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Journal of Chinese Society for Corrosion and protection  2026, Vol. 46 Issue (2): 315-326    DOI: 10.11902/1005.4537.2025.165
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Review on Corrosion and Protection of Key Structures for Offshore Photovoltaic Industry
CHEN Xiaohua1, MAN Cheng1, ZHEN Yongtai2, FU Long3, CUI Hongzhi1()
1.College of Materials Science and Engineering, Ocean University of China, Qingdao 266100, China
2.Guangdong Quanwei New Energy Technology Co. Ltd. , Dongguan 523000, China
3.School of Energy and Materials Engineering, Shandong Institute of Technology, Jining 272067, China
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CHEN Xiaohua, MAN Cheng, ZHEN Yongtai, FU Long, CUI Hongzhi. Review on Corrosion and Protection of Key Structures for Offshore Photovoltaic Industry. Journal of Chinese Society for Corrosion and protection, 2026, 46(2): 315-326.

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Abstract  

It can be foreseen that the construction of offshore photovoltaic (PV) power generation will facilitate the transfer of green power generation systems from land to sea, expand the space for the development of renewable energy, create new opportunities for the development of the photovoltaic industry, hence it is an important development direction for the photovoltaic industry. However, the marine environment is characterized by high humidity, and high salinity, which poses new challenges for the development of the offshore PV industry. In particular, the corrosion of key structural components such as PV module racks and pile foundations has become a key factor limiting its large-scale development and application. Considering this, herein, the corrosion issues of key structures in offshore PV systems were focused on. Such as the corrosion characteristics of the engineering structures of PV power generation systems may encounter in the marine environment are analyzed in terms of the structure types, structural features, material varieties, and service conditions etc. In addition, systematic countermeasures for corrosion protection of structural components were proposed, therewith providing a reference for the construction, operation and maintenance of offshore PV systems.
Key words:  off photovoltaic      structure      corrosion      protection     
Received:  03 June 2025      32134.14.1005.4537.2025.165
ZTFLH:  TG174.4  
Fund: National Natural Science Foundation of China(U2106216);Key R&D Program of Shandong Province(2023ZLGX05);Key Program of Natural Science Foundation of Shandong Province(ZR2022ZD12);Taishan Scholarship of Climbing Plan(tspd20230603);Project of Joint R & D Center for Marine Photovoltaic Technology between Ocean University of China and Quwei for Future New Energy Technology Development (Anhui) Co. Ltd
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CHEN Xiaohua
MAN Cheng
ZHEN Yongtai
FU Long
CUI Hongzhi

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https://www.jcscp.org/EN/10.11902/1005.4537.2025.165     OR     https://www.jcscp.org/EN/Y2026/V46/I2/315

Fig.1  Types of offshore photovoltaic structures: (a) pile foundation type[11], (b) floating type[12]
Fig.2  Area map of marine corrosive environment[14,15]
Fig.3  Corrosion failure mechanism of concrete structures in marine environments[31]
Fig.4  Corrosion macroscopic photos of galvanized steel at 0 h (a), 1000 h (b), 1500 h (c), 3000 h (d), 4000 h (e) and 5000 h (f) under neutral salt spray conditions of 0 μm (a1-f1), 65 μm (a2-f2), 85 μm (a3-f3) and 100 μm (a4-f4) coating[43]
Fig.5  Suggestions for overall corrosion protection of offshore PV[59]
SolutionEpoxy heavy-duty anti-corrosion coatingEpoxy glass flake coating
PerformanceGoodGood
Application methodKnife coatingSpray coating
Solid content100%84%
Abrasive resistance< 50 mg-
Loss coefficient1.3 low2.0 high
CostLowMedium
MaintainEasyMedium
Table 1  Comparatively analysis of different anticorrosion solutions[61]
SolutionGalvanizationGalvanization + CoatingCoating
PerformanceMediumExcellentGood
Reference standardNoYesYes
Application speedFastMediumMedium
Repair of welding pointsNoEasyEasy
CostLowMediumMedium
Table 2  Comparatively analysis of different anticorrosion solutions to steel truss at offshore area[61]
Surface treatment methodThickness / μmHV hardnessSalt spray test / hAdhesive strengthCombination modeCost (¥/kg)
Fluorocarbon coating25-602-530004Mechanical bonding3
Zinc impregnation5-85350-55096-30001Diffusion metallurgy4
Dacromet5-152-610004Oxidation3
Phosphating5-20500-5501003Chemical oxidation2
Table 3  Comparison table of four anti-corrosion technical indicators[71]
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