Abstract
This paper presents an automation strategy for multi-terminal HVDC (MT-HVDC) systems combining a dc optimal power flow (dc OPF) routine and a unified reference controller (URC). In the presented automatic framework, the dc OPF algorithm is implemented at the power dispatch center (PDC) of the MT-HVDC system to find optimal reference operation points of the power converters to minimize the losses during the operation of the MT-HVDC grid and solves the contradiction between minimizing losses and preventing commutation failure. At the local control systems, the operating points of the voltage-source converter (VSC) stations are tuned based on the calculations executed in the PDC, which enables fast response to power fluctuation and ensures a stable dc voltage. However, if the communication between the two control layers is lost, the MT-HVDC grid remains stable based on the pre-defined V-P droop characteristics for the power converter stations till the connection establishes again, and a set of new operating points is generated and sent. The static and dynamic simulations conducted on the CIGRE B4 HVDC test grid establish the efficient and effective grid control performance with the proposed automation strategy. The analysis shows that the proposed control scheme achieves the desired minimum losses while, at the same time, satisfying the system constraints.
Highlights
Broad academic and industrial studies within the field of Multi-Terminal HVDC (MT-HVDC) systems/grids have been conducted worldwide [1]–[8]
In the presented automatic framework, DC Optimal Power Flow (DC OPF) algorithm is implemented at the Power Dispatch Centre (PDC) of the Multi-Terminal VSCHVDC grid to find optimum reference operation points of the voltage-source converter (VSC) taking in account the operational limitations and MT-HVDC grid loss minimization
Simulation results are presented to confirm the effectiveness of the projected DC OPF control and dynamic interaction between AC and DC grids during base case, deficiency in power generation in weak AC network and ultimate breakage of transmission line
Summary
Broad academic and industrial studies within the field of Multi-Terminal HVDC (MT-HVDC) systems/grids have been conducted worldwide [1]–[8]. This paper presents an automation strategy for MT-HVDC grids combining a DC Optimal Power Flow (DC OPF) routine and a Unified Reference Controller. In the presented automatic framework, DC OPF algorithm is implemented at the Power Dispatch Centre (PDC) of the Multi-Terminal VSCHVDC grid to find optimum reference operation points of the VSCs taking in account the operational limitations and MT-HVDC grid loss minimization. A complete control-framework is presented in order to provide an efficient control and perform power-sharing in the MT-HVDC systems based on the DC OPF This enables running at the supervisory control center and programming a Unified Reference Controller at the primary control of the VSC stations stepping towards the automation of MT-HVDC grids. The result of the DC OPF will be achieved by equating the Lagrangian derivative with respect to the unknown variables to zero, and to solve the problem iteratively:
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