High-Performance 3-Phase 5-Level E-Type Multilevel–Multicell Converters for Microgrids

Benedetto, Marco Di; Lidozzi, Alessandro; Solero, Luca; Crescimbini, Fabio; Grbović, Petar J.

doi:10.3390/en14040843

Cited by 11 publications

(6 citation statements)

References 36 publications

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“…In addition to Equation (7), the electrical power at the inverter input terminals is considered in order to determine the current in the DC link of the overall traction drive. To this goal, the overall power loss in the power electronic conversion system is determined by using the approach earlier proposed in [37] and already used in [38]. Hence, both the switching power loss and the conduction power loss in the inverter switches and diodes are evaluated by considering only the fundamental harmonic of the inverter output phase current that is being represented by the time function:…”

Section: Modelling the Braking Transient For Arriving Trainsmentioning

confidence: 99%

Recovery of Trains’ Braking Energy in a Railway Micro-Grid Devoted to Train plus Electric Vehicle Integrated Mobility

et al. 2022

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This paper deals with the energy recovery resulting from the braking transient of trains arriving in a railway station, to feed a railway micro-grid that would be purposely connected to the railway traction circuit to feed the electrical infrastructure required for charging a fleet of electrical vehicles that are parked nearby the station and offered for providing train plus electric vehicle integrated mobility. Based on results of an experimental campaign intended to recording the mechanical quantities related to the braking transient of regional trains arriving in a medium-size station of the Italian railways network, this paper describes a suitable quasi-stationary model that allows the evaluation of the amount of energy that is recoverable over each single day of operation, as well as the micro-grid dynamic electric behaviour due to the sudden energy recovery transient in the railway catenary. The proposed railway micro-grid is discussed, particularly concerning the configuration of the dual-active-bridge converter for regulating the power flow from the railway catenary to the micro-grid during an energy recovery transient, as well as by considering the DC-DC converter that is used in the micro-grid, together with battery storage to provide voltage stability according to the micro-grid operating condition.

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Section: Modelling the Braking Transient For Arriving Trainsmentioning

confidence: 99%

Recovery of Trains’ Braking Energy in a Railway Micro-Grid Devoted to Train plus Electric Vehicle Integrated Mobility

et al. 2022

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“…In a two-level converter, the maximum blocking voltage is equal to the DC-bus voltage V BUS . The overvoltage ∆V, instead, depends on many factors, such as the leak inductance L S , the current transient di/dt, the coefficient k R to consider possible resonance in the DC-bus circuit, and the voltage drop across the free-wheeling diode V FR [22,23]. Therefore, the voltage rating can be estimated as in (1).…”

Section: Voltage Rating and Current Ratingmentioning

confidence: 99%

“…Considering a sinusoidal pulse width modulation (SPWM), the duty cycle waveform can be found as in (5), where the subscript "p" stands for the top switches, whereas the subscript "n" represents the bottom switches, and M is the modulation depth [23].…”

Section: Voltage Rating and Current Ratingmentioning

confidence: 99%

Analysis and Design of a High-Efficiency SiC MOSFET 6-Phase Boost Rectifier

et al. 2022

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In this paper, the analysis and the design of a high-efficiency power electronic conversion system for offshore wind applications are presented. This system is composed of a 6-phase AC–DC converter based on the SiC power semiconductors, to be used to control the achievable power from the wind turbine electrical generator. Thanks to the phase redundancy, the proposed boost rectifier is suitable for applications where reliability and fault tolerance capability are the main targets. To select the appropriate power semiconductor devices, voltage and current ratings have to be determined. After that, the power loss equations are derived in order to evaluate the conversion efficiency. To design the appropriate DC-bus capacitor configuration, an analytical investigation is carried out by estimating the DC-bus RMS current and the voltage ripple. Finally, the thermal sizing of the system is calculated to identify a suitable heatsink. To validate the proposed analysis, the analytical results are compared to simulation ones using the Plexim/PLECS tool in the MATLAB/Simulink environment. For further validation, a prototype of the converter is built and the experimental results are carried out. The results demonstrate that the peak efficiency of the 6-phase boost rectifier can reach 98% at 100 kHz switching frequency.

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“…In this context, Multilevel Power Inverters (MPIs) are a promising solution since they present, with respect to the traditional three-phase two-level inverters, reduced harmonic content in the output voltages, lower voltage stress in the power components, and reduced Electromagnetic Interference (EMI) [6,7]. Therefore, multilevel power inverters, because of these features, represent a valid solution in many fields of application where high performance is required [8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Switching Frequency Effects on the Efficiency and Harmonic Distortion in a Three-Phase Five-Level CHBMI Prototype with Multicarrier PWM Schemes: Experimental Analysis

et al. 2022

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The current climatic scenario requires the use of innovative solutions to increase the production of electricity from renewable energy sources. Multilevel Power Inverters are a promising solution to improve the penetration of renewable energy sources into the electrical grid. Moreover, the performance of MPIs is a function of the modulation strategy employed and of its features (modulation index and switching frequency). This paper presents an extended and experimental analysis of three-phase five-level Cascaded H-Bridges Multilevel Inverter performance in terms of efficiency and harmonic content considering several MC PWM modulation strategies. In detail, the CHBMI performance is analyzed by varying the modulation index and the switching frequency. For control purposes, the NI System On Module sbRIO-9651 control board, a dedicated FPGA-based control board for power electronics and drive applications programmable in the LabVIEW environment, is used. The paper describes the modulation strategies implementation, the test bench set-up, and the experimental investigations carried out. The results obtained in terms of Total Harmonic Distorsion (THD) and efficiency are analyzed, compared, and discussed.

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High-Performance 3-Phase 5-Level E-Type Multilevel–Multicell Converters for Microgrids

Cited by 11 publications

References 36 publications

Recovery of Trains’ Braking Energy in a Railway Micro-Grid Devoted to Train plus Electric Vehicle Integrated Mobility

Recovery of Trains’ Braking Energy in a Railway Micro-Grid Devoted to Train plus Electric Vehicle Integrated Mobility

Analysis and Design of a High-Efficiency SiC MOSFET 6-Phase Boost Rectifier

Switching Frequency Effects on the Efficiency and Harmonic Distortion in a Three-Phase Five-Level CHBMI Prototype with Multicarrier PWM Schemes: Experimental Analysis

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