智能海洋牧场
智能海洋牧场
Smart Ocean Pasture
立足国家“十四五/十五五”海洋强国、粤港澳大湾区国际科创中心、香港北部都会区“蓝色经济走廊”三大战略交汇节点,联动香港国际科学院、国内外院士团队及产业资本力量,重点打造“蓝色粮仓”核心项目。该项目聚焦海洋牧场领域,提供产业顶层规划设计与全链条整体解决方案,为海洋经济高质量发展及转型升级提供专业赋能,在切实筑牢国家粮食安全屏障的同时,推动海洋生态可持续发展。
Positioned at the convergence of three major national strategies—China's 14th and 15th Five-Year Plans for building a maritime powerhouse, the Guangdong-Hong Kong-Macao Greater Bay Area's international science and innovation hub, and Hong Kong's Northern Metropolis “Blue Economy Corridor”—this initiative leverages the Hong Kong International Academy of Sciences, teams of domestic and international academicians, and industrial capital to spearhead the “Blue Granary” flagship project. This initiative concentrates on the marine ranch sector, delivering top-level industrial planning and comprehensive end-to-end solutions. It provides specialized empowerment for the high-quality development and transformation of the marine economy, solidifying the national food security barrier while advancing the sustainable development of marine ecosystems.
海上牧场
Marine Pasture
中国海洋大学与智慧养殖联合研发全国领先的智慧养殖模式,包括信息技术、生物技术与海洋技术的“IBM3T”,“PB级大数据+AI技术”融合,海洋牧场特色种质资源“湿”库与高通量遗传资源“干”库协同建设新模式等多项技术。
Ocean University of China and Smart Aquaculture have jointly developed a nationally leading smart aquaculture model, incorporating multiple technologies including the “IBM3T” framework integrating information technology, biotechnology, and marine technology; the fusion of “PB-level big data and AI technology”; and a new collaborative model for constructing marine pasture-specific germplasm ‘wet’ repositories alongside high-throughput genetic resource “dry” repositories.
03
海洋产业——新能源
Marine Industries—New Energy
海洋牧场中,光伏利用海面或船舶顶部空间发电,为智能监测、投饵机等设备提供基础电力,弥补阴天风力不足;风力发电补充光伏,尤其在夜间或恶劣天气,增强能源持续供应能力。制氢将富余电能转化为氢能,既储存能量,又可为燃料电池供能或用于藻类培养,助力碳汇。储能系统平衡风光发电波动,保障增氧机、循环水泵等关键设备稳定运行,实现能源自给与零碳循环。
In marine ranches, photovoltaic systems harness the surface of the sea or vessel rooftops to generate electricity, providing foundational power for smart monitoring equipment and automatic feeders while compensating for insufficient wind energy on cloudy days. Wind power supplements photovoltaic generation, particularly during nighttime or adverse weather, enhancing continuous energy supply capabilities. Hydrogen production converts surplus electricity into hydrogen energy, both storing power and fueling fuel cells or supporting algae cultivation to bolster carbon sinks. Energy storage systems balance fluctuations in wind and solar generation, ensuring stable operation of critical equipment like aerators and recirculating pumps. This achieves energy self-sufficiency and a zero-carbon cycle.
04
海洋环保与安全
Marine Environmental Protection and Safety
05
海上牧场——AI智能管理
Marine Pasture—AI-Powered Management
禽类养殖生物肥料营养物质提取与应用
Extraction and Application of Nutrients from Poultry Manure Biofertilizer
采用全球先进的日本亚临界小分子裂解技术,粪污处理后养分保留完整。从原料中提取了高含量的氮、磷、钾、氨基酸及腐殖酸等多样营养物质。这些物质分子量小、溶解度高,可被海洋生物直接吸收。在处理过程中,高温高压消除病菌、草籽、虫卵,抗生素分解,重金属钝化等优势,为海洋生物提供了安全健康的保障。
Utilizing Japan's globally advanced subcritical small-molecule pyrolysis technology, nutrients remain fully preserved after manure treatment. High concentrations of nitrogen, phosphorus, potassium, amino acids, humic acids, and other nutrients are extracted from the raw materials. These substances feature low molecular weight and high solubility, enabling direct absorption by marine organisms. The processing involves high-temperature and high-pressure conditions that eliminate pathogens, weed seeds, and insect eggs, decompose antibiotics, and immobilize heavy metals. These advantages ensure a safe and healthy environment for marine life.