Optimal Dispatching of Park-level Integrated Energy System Considering Augmented Carbon Emission Flow and Carbon Trading Bargain Model

This paper establishes an optimal dispatching model of the park-level integrated energy system based on a dual game of supply and demand sides. Firstly, the concept of the carbon-to-charge ratio of energy storage and the principle of carbon emission conservation in a dispatching period are introduced, and an augmented carbon emission flow model is established. Based on the model, the carbon-oriented pricing mechanism is implemented in the park, and the upper and lower level game model between the park and its users is established. Besides, Nash bargain model is adopted to simulate the gaming behavior of various entities participating in carbon trading market among multiple parks, so as to form a dual game mechanism. A data-driven two-stage robust optimization combined with adaptive alternating direction method of multipliers is used to solve the problem. The optimal trading volume of carbon quota and trading price can be obtained. Finally, the case simulation results show the correctness of the proposed augmented carbon emission flow model and the role of pricing mechanism based on carbon emission flow in reducing carbon emission. At the same time, the effect of carbon trading market and carbon capture on different resource endowment entities are analyzed as well as the effectiveness of the adopted algorithm in this paper. © 2023 Automation of Electric Power Systems Press. All rights reserved.