Low-carbon operation strategy of virtual power plant considering progressive demand response

• Published in: International journal of electrical power & energy systems Vol. 161; p. 110176
• Main Authors: Li, Dongdong, Wang, Meina, Shen, Yunwei, Li, Fangxing, Lin, Shunfu, Zhou, Bo
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.10.2024; Elsevier
• Subjects: Carbon trading; Consumers’ surplus value; Demand response; Virtual power plant; Carbon trading; Demand response; Consumers’ surplus value; Virtual power plant
• ISSN: 0142-0615
• DOI: 10.1016/j.ijepes.2024.110176

•The load response transfer rate and dynamic incentive electricity price are considered in the model of the virtual power plant.•The consumption surplus value function is added to the carbon cost model with carbon intensity as the index.•The incentive electricity price is linked with the changing carbon price by taking the response transfer quantity as a bridge.•An intra-day rolling optimal regulating model is established on the basis of the equipment output deviation penalty. Adapting virtual power plants (VPPs) to the development of new power systems has gradually become a trend. Meanwhile, the economical and effective use of demand-side resources in VPPs has become a research hotspot in the field of new energy. This paper proposes a low-carbon operation strategy with progressive demand response (DR). A DR model id established by evaluating the scheduling potential of low-carbon and flexible loads and the DR transfer of different users motivated by incentive mechanisms. Because the changing carbon price in carbon trading also affects the response transfer amount, it is beneficial to reduce the operating cost of the energy system by using consumers’ surplus value according to consumer psychology to guide energy users to participate in DR. Finally, wind, light, user load data and VPP internal unit output are optimized in rolling mode over multiple time scales, and the optimal adjustment results of the previous day are taken as the basis. At the same time, the output deviation penalty function is added to further reduce the system cost. The nonlinear model of DR cost is transformed into a mixed integer linear model, which is modeled on MATLAB software and solved by a CPLEX optimization solver. The case analysis shows that the progressive DR strategy may increase the total operating cost of the system, but reduce the cost of the carbon emission. The proposed model and method can not only improve the feasibility and effectiveness of market supervision strategy, but also provides a useful reference for operators and demand-side users in energy systems to choose strategies.