Topologies, analysis, controls and generalization in H-bridge multilevel power conversion

Use of multilevel inverters is becoming popular in the recent years for high power applications. Various topologies and modulation strategies have been investigated for utility and drive applications in the recent literature. Trends in power semiconductor technology indicate a trade-off in the selection of power devices in terms of the switching frequency and voltage sustaining capability. New power converter topologies permit modular realization of multilevel inverters using a hybrid approach involving Integrated Gate Commutated Thyristors (IGCT) and Insulated Gate Bipolar Transistors (IGBT) operating in synergism. This work is devoted to the investigation of a hybrid multilevel power conversion system typically suitable for high performance, high power applications. This system designed for 4.16 kV, ≥100 HP load comprises of a hybrid seven-level inverter, a diode bridge rectifier and a IGBT rectifier per phase. The IGBT rectifier is used on the utility side as a real power flow regulator to the low voltage converter and as a harmonic compensator for the high voltage converter. The hybrid seven-level inverter on the load side consists of a high voltage, slow switching IGCT inverter and a low voltage, fast switching IGBT inverter. By employing different devices under different operating conditions, it is shown that one can optimize the power conversion capability of entire system. A detailed analysis of a novel hybrid modulation technique for the inverter, which incorporates stepped synthesis in conjunction with variable pulse width of the consecutive steps, is included. In addition, performance of a multilevel current regulated delta modulator as applied to the single phase full bridge IGBT rectifier is discussed. Operating principles, spectral structure and other practical issues such as power flow interaction between component inverters is described in detail in this thesis. A generalized topological structure along with an analysis of a generalized hybrid modulation strategy is also included. Detailed computer simulations accompanied with experimental verification are presented in this work.