长江科学院院报2025,Vol.42Issue(10):38-45,8.DOI:10.11988/ckyyb.20240909
考虑抽蓄的风光水火多能互补双层优化调度
Bi-level Optimal Scheduling of Wind-Solar-Hydro-Thermal Multi-energy Complementary System Considering Pumped Storage
摘要
Abstract
[Objective]In response to the operational challenge caused by high penetration of wind and solar power in modern power systems,this study aims to propose a bi-level optimized scheduling model for a multi-energy com-plementary power generation system incorporating pumped storage.The model seeks to enhance renewable energy u-tilization,optimize system economic performance,and improve system stability.The novelty lies in the integration of a bi-level optimization framework with a deep peak shaving strategy,while introducing CO2 emission intensity and thermal power output coefficient as evaluation indicators for multi-objective coordination of economy,environmental performance,and stability.[Methods]The upper-level model optimized the joint dispatch of wind,solar,hydro,and pumped storage with objectives of maximizing wind and solar output,minimizing net load fluctuation,and mini-mizing curtailed electricity.The lower-level model optimized the economic performance of the system,aiming at minimizing thermal power operational costs,pumped storage costs,and curtailed electricity penalties.Constraints included wind and solar output limits,hydro and pumped storage capacity limits,thermal unit ramping capabilities,and power balance requirements.The CPLEX solver combined with the YALMIP toolbox was employed to solve the high-dimensional nonlinear mixed-integer programming problem.CO2 emission intensity and thermal power output fluctuation coefficient were adopted as additional evaluation metrics to quantify environmental performance and sys-tem stability.[Results]Simulation results indicated that integrating pumped storage reduced total cost by 46 000 CNY(1.02%)and CO2 emission intensity by 6.4%in the summer scenario,while the thermal power output fluctu-ation coefficient decreased from 33.34%to 7.88%.In winter,thermal output stability improved to 7.67%.Increas-ing wind-solar penetration from 31.25%to 47.62%lowered system costs by 39.5%and reduced CO2 emission inten-sity by 58.3%.Enhancing deep peak shaving from 50%to 70%reduced total cost by 19.2%and decreased thermal power output fluctuation coefficient by 44.2%.[Conclusions]The introduction of pumped storage power station significantly enhances system flexibility,increasing renewable energy utilization by over 12%and reducing thermal unit peak regulation pressure by 50%.The bi-level optimization model ensures low-cost operation while reducing CO2 emission intensity by more than 0.1 kg/(kW·h)and maintaining thermal power output fluctuation coefficient below 8%.A combination of high wind-solar penetration(>40%)and deep peak shaving(70%)achieves optimal comprehensive benefits,providing theoretical support for scheduling of high renewable energy penetration power systems.This study provides an innovative methodology for the design and optimization of wind-solar-hydro-thermal-pumped storage multi-energy systems,and the findings can be generalized to other clean energy bases.关键词
优化调度/多能互补/分层优化/抽水蓄能/多目标优化/深度调峰Key words
optimal scheduling/multi-energy complementarity/hierarchical optimization/pumped storage/multi-objective/deep peak shaving分类
信息技术与安全科学引用本文复制引用
严新军,王红徐..考虑抽蓄的风光水火多能互补双层优化调度[J].长江科学院院报,2025,42(10):38-45,8.基金项目
新疆维吾尔自治区重点研发任务专项(2022B03024-3) (2022B03024-3)
