Automatic Adjustment Method of Power Flow Calculation Convergence for Large-scale Power Grid Based on Knowledge Experience and Deep Reinforcement Learning
Tianjing Wang, Yong Tang, Yanhao Huang, Xinglei Chen, Songtao Zhang, Hekai Huang
Abstract
In order to solve the problem of manpower and time cost consumption caused by strict non-convergence of power flow in large-scale power grid calculation, an automatic adjustment method of power flow convergence based on knowledge experience and deep reinforcement learning is proposed. Firstly, the knowledge experience of power flow convergence adjustment and the basic concepts and principles of deep reinforcement learning are introduced. Then we design state space, action space and multiple rewards of reinforcement learning, as well as the framework of deep neural network. Next, by adding knowledge and experience into reinforcement learning, the search space is narrowed. And the process of human adjustment is simulated, which is balancing active power and then balancing reactive power. So that the search has directivity, and the power flow adjustment strategy is constructed. When balancing reactive power, Dijkstra algorithm is used to locate capacitors and reactors near the nodes with potential reactive power deficiency by means of optimal path. Finally, the CEPRI(China Electric Power Research Institute) 36-node system and the northeast power grid are used to verify the effectiveness of the method.