Detail publikačního výsledku

Optimisation of island integrated energy system based on marine renewable energy

Zhao Wen Wang Bohong, BEng, Ph.D. Pan Ting, MSc, Ph.D. Chen Yujie Tao Hengcong Guo Baoying Varbanov Petar Sabev, prof. Ing. Dr. habil., Ph.D. Lu Jinshu

Originální název

Optimisation of island integrated energy system based on marine renewable energy

Anglický název

Optimisation of island integrated energy system based on marine renewable energy

Druh

Článek WoS

Originální abstrakt

Integrating marine renewable energy (MRE) with conventional energy sources and logically constructing island energy systems is crucial for alleviating island energy supply challenges and helping coastal energy systems achieve a sustainable, low-carbon transition. In this study, the status of marine energy utilisation technologies is reviewed, with a focus on advancements in energy conversion equipment, grid integration, and energy storage. The economic feasibility and environmental sustainability of marine energy systems are comparatively analysed to enhance the development and utilisation of marine energy technology while reducing the economic cost of power generation. Suitable equipment is highlighted for islands, with efficient energy generation strategies proposed to achieve cleaner, localised, and cost-effective island integrated energy system (IIES) design. Island energy facilities vary, and integrated development is crucial for building new energy systems. Based on the types and resources of island energy, IIESs are constructed for hierarchical energy utilisation and multi-energy coupling, coordinating resources to achieve source-grid-load-storage integration. The optimisation of IIESs is reviewed, with a focus on modelling methods, intelligent algorithm development, and system simulation. This study differs from previous research as it considers the integration of marine energy into existing systems to achieve comprehensive integration of multiple energy sources. Additionally, optimisation and solution methods for IIES models are summarised. To integrate complex, multivariable energy systems and create stable and predictable outputs, marine energy and load forecasting methods are explored. Overall, this study supports the advancement of marine energy utilisation, focusing on its progressive integration into island energy systems as the efficiency of marine energy improves. This work aims to inspire the development of new functions and modules based on existing system optimisation and forecasting techniques.

Anglický abstrakt

Integrating marine renewable energy (MRE) with conventional energy sources and logically constructing island energy systems is crucial for alleviating island energy supply challenges and helping coastal energy systems achieve a sustainable, low-carbon transition. In this study, the status of marine energy utilisation technologies is reviewed, with a focus on advancements in energy conversion equipment, grid integration, and energy storage. The economic feasibility and environmental sustainability of marine energy systems are comparatively analysed to enhance the development and utilisation of marine energy technology while reducing the economic cost of power generation. Suitable equipment is highlighted for islands, with efficient energy generation strategies proposed to achieve cleaner, localised, and cost-effective island integrated energy system (IIES) design. Island energy facilities vary, and integrated development is crucial for building new energy systems. Based on the types and resources of island energy, IIESs are constructed for hierarchical energy utilisation and multi-energy coupling, coordinating resources to achieve source-grid-load-storage integration. The optimisation of IIESs is reviewed, with a focus on modelling methods, intelligent algorithm development, and system simulation. This study differs from previous research as it considers the integration of marine energy into existing systems to achieve comprehensive integration of multiple energy sources. Additionally, optimisation and solution methods for IIES models are summarised. To integrate complex, multivariable energy systems and create stable and predictable outputs, marine energy and load forecasting methods are explored. Overall, this study supports the advancement of marine energy utilisation, focusing on its progressive integration into island energy systems as the efficiency of marine energy improves. This work aims to inspire the development of new functions and modules based on existing system optimisation and forecasting techniques.

Klíčová slova

Marine renewable energy, Energy conversion and storage, Island integrated energy system, Process systems engineering, Process integration

Klíčová slova v angličtině

Marine renewable energy, Energy conversion and storage, Island integrated energy system, Process systems engineering, Process integration

Autoři

Zhao Wen Wang Bohong, BEng, Ph.D. Pan Ting, MSc, Ph.D. Chen Yujie Tao Hengcong Guo Baoying Varbanov Petar Sabev, prof. Ing. Dr. habil., Ph.D. Lu Jinshu

Rok RIV

2026

Vydáno

01.09.2025

Nakladatel

Keai Publishing Ltd

Periodikum

Fundamental Research

Svazek

5

Číslo

5

Stát

Čínská lidová republika

Strany od

2161

Strany do

2179

Strany počet

19

URL

BibTex

@article{BUT201332,
  author="{} and Bohong {Wang} and Ting {Pan} and  {} and  {} and  {} and Petar Sabev {Varbanov} and  {}",
  title="Optimisation of island integrated energy system based on marine renewable energy",
  journal="Fundamental Research",
  year="2025",
  volume="5",
  number="5",
  pages="2161--2179",
  doi="10.1016/j.fmre.2024.11.022",
  issn="2096-9457",
  url="https://www.sciencedirect.com/science/article/pii/S2667325824005120"
}