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Research on the Asymmetrical Multilevel Hybrid Energy Storage System Based on Hybrid Carrier Modulation

Wei Jiang, Kai Ren, Shuai Xue, Chen Yang, Zhiqi Xu

2020IEEE Transactions on Industrial Electronics21 citationsDOI

Abstract

In this article, when the cascaded H-bridge topology is used in the asymmetrical multilevel hybrid energy storage system (AM-HESS), the asymmetry of the energy storage components' types and voltages makes it difficult for traditional modulation methods to realize an independent power control of each energy storage unit. Thus, these methods cannot be directly applied to the realization of the complex working modes of AM-HESS. To this end, an AM-HESS hybrid level shifted pulsewidth modulation (PWM) (HLS-PWM) technique is proposed. According to the directions of supercapacities' (SCs') output power and the total output power of the energy storage system, the HLS-PWM is divided into the two fundamental modes-the same (MP) and opposite (MN) modes. Subsequently, the SC charge and discharge control under both the unit power factor and the nonunit power factor is analyzed for the two modes. Furthermore, five operation modes and the power control method of AM-HESS are implemented through the charge and discharge control of the SC. Finally, simulation and experimental results verify that the proposed HLS-PWM can realize an efficient power control of the AM-HESS.

Topics & Concepts

Pulse-width modulationPower (physics)Energy storageRealization (probability)Modulation (music)Electronic engineeringH bridgeTopology (electrical circuits)VoltageControl theory (sociology)Computer sciencePower factorPower controlEnergy (signal processing)EngineeringElectrical engineeringPhysicsControl (management)MathematicsQuantum mechanicsArtificial intelligenceAcousticsStatisticsMultilevel Inverters and ConvertersMicrogrid Control and OptimizationAdvanced DC-DC Converters
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