An Averaged-Value Model of an Asymmetrical Hybrid Multi-Level Rectifier

An Averaged-Value Model of an Asymmetrical Hybrid Multi-Level Rectifier

The development and the validation of an averaged-value mathematical model of an asymmetrical hybrid multi-level rectifier is presented in this work. Such a rectifier is composed of a three-level T-type unidirectional rectifier and of a two-level inverter connected to an open-end winding electrical...

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Bibliographic Details
Published in:Energies (Basel) Vol. 12; no. 4; p. 589
Main Authors: Foti, Salvatore, Scelba, Giacomo, Testa, Antonio, Sciacca, Angelo
Format: Journal Article
Language:English
Published: Basel MDPI AG 13-02-2019
Subjects:
Asymmetry
Complex systems
Control algorithms
Converters
Data buses
Efficiency
Electric potential
Electric power
Electric power loss
electrical drives
Electrical loads
Energy conversion efficiency
energy saving
Estimating techniques
Inverters
multilevel power converters
open-end winding configuration
Optimization
Optimization techniques
permanent magnet synchronous generator
power factor
Pulse duration modulation
Reactance
Reactive power
Supplies
Topology
Voltage
voltage balancing
Winding
Italy
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Summary:The development and the validation of an averaged-value mathematical model of an asymmetrical hybrid multi-level rectifier is presented in this work. Such a rectifier is composed of a three-level T-type unidirectional rectifier and of a two-level inverter connected to an open-end winding electrical machine. The T-type rectifier, which supplies the load, operates at quite a low switching frequency in order to minimize inverter power losses. The two-level inverter is instead driven by a standard sinusoidal pulse width modulation (SPWM) technique to suitably shape the input current. The two-level inverter also plays a key role in actively balancing the voltage across the DC bus capacitors of the T-type rectifier, making unnecessary additional circuits. Such an asymmetrical structure achieves a higher efficiency compared to conventional PWM multilevel rectifiers, even considering extra power losses due to the auxiliary inverter. In spite of its advantageous features, the asymmetrical hybrid multi-level rectifier topology is a quite complex system, which requires suitable mathematical tools for control and optimization purposes. This paper intends to be a step in this direction by deriving an averaged-value mathematical model of the whole system, which is validated through comparison with other modeling approaches and experimental results. The paper is mainly focused on applications in the field of electrical power generation; however, the converter structure can be also exploited in a variety of grid-connected applications by replacing the generator with a transformer featuring an open-end secondary winding arrangement.
ISSN:1996-1073
1996-1073
DOI:10.3390/en12040589