A multi-objective optimisation framework for a standalone hybrid offshore renewable energy system with electrical and hydrogen loads

• Published in: Energy (Oxford) Vol. 330; p. 136826
• Main Authors: Kumar, Sumit, Panagant, Natee, Arzaghi, Ehsan, Baalisampang, Til, Garaniya, Vikram, Abbassi, Rouzbeh
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.09.2025
• Subjects: BESS; Comparative analysis; Floating solar PVs; Hybrid energy system; Hydrogen storage; Multi-objective optimization; Offshore wind; Reliability; Hydrogen storage; Floating solar PVs; Offshore wind; Multi-objective optimization; BESS; Reliability; Comparative analysis; Hybrid energy system
• ISSN: 0360-5442
• DOI: 10.1016/j.energy.2025.136826

Offshore renewable energy systems (ORESs) have substantial potential to decarbonize industries and clean energy generation. However, they face challenges, including high costs and risks due to uncertain and hazardous marine environments. To address this challenge, this study presents a multi-objective design and optimization framework for a hybrid standalone ORES powering industrial and domestic green electricity and hydrogen loads simultaneously. The hybrid ORES model integrates offshore wind (OWF) and floating solar (FPV) farms with large-scale battery energy storage systems (BESS) and hydrogen storage systems (HSS) as a firming technology. The framework optimises three conflicting objectives, including minimising cost and potential energy waste and maximising system reliability, subject to various technical and economic constraints. To regulate optimal energy flow and protect ORES components, a simple and efficient power management strategy is presented and utilized. Five recent state-of-the-art multi-objective metaheuristics are applied to solve the hybrid ORES design and obtain Pareto solutions. The comparative analysis utilises widely employed Pareto front hypervolume (HV) metric statistics and Friedman's rank test. A case sensitivity analysis is conducted to evaluate the model's robustness, reliability, and effectiveness. Validation of the methodology is conducted through a real-world case study in Australia's offshore region, showcasing its capacity to supply clean energy to industrial and domestic loads. Results indicate SHAMODE-WO's superior diversity and convergence traits in Pareto-optimal sets, with SHAMODE closely trailing. Furthermore, the average Friedman rank across all three cases designates SHAMODE-WO as the top performer. The proposed framework can facilitate decision-makers in addressing complex multi-objective ORES optimization problems and choosing optimal solutions. [Display omitted] •Design and optimization of a large-scale standalone off-grid ORES.•Hybrid OWF-FPV-BESS-HSS system model for simultaneous electricity and hydrogen demand.•Multi-objective optimization addressing three objectives: technical, economic, and risk, concurrently.•A real-world case study from the Australian offshore environment.•Application of five advanced multi-objective metaheuristics with comparative analysis.