Abstract
In a grid, the choice of the point of common coupling (PCC) does not solely rely on the voltage level alone but also conjointly depends on the grid strength for many explicit purposes. Nowadays, the affinity of low SCR grid connections has become a crucial thought once it involves the integration of wind generation plants (WPPs). Since the quality of wind resources is a critical issue, these plants are usually placed in remote areas with a sophisticated potential of wind flow. These remote areas are typically less inhabited, where the grid does not perpetually always have to be sturdy. Moreover, the exceeded power demand loading and higher wind penetration affect the generation, transmission, and distribution utilities by permitting the flow of unbalanced voltages and currents in the power system. Therefore, the quality of transmitted power is becoming a crucial facet of distributed energy generation units. In this paper, a permanent-magnet synchronous generator (PMSG) based wind energy conversion system (WECS) is presented. It discusses a solution, which provides the low voltage ride through (LVRT) provision by the suppression of DC link overvoltage and active power limitation during an asymmetrical grid fault. With improved back-to-back converter control, the machine side converter (MSC) is employed to control the DC-link voltage. Furthermore, the grid side converter (GSC) is used to implement the active/reactive current injection according to the outlined limits. The need for external hardware is eventually avoided, which is typically required to dissipate the additional energy generated during a grid fault. Hence, it is proven to be an affordable solution.
Highlights
The greenhouse emission commencing from the ignition of fossil fuels to harvest electrical energy contributes as the foremost factor in global warming and climate change
Due to wind nonlinearity and consumer demand, there are many coefficients that must be controlled for transmitting power supply to the point of common coupling (PCC)
To regulate power flow in a permanent-magnet synchronous generator (PMSG)-based wind energy conversion system (WECS), there is a need to deploy back-to-back converters on the grid and generator sides, which assist in regulating the voltages during unbalanced conditions
Summary
The greenhouse emission commencing from the ignition of fossil fuels to harvest electrical energy contributes as the foremost factor in global warming and climate change. To regulate power flow in a PMSG-based WECS, there is a need to deploy back-to-back converters on the grid and generator sides, which assist in regulating the voltages during unbalanced conditions (asymmetrical faults).
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