Design and analysis of a high step‐up single‐switch coupled inductor DC‐DC converter with low‐voltage stress on components for PV power application

Azizkandi, Mahmoodreza Eskandarpour; Sedaghati, Farzad; Shayeghi, Hossein

doi:10.1002/cta.2633

Cited by 33 publications

(49 citation statements)

References 37 publications

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“…Therefore, the value of coupling coefficient can be assumed unity. The ideal voltage gain of the proposed converter at k = 1 is derived as (22).…”

Section: Voltage Gainmentioning

confidence: 99%

“…The coupled inductor and voltage multiplier techniques are combined in Ajami et al 14 and Axelrod et al 15 In spite of the fact that the converters in the previous studies [11][12][13][14][15] provide a high voltage gain and limit voltage spike on the switches, their input current is discontinuous with a high ripple. Therefore, in the previous studies, [16][17][18][19][20][21][22] some DC-DC converters with continuous input current and low switch voltage stress are introduced. Nevertheless, a high turn ratio and duty cycle are needed to achieve a very high step-up voltage gain in these converters.…”

Section: Introductionmentioning

confidence: 99%

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Single switch quadratic boost converter with continuous input current for high voltage applications

Mirzaee

Ansari

Moghani

2020

Circuit Theory & Apps

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Summary In this paper, a novel non‐isolated very high step‐up DC‐DC converter is presented. The introduced converter benefits from various advantages, namely, very high voltage gain, low voltage stress on the active switch, and continuous input current with low ripple. Therefore, the presented converter is suitable for renewable energy applications. In addition, the energy of the leakage inductance of the coupled inductor is successfully recovered, and the voltage spike of the active switch is clamped during the turn‐off process. Hence, a switch with low Rds−on can be used, which decreases the conduction losses as well as cost of the converter. Furthermore, the voltage stress of the output diode is decreased, which reduces the reverse recovery problem. The steady‐state analysis and design considerations of the proposed converter are discussed. Finally, the theoretical analysis is validated with the experimental results at an output power of 150 W.

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“…Therefore, the value of coupling coefficient can be assumed unity. The ideal voltage gain of the proposed converter at k = 1 is derived as (22).…”

Section: Voltage Gainmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Single switch quadratic boost converter with continuous input current for high voltage applications

Mirzaee

Ansari

Moghani

2020

Circuit Theory & Apps

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“…Moreover, it should be considered that using a higher turn ratio to achieve a higher voltage gain causes higher electromagnetic interference noise and power losses. Recently, some high step-up DC-DC converters based on two-winding coupled inductor (2WCI) are presented in [8][9][10][11][12][13][14][15][16][17]. Moreover, several recent high step-up DC-DC converters with three-winding coupled inductor (3WCI) have been presented in [18][19][20][21][22], which leads to having more flexible regulation on voltage stress and voltage gain.…”

Section: Introductionmentioning

confidence: 99%

Two‐ and three‐winding coupled‐inductor‐based high step‐up DC–DC converters for sustainable energy applications

Azizkandi

Sedaghati

Shayeghi

et al. 2020

IET Power Electronics

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This study proposes two configurations for a non-isolated, high step-up, single-switch, coupled-inductor-based DC-DC converter. A coupled inductor and voltage multiplier cells are used in the presented topologies to obtain a high voltage gain. Also, a passive clamp circuit is applied in the topologies to reduce voltage stress of the main power switch. This leads to utilising a power switch with lower on-state resistance, which decreases the conduction loss. Several advantages such as low operating duty cycle, high voltage conversion ratio, reduced voltage stress of semiconductors, low turn ratio of the coupled inductor, leakage inductance energy recovery and high efficiency operation make the presented structures appropriate for sustainable energy applications. The operational principle and steady-state analysis of the suggested topologies in continuous conduction mode are expressed in detail. Also, design procedure and theoretical efficiency of the topologies are presented. Then, the suggested topologies are compared with several similar high step-up topologies to prove their advantages. Finally, the performance and feasibility of the proposed DC-DC converter configurations are confirmed through experimental measurement results of 29 V input and 435 V/213 W and 480 V/238 W output laboratory prototypes at 50 kHz switching frequency.

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“…However, by adding a clamp circuit, the number of devices is increased, which leads to an increase in the converter size and cost [21]. The coupled inductor and voltage multiplier circuit are combined to provide a highvoltage conversion ratio [22][23][24]. These converters are highperformance circuits with low cost and simple structures, which usually include diodes and capacitors to increase DC voltage [25].…”

Section: Introductionmentioning

confidence: 99%

Analysis and implementation of a boost DC–DC converter with high voltage gain and continuous input current

Sedaghati

Pourjafar

2020

IET Power Electronics

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In this study, a new high-voltage gain DC-DC converter based on the coupled inductor and voltage lift circuit technique is proposed. In the suggested converter, a high-voltage conversion ratio is achieved using a low turn's ratio of the coupled inductor which decreases the volume of core. Also, by selecting the low number of turn's ratio of coupled inductors, the peak voltage through the semiconductors is decreased subsequently. Moreover, the voltage lift circuit is utilised for further increasing the voltage gain and clamping the voltage spike through the main power switch. Zero current switching condition of diodes is another merit of the proposed DC-DC converter, which leads to decrease in the reverse recovery losses generated by diodes. Therefore, the overall efficiency can be enhanced. Technical analysis and comparison surveys with similar topologies are provided to demonstrate the effectiveness of the suggested DC-DC converter. Finally, to validate the performance of the proposed structure, a laboratory prototype with a 200 W power level and 25 kHz operating frequency is implemented.

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Design and analysis of a high step‐up single‐switch coupled inductor DC‐DC converter with low‐voltage stress on components for PV power application

Cited by 33 publications

References 37 publications

Single switch quadratic boost converter with continuous input current for high voltage applications

Single switch quadratic boost converter with continuous input current for high voltage applications

Two‐ and three‐winding coupled‐inductor‐based high step‐up DC–DC converters for sustainable energy applications

Analysis and implementation of a boost DC–DC converter with high voltage gain and continuous input current

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