Bi-level Bidding Model for Cascaded Hydropower Under Uncertain Carbon-Electricity Coupled Market

With the deepening of the reform of electricity markets and carbon markets, the bidding problem for the cascaded hydropower under carbon trading-electricity trading (referred as to carbon-electricity) coupled market needs to be solved urgently. How to decouple trading rules and deal with market uncertainty while considering its own non-convex generation characteristics is the key to solve the problem. Therefore, a bi-level optimization model of cascaded hydropower station bidding under the carbon-electricity coupled market is constructed, which takes into account the uncertainties of supply and demand in the Chinese certified Emission Reduction (CCER) market. The upper model takes the market clearing price as the parameter to decide the generation plan and bidding curve of cascaded hydropower in the electricity market and CCER market. The lower model takes the market declaration information as the parameter to calculate the CCER market clearing results in different time periods and different scenarios. The proposed model takes into account the non-convex operation characteristics of cascaded hydropower and the rules of the carbon-electricity coupling market, and uses a variety of possible supply and demand relations to describe the uncertainty of the CCER market. The bi-level model is transformed into a mixed-integer linear programming model by strong duality theory, big-M method and piecewise linear method. Based on the background of two cascaded hydropower stations in the main stream of the Lancang River in China, the analysis results show that considering the uncertainty of the CCER market can effectively improve the stability of the bidding plan, and the coupled market mechanism can guide the power generation enterprises to adjust the power generation plan according to the two market demands. The power generation enterprises can improve their own income and promote the rational allocation of system resources. © 2023 Automation of Electric Power Systems Press. All rights reserved.