Abstract
The growing relevance of voltage source converters (VSCs), and the deep impact they have on the development and maintenance of the electrical grid, increase the necessity of further research on how to deal with nonideal grid conditions from the VSCs control. This paper is aimed to summarize the basic techniques and schemes that might be required for a grid-connected VSC to work under these conditions: grid synchronization schemes, sequence decomposition, current reference generation, and current controllers. At the same time, some alternative schemes that improves the basic ones are cited. Modelling and the two typical current controllers design and tuning under stationary and synchronous reference frames are also exhibited. Given the importance of the current control stage in the VSC behaviour, five control schemes, designed to track negative sequence currents, are shown and tested in simulation and experiments. According to the experiments, it is shown that the standard proportional-resonant controller achieves the best performance in negative sequence tracking due to the robustness of its non-ideal version, the improved implementation thanks to the delta operator, and the non-dependence on grid-synchronization schemes. Alternatively, one approach based on dual synchronous reference frame is also highlighted for easiness of implementation and good performance.
Highlights
The development of power semiconductors and the flexibility required for power converters are the main reasons for the popularity of voltage source converters (VSCs) [1]
This paper considers two control schemes that uses resonant terms for inner current controller (ICC) under unbalanced grid voltage conditions
Note that the main issue for current controller (CC) regarding unbalanced conditions is the tracking of the negative sequence current references
Summary
The development of power semiconductors and the flexibility required for power converters are the main reasons for the popularity of voltage source converters (VSCs) [1]. By modulating different voltage levels, they can control the power flow demanded by the design application [2], [3]. Either if VSCs are grid-connected or working in islanded operation mode [4], [5], the flow of energy is controlled by means of the phase currents. Determination of the desired phase currents (current reference generation) and the design of the stage that regulates them (current controller) are crucial [6].
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More From: IEEE Open Journal of the Industrial Electronics Society
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