海上风电全生命期资产闭环智慧管理方法及应用OA
Closed-loop smart management method and application of offshore wind power assets through the full life cycle
随着国家逐步取消海上风电上网补贴政策,海上风电项目进入降本增效的关键时期,迫切需要建立新的全生命期建设和运行管理模式,以促进海上风电产业高质量发展.该文基于中国海上风电项目管理现状,首先提出了全面感知、真实分析、实时控制和持续优化的海上风电项目全生命期闭环管理方法,并构建了资产管理的成本、绩效和风险评估模型;其次,总结海上风电项目全生命期管理的关键技术,构建了全生命期智慧管理系统架构,并研发了集成项目开发、智慧基建、智慧运维和延寿退役的全生命期智慧管理功能模块;最后,在江苏某海上风电场进行了实例验证.该文研究结果可为同类工程搭建全生命期智慧管理系统架构,实现资产闭环智慧管理提供参考.
[Objective]As China gradually phases out its subsidy policy for offshore wind power(OWP),the industry has entered a decisive cost reduction and efficiency enhancement stage.Unlike onshore wind projects,OWP projects still face substantially higher construction and operating costs,which makes competitiveness under grid-parity conditions highly challenging.However,the theoretical framework for managing the smart lifecycle of OWP projects remains underdeveloped,with incomplete asset management and evaluation methods.The smart lifecycle management of OWP projects is in its nascent stage,with fragmented data systems and poor integration across planning,construction,and operations.Consequently,there is an urgent need for an innovative,lifecycle-oriented management approach to support the OWP industry's high-quality and sustainable development.[Methods]This study proposes a closed-loop smart management mechanism for OWP projects,focusing on four key dimensions:perception,analysis,real-time control,and optimization.This study summarizes the digital transformation and smart management pathways of OWP assets throughout their lifecycle,from feasibility to construction,operation,and final decommissioning.This study classifies management elements into cost,efficiency,and risk,creating a closed-loop evaluation model for OWP assets.This model enables a dynamic representation of each asset's status in terms of cost,efficiency,and risk levels at any moment.Furthermore,this study identifies and analyzes key smart management technologies relevant to various phases of the lifecycle.Accordingly,a smart lifecycle management platform has been designed with a five-layer architecture:data acquisition,data management,modular functional applications,decision support,and interactive visualization.A prototype system was developed to address project development and design,smart construction,and smart operation and maintenance.The system was applied in a large offshore wind farm in Jiangsu Province,China,and the asset conditions were compared before and after its implementation.[Results]A comparative analysis based on actual operational data showed significant improvements:(1)Effective cost control was achieved during the construction period,along with rational planning for operation and maintenance,reduced downtime,and improved generation efficiency.Thus,the lifecycle levelized cost of energy decreased from 0.92 yuan/(kW·h)to 0.76 yuan/(kW·h),which was approximately 17.4%.(2)When evaluated against three key efficiency indicators-compliance rate of power generation,effective operation time assurance rate,and average failure rate-the poorly performing turbines(#3,#10,and#16)showed significant improvements after rectification,with lower osculating values.(3)Comprehensive risk assessment identified anomalies in the transmission and blade systems as primary concerns,which allowed for targeted maintenance interventions,improved equipment availability,and reduced unplanned maintenance requirements.[Conclusions]The proposed closed-loop smart lifecycle management system offers a new technical solution for reducing costs and improving efficiency in OWP projects.Practical application shows that the system can enhance project planning and design,reduce development and operational costs,improve asset equipment reliability,extend the power generation lifecycle,and ensure ongoing value creation throughout the lifecycle.The study findings offer valuable guidance for smart management in similar offshore renewable energy projects,thereby contributing to the sustainable development of the wind power industry through digital transformation.
樊启祥;林鹏;王鑫;姚中原;刘鑫;余卓憬
中国华能集团有限公司,北京 100031清华大学水利水电工程系,北京 100084||清华四川能源互联网研究院,成都 610213清华大学水利水电工程系,北京 100084||中国长江三峡集团有限公司科学技术研究院,北京 100038华能国际电力股份有限公司江苏清洁能源分公司,南京 210008中国华能集团清洁能源技术研究院有限公司,北京 102209中国华能集团有限公司,北京 100031
管理科学
海上风电全生命期智能建造闭环管理资产管理
offshore wind powerfull life cycleintelligent constructionclosed-loop controlasset management
《清华大学学报(自然科学版)》 2026 (4)
796-809,14
中国华能集团有限公司科技项目(HNKJ19-H16)中国电建集团核心科技项目(DJ-HXGG-2022-03)
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