Optimal Capacity Configuration for Wind Power and Photovoltaic-Oxygen-enriched Coal-fired Power Generation System Considering Carbon Capture Technology

To reduce the carbon emissions of thermal power plants and improve the economic benefits of wind power and photovoltaic-oxygen-enriched coal-fired power generation systems, an optimal capacity configuration method for wind power and photovoltaic-oxygen-enriched coal-fired power generation systems considering the dual-source and dual-load scenario reduction and gradual ladder-type carbon price is proposed. Firstly, the wind power and photovoltaic-oxygen-enriched coal-fired power generation system is constructed by taking the oxygen-enriched combustion capture technology as the core, and the refined oxygen-enriched combustion model is constructed. Meanwhile, to cope with the complex and diverse source-load scenarios, a dual-source and dual-load scenario reduction method is proposed. On this basis, a ladder-type carbon trading mechanism is proposed including the gradual ladder-type carbon price in multi-scenarios, and an optimal capacity configuration model for the wind power and photovoltaic-oxygen-enriched coal-fired power generation system with the goal of minimizing the total annual cost of the system is established. Finally, the simulation is conducted based on the source-load data of a certain area, and a comparison scheme is set to verify the effectiveness of the proposed method. The results show that the proposed dual-source and dual-load scenario reduction method has a better clustering effect than the traditional methods, and the proposal of the refined oxygen-enriched combustion model and the development of gradual ladder-type carbon price can further enhance the system economics and low-carbon benefits. © 2023 Automation of Electric Power Systems Press. All rights reserved.