船舶运行数据驱动的能量性能评估——以一艘混合动力舰艇为例

IF 2.6 4区工程技术 Q1 Engineering

Journal of Marine Engineering and Technology Pub Date : 2022-04-27 DOI:10.1080/20464177.2022.2058690

N. Vasilikis, R. Geertsma, K. Visser

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引用次数: 6

摘要

除了海上验收试验之外，船舶设计者几乎从未从他们设计的实际操作中收到反馈。同样，操作船只的船员也不清楚不同选择的能源性能和环境足迹。本文提出了一种基于连续监测的操作数据的方法，并将其应用于荷兰皇家海军的一艘海洋巡逻艇，以确定在整个操作范围内不同操作条件对能源性能的影响，同时也检查了为船舶配备混合动力推进的决定。具体来说，它引入了平均能源效率指标和离散船舶航速的平均总能源效率，作为量化能源收益和损失的主要工具，以帮助制定更明智的设计和运营决策。此外，它还演示了一个数据集丰富程序，使用制造商的信息，以防并非所有需要的传感器都可用。结果表明，电力推进的效率比最佳的机械推进模式低15-25%，并且在船舶的整体能源性能方面，速度每增加1节，在8至14节和14节以上的最小/英里排放量分别增加7%和14%。

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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Operational data-driven energy performance assessment of ships: the case study of a naval vessel with hybrid propulsion

Ship designers hardly ever receive feedback from the actual operation of their designs apart from sea acceptance trials. Similarly, crews operating the vessels do not receive a clear picture of the energy performance and environmental footprint of different options. This paper proposes a methodology based on operational data from continuous monitoring, and applies it to an ocean patrol vessel of the Royal Netherlands Navy in order to identify the impact of diverse operational conditions on energy performance over the whole operating range, but also to examine the decision to equip the vessel with hybrid propulsion. Specifically, it introduces mean energy effectiveness indicator and mean total energy efficiency over discretised vessel speed, as the main tool in quantifying the energy gains and losses to assist in making better-advised design and operational decisions. Moreover, it demonstrates a dataset enrichment procedure, using manufacturers' information, in case not all needed sensors are available. Results suggest that electrical propulsion was 15–25% less efficient than the best mechanical propulsion mode, and on the overall energy performance of the vessel, increasing speed by 1 knot caused a 7% and 14% increase over the minimum /mile emissions between 8 and 14, and above 14 knots respectively.

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来源期刊

Journal of Marine Engineering and Technology 工程技术-工程：海洋

CiteScore

5.20

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： The Journal of Marine Engineering and Technology will publish papers concerned with scientific and theoretical research applied to all aspects of marine engineering and technology in addition to issues associated with the application of technology in the marine environment. The areas of interest will include: • Fuel technology and Combustion • Power and Propulsion Systems • Noise and vibration • Offshore and Underwater Technology • Computing, IT and communication • Pumping and Pipeline Engineering • Safety and Environmental Assessment • Electrical and Electronic Systems and Machines • Vessel Manoeuvring and Stabilisation • Tribology and Power Transmission • Dynamic modelling, System Simulation and Control • Heat Transfer, Energy Conversion and Use • Renewable Energy and Sustainability • Materials and Corrosion • Heat Engine Development • Green Shipping • Hydrography • Subsea Operations • Cargo Handling and Containment • Pollution Reduction • Navigation • Vessel Management • Decommissioning • Salvage Procedures • Legislation • Ship and floating structure design • Robotics Salvage Procedures • Structural Integrity Cargo Handling and Containment • Marine resource and acquisition • Risk Analysis Robotics • Maintenance and Inspection Planning Vessel Management • Marine security • Risk Analysis • Legislation • Underwater Vehicles • Plant and Equipment • Structural Integrity • Installation and Repair • Plant and Equipment • Maintenance and Inspection Planning.