Given the stringent anti-corrosion requirements of coastal wetland areas, Huge Energy selected high-strength, highly corrosion-resistant Zn-Al-Mg steel materials to create an integrated pile and column structure. These structures meet the international C5M anti-corrosion standard, offering excellent waterproofing, moisture resistance, and anti-oxidation performance. The mounting systems are designed with adjustable angles to optimize sunlight exposure for aquaculture needs, while preventing excessive water temperature, creating a favorable environment for fish and shrimp farming.
Huge Energy's R&D team tailored a comprehensive PV mounting system solution based on the project's specific conditions. By adopting a modular design and highly pre-assembled components, the installation difficulty was significantly reduced, while the stability and durability of the system were enhanced. This ensures the project's long-term stable operation.
From project initiation to its official grid connection, Huge Energy's R&D team upheld a professional and efficient working attitude, responding promptly to customer needs. Leveraging extensive project experience, the team provided professional advice and practical solutions.
Once fully operational, the fishery-solar hybrid photovoltaic power station is expected to generate an annual electricity output of 630 million kilowatt-hours, sufficient to meet the electricity needs of 110,000 households. Besides supplying energy to the surrounding areas and alleviating power shortages, the plant is projected to reduce carbon dioxide emissions by approximately 540,000 tons annually, equivalent to planting 85,000 acres of forest each year. This will contribute significantly to improving the local and global ecological environment.
Over the years, Huge Energy has continuously explored and practiced fishery-solar hybrid applications in the PV field, successfully implementing projects across the globe. The efficient resource utilization model of “solar power generation above, aquaculture below” not only optimizes resource allocation but also creates substantial economic returns for operators through dual benefits of farming and power generation.
