A single‐switch high‐gain DC–DC converter for photovoltaic applications

Kalahasthi, Rajesh Babu; Ramteke, M. R.; Suryawanshi, Hiralal Murlidhar; Kothapalli, Koteswara Rao

doi:10.1002/cta.3205

Cited by 17 publications

(21 citation statements)

References 36 publications

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“…In addition, these configurations also provide high efficiency and low voltage stress [36−38]. From [39,40], it is noted that the cascaded configuration of boost converters exhibits ultra-high gain with an elimination of diode reverse recovery loss. At the same time, it is capable of achieving desired operating characteristics required for renewable applications.…”

Section: Literature Reviewmentioning

confidence: 99%

Adaptive neuro-fuzzy approach for maximum power point tracking with high gain converter for photo voltaic applications

2022

IJATEE

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Energy is essential for improving the management of the power systems. One of the major concerns in the power sector is increasing demand of power that tends to increase the demand for fossil fuels causing environmental problems. Thus, it is essential to use variable renewable energies for direct current (DC) micro grid applications. Solar photo voltaic (PV) is one of the phenomena where the solar irradiance is converted to electrical power through solar cell. A new high gain converter is implemented which is fed from solar PV to track the maximum voltage and power so as to elevate the output efficiency of the PV panel. The envisioned converter can be effectively worked in continuous conduction mode (CCM) with same gating pulse for the two switches that guarantees wide plying range. The preferred converter comprises least number of components and achieves a maximum gain of 25 for the switch on period of 0.8 which makes the control circuit simpler compared to other non-coupled inductor topologies. Presently, special maximum power point tracking (MPPT) procedures have been acquainted to track the maximum power point (MPP) viably of which adaptive neuro fuzzy inference system (ANFIS) based controller is used in this article and high efficiency of about 98.96% is attained with good dynamic response. Over here, the potency of the system is endorsed by means of MATLAB/SIMULINK and compared with the other standard MPPT methods. Further, functioning and assessment of the conspired work are inspected carefully and verified effectively.

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Section: Literature Reviewmentioning

confidence: 99%

Adaptive neuro-fuzzy approach for maximum power point tracking with high gain converter for photo voltaic applications

2022

IJATEE

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“…By combining the coupled inductor with some techniques, the voltage level can be increased significantly. These techniques include voltage lifting, 14,15 voltage multiplier, 16–20 switched capacitor, 21,22 and switched inductor 23 …”

Section: Introductionmentioning

confidence: 99%

“…[9][10][11][12][13] By combining the coupled inductor with some techniques, the voltage level can be increased significantly. These techniques include voltage lifting, 14,15 voltage multiplier, [16][17][18][19][20] switched capacitor, 21,22 and switched inductor. 23 Disadvantages of the coupled inductor include large inductor magnetization current, using half of the B-H curve of core, and increased current ripple at the primary winding.…”

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confidence: 99%

Theoretical and experimental evaluation of SEPIC‐based DC–DC converters with two‐winding and three‐winding coupled inductors

Mahmoudi

Ajami

Babaei

et al. 2022

Circuit Theory & Apps

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In this paper, an SEPIC‐based direct current–direct current (DC–DC) converter with high voltage gain and continuous input current is provided. Input current Continuity is a great advantage for renewable resources applications, and a small filter can be used in the output of these sources. Also in this paper, the effect of coupled inductor in three‐winding structure is discussed compared to the two‐winding coupled inductor. Precise analysis of converters based on two‐winding and three‐winding coupling inductors requires that the structures be similar so that the evaluation can be performed correctly. A comparison is performed between the two‐winding coupled inductor‐based converter and the improved converter to show the advantages of the proposed converter. All elements of the converter have been compared, and since both converters are different in terms of coupled inductor, complete analyses have been done in the field of calculating inductors. In addition to the features of the two‐winding coupled inductor converter, the proposed converter requires smaller coupled inductor to decrease the core size and increase the converter efficiency.

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“…Several sources can be considered in the scope of distributed generation, such as fuel cells (FC) and the photovoltaic cells (PV) 1–3 . These sources provide a low DC voltage (typically <50 V), so a high step‐up DC‐DC converter is required to increase this low voltage to high output voltage 4 . The standard boost converter and flyback converter are, respectively, the simplest nonisolated and isolated step‐up converters.…”

Section: Introductionmentioning

confidence: 99%

“…[1][2][3] These sources provide a low DC voltage (typically <50 V), so a high step-up DC-DC converter is required to increase this low voltage to high output voltage. 4 The standard boost converter and flyback converter are, respectively, the simplest nonisolated and isolated step-up converters. However, in these applications where high voltage gain is required, these standard converters cannot achieve good performance, due to the extreme duty cycle or high turns ratio of coupled inductor (CI) required to reach such a goal.…”

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confidence: 99%

High step‐up active switched coupled inductor DC‐DC converter with voltage multiplier

Andrade

Faistel

Toebe

et al. 2022

Circuit Theory & Apps

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High step-up DC-DC converters are commonly used in new energy applications such as DC microgrid, photovoltaic cell, and fuel cell. Thus, this article introduces a new nonisolated high step-up DC-DC converter based on active switched coupled inductor with a voltage multiplier cell. The proposed converter presents low current and voltage stress across the switches owing of the dual active switches structure. Besides that, by the voltage multiplier cell (one diode and one capacitor), the voltage gain of proposed converter is increased. In addition, it can be highlighted that the proposed converter has low component count, simplicity of operation in continuous and discontinuous conduction mode, and energy stored in the leakage inductor that is recycled in the capacitor of voltage multiplier cell. This article discussed the principle of operation, the ideal and nonideal voltage gain, external characteristic, voltage and current stress, design guidelines, and performance comparison with previous high step-up converters. Finally, a prototype circuit with input power 300 W, input voltage 30 V, and output voltage 400 V was built in the laboratory to verify the theoretical evaluation, and the maximum achieved efficiency was 95.35% at nominal power 300 W. K E Y W O R D Sactive switched coupled inductor, active switched inductor, high step-up, high voltage gain, voltage multiplier | INTRODUCTIONDistributed generation is an alternative to the existing global energy system, becoming a promising candidate for the more efficient use of energy, economic-financial and environmental resources. Several sources can be considered in the scope of distributed generation, such as fuel cells (FC) and the photovoltaic cells (PV). [1][2][3] These sources provide a low DC voltage (typically <50 V), so a high step-up DC-DC converter is required to increase this low voltage to high output voltage. 4 The standard boost converter and flyback converter are, respectively, the simplest nonisolated and isolated step-up converters. However, in these applications where high voltage gain is required, these standard converters cannot achieve good performance, due to the extreme duty cycle or high turns ratio of coupled inductor (CI) required to reach such a goal. In this situation, the parasitic resistances of components or leakage inductance of CI result in large conduction losses, high copper losses of windings, and overvoltage problem on semiconductors. 5,6

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A single‐switch high‐gain DC–DC converter for photovoltaic applications

Cited by 17 publications

References 36 publications

Adaptive neuro-fuzzy approach for maximum power point tracking with high gain converter for photo voltaic applications

Adaptive neuro-fuzzy approach for maximum power point tracking with high gain converter for photo voltaic applications

Theoretical and experimental evaluation of SEPIC‐based DC–DC converters with two‐winding and three‐winding coupled inductors

High step‐up active switched coupled inductor DC‐DC converter with voltage multiplier

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