Advanced DC Bias Suppression Strategy Based on Finite DC Blocking Devices

The ground return current of a high voltage direct current system will intrude the transformers adjacent to the grounding electrode in the case of monopole operation, leading to the half-cycle saturation of transformers. To mitigate the adverse effect, placing dc blocking devices (BDs) in transformer neutrals is popularly advocated. The conventional switching method of BDs may redirect the dc flow from one transformer with a BD to neighboring transformers without BDs. In this case, the dc currents through the neutrals of those transformers may possibly exceed the threshold undesirably. This problem is due to the lack of guidance for dc current distribution from the global view by means of finite BDs. Thus, this paper presents an optimization approach for the switching of BDs based on the gravitational search algorithm. A mathematical model for investigating the dc global distribution is established with the equivalent resistive network of an ac system, the location distribution of substations and grounding electrodes. Then, an optimal switching scheme to minimize the adverse impact of dc bias is presented, and the principle and the concrete implementation process are detailed. The feasibility and the advantage of the proposed scheme are demonstrated by numerous comparative case studies.