POWER CONVERSION NETWORKING AND MODELING APPROACH FOR WAVE-WIND-SOLAR-STORAGE INTEGRATED PLATFORM

Lin Yingming; Yan Binjie; Xie Pingping; Zeng Kaiyue; Gao Dongzhao; Wang Kunlin

doi:10.19912/j.0254-0096.tynxb.2025-0031

PDF(3094 KB)

Acta Energiae Solaris Sinica ›› 2026, Vol. 47 ›› Issue (5) : 146-155. DOI: 10.19912/j.0254-0096.tynxb.2025-0031

POWER CONVERSION NETWORKING AND MODELING APPROACH FOR WAVE-WIND-SOLAR-STORAGE INTEGRATED PLATFORM

Lin Yingming¹, Yan Binjie¹, Xie Pingping¹, Zeng Kaiyue¹, Gao Dongzhao^2~4, Wang Kunlin^2~4

Author information +

History +

Abstract

To address the stable power supply challenge posed by volatile, intermittent, and random renewable energy integration in wave-wind-solar-storage integrated power generation platforms with various installed capacity configurations and operation modes, three wave-wind-solar-storage integrated offshore platform topology circuits and power conversion networking technologies are proposed. A comprehensive simulation model, including wind, solar, wave, energy storage, and load is established. The system is tested under different operation modes and various disturbance conditions. The results show that the renewable energy are independently and efficiently converted, and the voltage and frequency are stabilized. The wave-wind-solar-storage integrated networking and modeling method provides an effective solution adaptable to various offshore power generation platform scenarios, effectively addressing the challenge of stable power supply for wave-wind-solar-storage power generation platforms. This method offers effective technical support for the integration of marine renewable energy, accommodating increasingly complex platform topologies, diversified power generation units, and hybrid converter technologies.

Key words

renewable energy / wave energy converters / wind power integration / solar energy / networking technologies / power conversion

Cite this article

EndNote

Ris (Procite)

Bibtex

Download Citations

Lin Yingming, Yan Binjie, Xie Pingping, Zeng Kaiyue, Gao Dongzhao, Wang Kunlin. POWER CONVERSION NETWORKING AND MODELING APPROACH FOR WAVE-WIND-SOLAR-STORAGE INTEGRATED PLATFORM[J]. Acta Energiae Solaris Sinica. 2026, 47(5): 146-155 https://doi.org/10.19912/j.0254-0096.tynxb.2025-0031

References

[1] MAHMUD K, RAHMAN M S, RAVISHANKAR J, et al.Real-time load and ancillary support for a remote island power system using electric boats[J]. IEEE transactions on industrial informatics, 2020, 16(3): 1516-1528.
[2] XIAO H Q, HUANG X W, HUANG Y, et al.Self-synchronizing control and frequency response of offshore wind farms connected to diode rectifier based HVDC system[J]. IEEE transactions on sustainable energy, 2022, 13(3): 1681-1692.
[3] GAO R, SHE X, HUSAIN I, et al.Solid-state-transformer-interfaced permanent magnet wind turbine distributed generation system with power management functions[J]. IEEE transactions on industry applications, 2017, 53(4): 3849-3861.
[4] RADHIANSYAH, RACHMILDA T D, HAMDANI D. Performance analysis of offshore floating PV systems in isolated area[C]//2021 3rd International Conference on High Voltage Engineering and Power Systems (ICHVEPS). Bandung, Indonesia, 2021: 651-655.
[5] ZHENG H D, ZHENG X Y, LEI Y, et al.Experimental validation on the dynamic response of a novel floater uniting a vertical-axis wind turbine with a steel fishing cage[J]. Ocean engineering, 2022, 243: 110257.
[6] EDWARDS E C, HOLCOMBE A, BROWN S, et al.Trends in floating offshore wind platforms: a review of early-stage devices[J]. Renewable and sustainable energy reviews, 2024, 193: 114271.
[7] WU X R, XIAO W Q, YANG L J, et al.Research on hydrodynamic characteristics of an offshore flexible floating photovoltaic in waves[C]//2022 3rd International Conference on Geology, Mapping and Remote Sensing (ICGMRS). Zhoushan, China, 2022: 841-845.
[8] 盛松伟, 王坤林, 吝红军, 等. 100 kW鹰式波浪能发电装置“万山号”实海况试验[J]. 太阳能学报, 2019, 40(3): 709-714.
SHENG S W, WANG K L, LIN H J, et al.Open sea tests of 100 kW wave energy convertor sharp eagle Wanshan[J]. Acta energiae solaris sinica, 2019, 40(3): 709-714.
[9] 王坤林, 盛松伟, 叶寅, 等. 基于逆变器直流电压模式波能装置并网接入方法[J]. 太阳能学报, 2023, 44(2): 224-228.
WANG K L, SHENG S W, YE Y, et al.Grid connection for multi HPGS in WEC based on inverter in DC voltage mode[J]. Acta energiae solaris sinica, 2023, 44(2): 224-228.
[10] FERRAZ DE ANDRADE SANTOS J A, DE JONG P, ALVES DA COSTA C, et al. Combining wind and solar energy sources: potential for hybrid power generation in Brazil[J]. Utilities policy, 2020, 67: 101084.
[11] LÓPEZ M, RODRÍGUEZ N, IGLESIAS G. Combined floating offshore wind and solar PV[J]. Journal of marine science and engineering, 2020, 8(8): 576.
[12] DELBEKE O, MOSCHNER J D, DRIESEN J.The complementarity of offshore wind and floating photovoltaics in the Belgian North Sea, an analysis up to 2100[J]. Renewable energy, 2023, 218: 119253.
[13] CONG P W, TENG B, BAI W, et al.Wave power absorption by an oscillating water column (OWC) device of annular cross-section in a combined wind-wave energy system[J]. Applied ocean research, 2021, 107: 102499.
[14] ASTARIZ S, IGLESIAS G.Output power smoothing and reduced downtime period by combined wind and wave energy farms[J]. Energy, 2016, 97: 69-81.
[15] VÁZQUEZ R, CABOS W, NIETO-BORGE J C, et al. Complementarity of offshore energy resources on the Spanish coasts: wind, wave, and photovoltaic energy[J]. Renewable energy, 2024, 224: 120213.
[16] VAN DER ZANT H F, PILLET A C, SCHAAP A, et al. The energy park of the future: modelling the combination of wave-, wind-and solar energy in offshore multi-source parks[J]. Heliyon, 2024, 10(5): e26788.
[17] XU L, ZHANG C, ZHU X Y.Decoupling control of a dual-stator linear and rotary permanent magnet generator for offshore joint wind and wave energy conversion system[J]. IET electric power applications, 2020, 14(4): 561-569.
[18] NAJAFI-SHAD S, BARAKATI S M, YAZDANI A.An effective hybrid wind-photovoltaic system including battery energy storage with reducing control loops and omitting PV converter[J]. Journal of energy storage, 2020, 27: 101088.
[19] RAHMAN M A, ISLAM M R, MUTTAQI K M, et al.Modeling and design of a multiport magnetic bus based novel wind-wave hybrid ocean energy generation technology[C]//2020 IEEE Industry Applications Society Annual Meeting. Detroit, MI, USA, 2020: 1-6.
[20] LU S Y, WANG L, LO T M, et al.Integration of wind power and wave power generation systems using a DC microgrid[J]. IEEE transactions on industry applications, 2015, 51(4): 2753-2761.
[21] NAIDU R S R K, PALAVALASA M, CHATTERJEE S. Integration of hybrid controller for power quality improvement in photo-voltaic/wind/battery sources[J]. Journal of cleaner production, 2022, 330: 129914.
[22] BASARAN K, CETIN N S, BOREKCI S.Energy management for on-grid and off-grid wind/PV and battery hybrid systems[J]. IET renewable power generation, 2017, 11(5): 642-649.
[23] SOLIMAN M S, BELKHIER Y, ULLAH N, et al.Supervisory energy management of a hybrid battery/PV/tidal/wind sources integrated in DC-microgrid energy storage system[J]. Energy reports, 2021, 7: 7728-7740.
[24] BELILA A, BENBOUZID M, BERKOUK E M, et al.On energy management control of a PV-diesel-ESS based microgrid in a stand-alone context[J]. Energies, 2018, 11(8): 2164.
[25] 王坤林, 游亚戈, 王孝洪, 等. 直流纳电网技术在波能装置群中的应用[J]. 太阳能学报, 2017, 38(7): 1877-1884.
WANG K L, YOU Y G, WANG X H, et al.The application of DC nano grid for WECs[J]. Acta energiae solaris sinica, 2017, 38(7): 1877-1884.
[26] 叶寅, 王坤林, 盛松伟, 等. 波浪能装置液压发电系统实验研究[J]. 可再生能源, 2021, 39(12): 1699-1704.
YE Y, WANG K L, SHENG S W, et al.Experimental study on hydraulic power generation system of wave energy converter[J]. Renewable energy resources, 2021, 39(12): 1699-1704.
[27] AL ALAHMADI A A, BELKHIER Y, ULLAH N, et al. Hybrid wind/PV/battery energy management-based intelligent non-integer control for smart DC-microgrid of smart university[J]. IEEE access, 2021, 9: 98948-98961.