Modified SVPWM-Controlled Three-Port Three-Phase AC–DC Converters With Reduced Power Conversion Stages for Wide Voltage Range Applications

Wu, Hongfei; Liu, Tingting; Yang, Tianyu; Xing, Yan

doi:10.1109/tpel.2017.2761906

Cited by 47 publications

(16 citation statements)

References 24 publications

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“…In this section, multiport DC‐DC conversion with non‐isolated type of converter is exhibited which is discussed in literature [68, 71–77][78–85][6, 86–102]…”

Section: Multi‐port Dc‐dc Converter Using Transformermentioning

confidence: 99%

Topological review of hybrid RES based multi‐port converters

Yalla

Subudhi

Ramachandaramurthy

2022

IET Renewable Power Gen

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Depletion of natural resources like gas, oil, coal along with environment pollution increased the popularity of the Renewable Energy Sources (RES). Power Electronic converters are utilized for conversion of power from RES to coordinate the stand-alone load and utility grid. MPPT control is also established by these converters to supply the standalone or gridconnected load despite of the RES's unpredictable nature. In order to reduce the number of switches used for integrating RES to drive loads, Multi-port converters are developed. These converters have the capability to supply more than one load simultaneously. Furthermore, more number of RESs are connected using these converters in order to drive common loads. Available literatures do not explain in detail regarding various types of multi-output converters, their advantages, disadvantages, application area and control techniques used in order to drive these converters. In this context, a review of recent advances in multi-port DC-DC converters for different application using hybrid RESs is carried out. Initially in literature, few DC-DC converters are connected in parallel, series configuration and used as multi-port converters. Multi-stage conversion is realized using DC-AC-DC conversion. Advantages of conventional converters are integrated in order to develop derived multi-output converters. These multi-port converters have the capability to drive both DC and AC loads from a single DC input source. The converters share common power electronics equipment while generating both DC and AC power simultaneously. Furthermore, these multi-port converters also use single step power conversion process which reduces the overall system loss. As these hybrid multi-port converters use lesser number of power electronic switches, the control complexity of these converters reduces compared to the conventional converters connected in cascaded or parallel manner to drive loads. A detailed review of these multi-port converters with respect to topologies, and operating principle, diverse reliability and effectiveness are presented in this paper. This survey helps designers to select the appropriate RES-based multi-port converters for their respective applications. INTRODUCTIONRecent developments in RESs based smart grids, EVs, aerospace applications, and mobile portable devices gave a scope to new DC-DC power conversion system [1-3]. For renewable energy sectors, a DC-DC power conversion system is developed for energy harvest maximization. The fastest growing RES are Wind and PV, which is said to be as power optimizers [4,5]. For diversified application, DC-DC power conversion system should accommodate several input energyThis is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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“…In this section, multiport DC‐DC conversion with non‐isolated type of converter is exhibited which is discussed in literature [68, 71–77][78–85][6, 86–102]…”

Section: Multi‐port Dc‐dc Converter Using Transformermentioning

confidence: 99%

Topological review of hybrid RES based multi‐port converters

Yalla

Subudhi

Ramachandaramurthy

2022

IET Renewable Power Gen

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“…However, there are large voltage ripples during transitions. Moreover, the authors from the same group derived a novel three-phase three-port rectifier (TPTPR) as the PFC converter from the well-known three-phase six-switch boost rectifier in [60]. In order to reduce the conversion stages and improve the power conversion efficiency, a modified space vector PWM (SVPWM) strategy was proposed.…”

Section: Control Techniquesmentioning

confidence: 99%

Electrical and Electronic Technologies in More-Electric Aircraft: A Review

Liu

Mei

et al. 2019

IEEE Access

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This paper presents a review of the electrical and electronic technologies investigated in moreelectric aircraft (MEA). In order to change the current situation of low power efficiency, serious pollution, and high operating cost in conventional aircraft, the concept of MEA is proposed. By converting some hydraulic, mechanical, and pneumatic power sources into electrical ones, the overall power efficiency is greatly increased, and more flexible power regulation is achieved. The main components in an MEA power system are electrical machines and power electronics devices. The design and control methods for electrical machines and various topologies and control strategies for power electronic converters have been widely researched. Besides, several studies are carried out regarding energy management strategies that intend to optimize the operation of MEA power distribution systems. Furthermore, it is necessary to investigate the system stability and reliability issues in an MEA, since they are directly related to the safety of passengers. In terms of machine technologies, power electronics techniques, energy management strategies, and the system stability and reliability, a review is carried out for the contributions in the literature to MEA. INDEX TERMS More-electric aircraft, machine technologies, power electronics techniques, energy management strategies, system stability and reliability.

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“…Therefore, the proposed circuit is mostly suitable for low power applications.Wu, H investigated the topologies, operation principles, and modulation strategies of a three-port three-phase rectifier (TPTPR). The study improves the overall efficiency of the TPTPR-based AC-DC power conversion system [8]. Mallik, A proposed a three-phase boost power factor correction (PFC) using a single DC output voltage sensor is controlled by another methodology [9].…”

Section: Introductionmentioning

confidence: 99%

Soft-Switching Technology of Three-Phase Six-Switch PFC Rectifier

Zhen

2020

Energies

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An active clamp, three-phase, six-switch power factor correction rectifier with a one-cycle controller is proposed, which can effectively suppress the reverse recovery of the reverse parallel diode of the bridge arm switch and reduce the reverse recovery loss. The main switches and auxiliary switch are both zero-voltage switches. It works in a fixed switching frequency and low power stress during the switching period. The specific working process and control circuit are analyzed in detail, and the model simulation is carried out. The experimental platform of a 2.5 KW prototype, with a complete test and verification of the soft switch technology proposed in this paper, was set up in the laboratory.

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Modified SVPWM-Controlled Three-Port Three-Phase AC–DC Converters With Reduced Power Conversion Stages for Wide Voltage Range Applications

Cited by 47 publications

References 24 publications

Topological review of hybrid RES based multi‐port converters

Topological review of hybrid RES based multi‐port converters

Electrical and Electronic Technologies in More-Electric Aircraft: A Review

Soft-Switching Technology of Three-Phase Six-Switch PFC Rectifier

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