Review on State-of-the-Art Unidirectional Non-Isolated Power Factor Correction Converters for Short-/Long-Distance Electric Vehicles

Sayed, Sawsan; Massoud, Ahmed M.

doi:10.1109/access.2022.3146410

Cited by 58 publications

(11 citation statements)

References 124 publications

(166 reference statements)

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“…These converters offer alternative solutions for shoreto-ship low-voltage connections. Other types of nonisolated PFC topologies proposed for EV charging applications can be an option for shore-to-ship connections such as Buck-boost, SEPIC, Ćuk, Zeta, or Luo derived converters [36]. For onshore fast charging, Takamasa et al [37], and Hiroyasu et al [38] investigated an on-road EV quick charger to charge a 25 kW electric boat.…”

Section: Diode Bridge Rectifiermentioning

confidence: 99%

A Review of Power Converters for Ships Electrification

Mahdi

Hoff

Østrem

2023

IEEE Trans. Power Electron.

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Section: Diode Bridge Rectifiermentioning

confidence: 99%

A Review of Power Converters for Ships Electrification

Mahdi

Hoff

Østrem

2023

IEEE Trans. Power Electron.

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“…PFC rectifiers have applications in charging low-capacity lithium-ion batteries, such as those used in electronic devices, including mobile phones, which require high power density designs but are also needed for charging electric vehicle (EV) battery banks. Those converters used as on-board or off-board EV chargers can be unidirectional or bidirectional [ 13 , 14 , 15 , 16 ]. A review of single-phase unidirectional non-isolated PFC converters for onboard battery chargers can be found in [ 16 ].…”

Section: Introductionmentioning

confidence: 99%

“…Those converters used as on-board or off-board EV chargers can be unidirectional or bidirectional [ 13 , 14 , 15 , 16 ]. A review of single-phase unidirectional non-isolated PFC converters for onboard battery chargers can be found in [ 16 ]. Other applications are in uninterruptible power supplies for data centers [ 17 ], and wireless power transfer systems [ 18 ].…”

Section: Introductionmentioning

confidence: 99%

Multi-Phase Interleaved AC–DC Step-Down Converter with Power Factor Improvement

et al. 2023

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This paper presents the converter design of a single-phase non-isolated step-down controlled rectifier for power factor improvement and output voltage regulation. The converter consists of a full-bridge diode rectifier and a DC-DC interleaved buck converter of two or more switching cells that has an LC filter in its input. It is proposed that the interleaved switching cells operate in discontinuous conduction mode and the current through the input LC filter be continuous, avoiding switching frequency components to be injected into the grid. The controller, which has a simple structure and a small number of sensors, allows the system to achieve a high power factor. It also regulates the output voltage to a constant reference. An experimental prototype is built and tested to validate the analysis and proposed design. The closed-loop converter is evaluated both in a steady state and in transient conditions. At steady state, the converter achieves a power factor above 0.9 with a maximum of 45.4% THD at 110.1 W. The main contributions of this paper are guidelines for the design of the converter, open-loop analysis, and converter control.

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“…To perform the AC-DC operation the conventional diode rectifier might be used which leads to more power loss consequently the power factor as well as THD degrades. To maintain the PFC tropology might be used which is complicated and costly [7][8][9][10][11][12][13][14][15][16][17][18]. To get rid of it a low-frequency coupled inductor-based AC-DC converter has been used which is associated with a LCL filter and two diodes [19][20][21][22].…”

Section: Introductionmentioning

confidence: 99%

A Modified PI-Controller Based High Current Density DC–DC Converter for EV Charging Applications

2023

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Electric vehicles (EVs) are getting more popular in the field of automobiles due to environmental factors and others. Since electric vehicles manage their power from the rechargeable battery so it's essential to have a reliable, efficient, and economical battery charger that can provide stable required output for the specified EV's battery. In this paper, a DC-DC converter with a modified PI controller has been presented which helps to achieve the required output voltage and high current density with negligible overshoot for the specified lithium-ion battery system to minimize the charging time. Apart from minimizing the power loss of the active switches, the proposed system minimizes the junction temperature which eventually improves the life cycle of the converter. The analysis of the proposed converter is performed both in ideal and non-ideal conditions. The power loss of the active switches and the junction temperature have also been analyzed. An economical and effective dc and ac side inductor has been designed and perform the total power loss and the temperature rise. The analysis results show that the proposed converter can maintain a power factor of more than 90% and a total harmonic distortion of less than 0.46%, which is ideal for the high-density load current. The reliability of the dc-dc converter is also evaluated. A hardware prototype has also been implemented to confirm its viability for EV battery charging applications.INDEX TERMS Buck, Lithium-ion battery charger, Electric vehicle battery charger, AC-DC converter, Isolated ac-dc converter, Power factor correction, MOSFET power loss estimation, MOSFET thermal analysis, Modified PI controller, State-space representation of converter.

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Review on State-of-the-Art Unidirectional Non-Isolated Power Factor Correction Converters for Short-/Long-Distance Electric Vehicles

Cited by 58 publications

References 124 publications

A Review of Power Converters for Ships Electrification

A Review of Power Converters for Ships Electrification

Multi-Phase Interleaved AC–DC Step-Down Converter with Power Factor Improvement

A Modified PI-Controller Based High Current Density DC–DC Converter for EV Charging Applications

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