| dc.description.abstract | The single phase converters are inherently exposed to the pulsating power. The conventional
approach to supply this pulsating power is to use a huge Electrolytic capacitor. However,
Electrolytic capacitors with high failure rate brings down the overall system lifetime.
The Active Power Decoupling (APD) approaches using a set of switches to control the
voltage across the storage capacitor, reduces the capacitance requirement many fold. Thereafter,
film capacitors, with higher life time, are used to replace the Electrolytic ones. Among many active
solutions proposed in the literature, the AC decoupling topologies, stand out due to their
adaptability to high power converter. However, the available solutions lead to excessive voltage and
current stress on the switches for the applications involving wide range of power factor (PF).
Moreover, when the converter supplies the local non-linear load, the power profile contains
even order harmonics other than the double frequency component. Therefore, the converter should
now be equipped with the control strategy to supply these harmonic powers as well.
The present work aims to address the above mentioned issues.
First, an APD scheme is proposed which is suitable for high power application and works
seamlessly for any PF without overstressing the switches. The proposed topology achieves upto
57% reduction in average curent stress and 41% reduction in DC bus voltage requirement when
compared with the existing solutions available.
Second, a robust control structure ensuring a stable operation of the converter is developed.
With the proposed control, the fundamental control issue of controlling two states with a single
control variable is resolved. Also, the control takes care of practical issues suh as model uncertainty,
arising out of the component tolerance, drifts etc..
Finally, a control strategy is developed to compensate selected harmonics from the DC bus
in presence of non-linear loads. The generation of reference involves simultaneous solution of a set
of non-linear equations. The proposed solution achieves the desired harmonic performance with
reduced RMS current in the APD branch.
In summary, an APD topology with least switch-stress has been proposed, which works
seamlessly for any PF. Also, several robust control mechanisms are devised for the situations like
system with more states (uncontrollable), polluted grid and non-linear loads | en_US |
