Abstract
This paper proposes an open-circuit fault-tolerant design for the cascaded H-Bridge rectifier incorporating reactive power compensation. If one or two switching devices of the H-bridge modules are fault, the drive signals of the faulty H-bridge modules will be artificially redistributed into the bridgeless mode (including the boost bridgeless mode, the symmetric boost bridgeless mode, the totem-pole bridgeless mode and the symmetry totem-pole bridgeless mode) and cooperate with the normally operated H-bridge modules. In this case, the faulty cascaded H-bridge rectifier is not only able to achieve active power transmission, but also can still provide part of reactive power compensation when injecting reactive power from the power grid. Nonetheless, the reactive power that it can supply will be limited, due to the unidirectional characteristics of the bridgeless mode for the faulty modules. Therefore, a method for calculating its adjustable power factor angle range is also presented, which provides the basis for the faulty modules switching to the bridgeless mode. Then, a control strategy of the cascaded H-bridge rectifier incorporating reactive power compensation under the faulty condition and normal operation is presented. Finally, an experimental platform with a single-phase cascaded H-bridge rectifier containing three cells is given to verify the proposed theories.
Highlights
In recent years, due to the access of nonlinear loads in the power system, the power quality control technology with power electronic converters as the core has attracted increasing attention
The advantage of the multifunctional power rectifier is that reactive power can be processed locally and distributed, thereby the loss of reactive power on power transmission line is reduced
Inspired by [22], this paper presents a new fault-tolerant operating mode for multifunctional cascaded H-bridge rectifiers
Summary
Due to the access of nonlinear loads in the power system, the power quality control technology with power electronic converters as the core has attracted increasing attention. Increasing scholars and research teams believe that integrating reactive power compensation functionality with bidirectional rectifiers that exist in practice to construct multifunctional power electronic rectifiers in the distributed generation system is a more reasonable and cost-effective solution [1,2,3]. These multifunctional power rectifiers can realize their functions, and complete the reactive power compensation for the grid. [4] has pointed out that the multifunctional power rectifiers are essential to employed in the smart grid and modular multicell converter to feature a two-way flow of electricity between production and consumption. Realizing reactive power compensation requires almost no additional hardware costs [4,5,6].
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