7.1% from the other solutions, and the lowest total weight (10.54 tons) with an average difference of 15.4% from the other configurations. Overall, this study demonstrates the efficient configuration and control of hybrid energy systems using parameterized components.

查看原文本刊更多论文

基于模型的参数研究，用于比较氢气混合动力货船的系统配置和控制

海洋能源系统的研究现状主要集中在传统的柴油系统上，而关于氢混合动力系统等替代能源的配置和控制方面的文献资料则十分有限，最近由于能源转型，氢混合动力系统越来越受到关注。本文介绍了将一艘普通货船概念性改造为氢混合动力版本的建模和控制研究。文中使用了通用的燃料电池、电池和转换器模型，可轻松适应各种动力装置尺寸和船舶类型。针对功率共享、直流母线电压控制和电池充电状态（SoC）调节，开发了一种稳健协调的能源管理策略（EMS），可针对不同的船舶功率曲线实施。安装的燃料电池总功率和电池容量是从一系列船舶功率曲线中启发式选出的。根据问题的框架，创建了一个不同制造商生产的燃料电池数据库，以测试燃料消耗、成本和重量方面的不同组合。燃料价格的不确定性用正态分布图表示。针对船舶的一个功率曲线和平均燃料成本，介绍了系统配置和控制结果。结果表明，采用建议的控制方法后，功率损耗小于 1%，直流母线电压波动小于 0.5%，电池 SoC 在整个分析功率曲线期间保持在 35-65% 之间。8 个 150 千瓦堆栈的配置具有最低的总燃料成本（730 美元），与其他解决方案的平均差异为 7.1%；总重量（10.54 吨）最低，与其他配置的平均差异为 15.4%。总之，本研究展示了利用参数化组件对混合能源系统进行高效配置和控制的方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Modelling and Optimisation of Ship Energy Systems 2023

自引率

0.00%

发文量