A Family of Scalable Non-Isolated Interleaved DC-DC Boost Converters With Voltage Multiplier Cells

Alzahrani, Ahmad; Ferdowsi, Mehdi; Shamsi, Pourya

doi:10.1109/access.2019.2891625

Cited by 96 publications

(60 citation statements)

References 45 publications

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“…This can be achieved by the use of VD, but it is not possible with VT cells. Table I summarizes the voltage gain of cells and the static gain of converters obtained with the insertion of these VMCs, based on (Alzahrani et al 2019), (Axelrod et al 2008) and (Yao et al 2015), where D is duty cycle of converter and n is the transformer turn ratio.…”

Section: Derivation Of Convertermentioning

confidence: 99%

Analysis and Design of Isolated SEPIC Converter with Greinacher Voltage Multiplier Cell

Andres

Romitti

Dupont

et al. 2020

Anais Do Congresso Brasileiro De Automática 2020

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High step-up converters are required and used in photovoltaic applications, due to low voltage of photovoltaic modules. In this paper, an isolated dc-dc high step-up SEPIC with a Greinacher voltage doubler cell is presented. It has the advantage of continuous input current, high efficiency, high voltage gain, isolation and demands a single switch, being suitable for low power grid-tie photovoltaic systems. The operating principles and steady-state analysis are presented, including the detailed analysis of resonant stage, where the value of primary side capacitor is taken into account and plays an important role in the design of the converter, since it directly affects the resonance frequency and RMS current values. Simulation results are presented to validate the analysis and design.

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Section: Derivation Of Convertermentioning

confidence: 99%

Analysis and Design of Isolated SEPIC Converter with Greinacher Voltage Multiplier Cell

Andres

Romitti

Dupont

et al. 2020

Anais Do Congresso Brasileiro De Automática 2020

View full text Add to dashboard Cite

show abstract

“…On the other hand, there are many benefits to employing a non-isolated converter. With the elimination of the transformer, it reduces the cost and size of the converter [10]- [11]. This also makes the converter circuit simpler in topology.…”

Section: Introductionmentioning

confidence: 99%

Triple-Mode Active-Passive Parallel Intermediate Links Converter With High Voltage Gain and Flexibility in Selection of Duty Cycles

et al. 2020

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A high number of research work is being carried out in the field of DC-DC converters to improve the performance of microgrid operation. The DC microgrid has a high level of acceptance because of the integration of renewable energy sources. In DC Microgrid, there is a need for improved DC-DC converter topologies which offer high gain, small size, enhanced efficiency, reduced voltage stress and reduced component count etc. A new Triple-Mode Active-Passive Parallel Intermediate Links (TM-A2P-IL) converter is proposed in the paper. The A2P-IL is designed by a combination of an inductor, capacitor, diode, and control switch. The proposed converter is derived by inserting A2P-IL in conventional boost converter. The proposed TM-A2P-IL converter operates in three modes and provides a high voltage gain without using a transformer, voltage multiplier stages, coupled inductor, switched inductor/capacitor circuitry. The other benefits of the proposed TM-A2P-IL converters are flexibility in the selection of duty cycles, reduced voltage stress of devices, small reactive components, single-stage power conversion. The proposed converter circuit, operating principle, steady-state analysis is studied for both CCM and DCM, discussed. The comparison between available similar type converters and the proposed converter is provided. The operation and performance of the proposed A2P-IL converter are validated through simulation and experimental work.

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“…The benefits of interleaving include high power capability, modularity, and improved reliability. However, an interleaved topology improves converter performance at the cost of additional inductors, power switching devices, and output rectifiers . The size of inductors in the interleaved method is lower than the conventional ones.…”

Section: Introductionmentioning

confidence: 99%

A novel structure for high step‐up DC‐DC converter with flexibility under the variable loads for EV solar charging system

Eskandarian

Harchegani

Kazemi

2020

Int Trans Electr Energ Syst

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Summary Recently, with the development of electric vehicles (EVs), in order to compensate for the undesirable effects of charging stations on grid characteristics, paying attention to the local generators based on renewable energy has increased and has caused to develop of the peripheral systems. In this paper, a high step‐up multistage structure consisting of several integrated boost flyback converter (IBFC) has been proposed. In the combination of these stages, the boost subconverters are interleaved in order to charge the battery bank and are in series with the flyback subconverters in order to supply the variable loads. The proposed structure has advantages, such as applicability in high voltage step‐up cases, enhanced reliability in photovoltaic system, and flexibility against variable power consumption. In addition, this structure at the no‐load condition has the ability to charge the battery system with proper voltage and supply several vehicles simultaneously without any voltage drop. Furthermore, the energy stored in leakage inductor can be recycled instead of damping with passive snubbers, resulting in high conversion efficiency and simple circuit structure with fewer components. The performance of proposed structure is analyzed in detail at no‐load, loading, and input power outage conditions. Then, the proposed converter with solar panel input power in order to supply the EV charging system is simulated in Matlab/Simulink to verify the analytical results. Finally, a three‐stage prototype (17.3–240 V) with 60 W solar panel input has been developed, which validates the feasibility and the effectiveness of the proposed topology using variable loads (180, 360, 720 W).

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A Family of Scalable Non-Isolated Interleaved DC-DC Boost Converters With Voltage Multiplier Cells

Cited by 96 publications

References 45 publications

Analysis and Design of Isolated SEPIC Converter with Greinacher Voltage Multiplier Cell

Analysis and Design of Isolated SEPIC Converter with Greinacher Voltage Multiplier Cell

Triple-Mode Active-Passive Parallel Intermediate Links Converter With High Voltage Gain and Flexibility in Selection of Duty Cycles

A novel structure for high step‐up DC‐DC converter with flexibility under the variable loads for EV solar charging system

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