Resumen de Advanced digital resonant control techniques for grid-connected voltage source converters
It is a fact that the presence of power distributed generation sources in the electrical sector is growing exponentially worldwide. This can mainly be explained by the increase of renewable energy production, which involves principally grid-connected single- and three-phase Voltage Source Converters (VSCs).
Regarding the regulations for medium and high power inverters, it is not enough to generate currents with low harmonic content and a unity-power-factor operation: grid-connected VSCs also have to work properly when the electrical grid presents non-ideal characteristics such as frequency variations, sags, swells or a high impedances, among other disturbances.
In line with the above and to improve the grid currents quality, LCL filters are widely used at the input of VSCs for their attenuation capabilities at high frequencies. However, they present a big resonance that may produce robustness issues. In order to study this problem and to stablish a basis for the controllers design, the grid-connected VSC mathematical models have been obtained, analysed and discretised, including passive and active LCL resonance damping techniques.
Adaptive Feedforward Cancellation (AFC) is the control technique addressed in this research work, leading to robust designs which are able to face all the grid disturbances aforementioned. AFC controllers, formed by resonators, have been considered in continuous- and discrete-time forms, and presenting infinite and finite gain, along with an anti-windup system for limitation purposes.
The development of an AFC control design method (directly in discrete time), and the use of automatic code generation tools, have allowed a fast implementation of the resonant controllers into a Digital Signal Processor (DSP). The experimental results obtained from the VSC prototypes (also developed during this thesis), prove the robustness of this control technique.
