Double-layer optimal allocation of heat storage capacity in combined solar thermal-wind power generation system
Wind power generation and solar thermal power generation have complementary advantages in terms of time characteristics,and the heat storage system equipped with solar thermal power station can effectively alleviate the peak regulation pressure and improve the wind power absorption capacity.On this basis,a solar thermal-wind combined power generation system is proposed.The Latin hypercube sampling method is used to effectively reduce the uncertainty of wind power output and solar irradiation intensity.Then,a two-stage double-layer optimal allocation method is proposed to rationally allocate the heat storage capacity.The upper layer model aims to minimize the investment cost of comprehensive operation of the system and the lowest curtailment of the system.The optimal heat storage capacity is determined by a fuzzy multi-attribute decision scheme.In the lower layer model,the operation is optimized with the goal of maximizing the net benefit of the cogeneration system in the scenario.The results show that the optimal heat storage capacity of the heat storage system of the solar thermal power station is 906 MW·h,and the comprehensive operating cost for the optimal heat storage capacity configuration is 2 430 000 yuan.Through the comparison between the results of different scenarios,the curtailment of the system with this configuration method reduces by 69.615 MW,and the net revenue of the system increases by 7.7%.
solar thermal power stationuncertaintycombined power generation systemoptimal heat storage capacitytwo-layer optimization
国家科技期刊平台
NSTL
万方数据
