Abstract
Affected by different steady-state reactive power output ratios among generators, capacitors and other reactive devices in the end-to-end power grid, voltage collapse may occur due to the failure of the receiving-end AC system, and the problem of voltage stabilization in multi-DC feed systems is particularly common. For suppressing voltage collapse, sufficient dynamic reactive power support is an effective measure, and there are some differences in the dynamic support effect of different reactive power sources. The dynamic reactive power response of the generator and its reactive power margin are two important factors affecting the coordination and optimization of the reactive power of the generator. The comprehensive evaluation index is adopted to optimize the sequencing of the reactive power output of the generator near the DC drop point. A coordinated control method of dynamic and static reactive power for DC near-point systems at different voltage levels is proposed. By controlling the steady-state reactive power output ratio between multiple reactive devices, the node voltage is maintained near the target value, and reactive power control schemes at different voltage levels can be given to meet load changes. Finally, taking the actual situation of Central China Power Grid as an example, the results of different reactive voltage control strategies are compared and analyzed, which proves that the coordinated control strategy of multiple reactive power devices can significantly improve the stability of the receiving grid voltage.
Highlights
The problem of voltage stability at the receiving end is increasingly prominent, which has attracted widespread attention
The UHVDC transmission receiving end system needs a large amount of reactive power support, and the required compensation amount reaches 40% to 60% of the active power it transmits
The development trend of UHV regional interconnection has brought severe tests to the system's reactive voltage management capability, especially the dynamic reactive power compensation capability[3]; In literature[4], the influence of DC feed on the stability of the receiving end grid voltage was analyzed, and the reactive power optimization analysis of the AC / DC interconnection system of China Southern Power Grid was performed by the plane constraint method
Summary
The problem of voltage stability at the receiving end is increasingly prominent, which has attracted widespread attention. The development trend of UHV regional interconnection has brought severe tests to the system's reactive voltage management capability, especially the dynamic reactive power compensation capability[3]; In literature[4], the influence of DC feed on the stability of the receiving end grid voltage was analyzed, and the reactive power optimization analysis of the AC / DC interconnection system of China Southern Power Grid was performed by the plane constraint method This method, takes the squared sum of node voltage deviations as the minimum and does not fully consider the effects of each reactive device on the transient stability; In [5], through the simulation system, the correlation matrix of the transient voltage response of other nodes after the N-1 failure of the target node is constructed, and the correlation matrix is calculated and analyzed using the K-core decomposition method to select nodes with a high degree of correlation with the target node as a transient voltage strong support node; In Reference [6], the proposed dynamic reactive power configuration scheme can reduce the number of DC commutation failures, no clear index is given on how to distribute the reactive power output; Taking measures from the aspects of control protection, adding additional equipment, and inverter topology reform can effectively improve voltage stability[7]. By calculating the dynamic reactive power response and dynamic reactive power support margin of the generator, a comprehensive evaluation index of the voltage stability of each generator near the DC drop point was found to determine the coordinated control sequence of each generator, and through the proposed coordinated optimization control method, a quantitative index is given for the reactive power ratio at each voltage level
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