Your search keyword '"Mahmoodreza Eskandarpour Azizkandi"' showing total 9 results

1. A topology of coupled inductor DC–DC converter with large conversion ratio and reduced voltage stress on semiconductors

Author

Ebrahim Babaei, Mahmoodreza Eskandarpour Azizkandi, and Farzad Sedaghati

Subjects

Materials science, 020209 energy, 020208 electrical & electronic engineering, 02 engineering and technology, Inductor, Topology, law.invention, Lift (force), Capacitor, Power rating, law, Clamper, Duty cycle, 0202 electrical engineering, electronic engineering, information engineering, Voltage multiplier, Electrical and Electronic Engineering, Voltage

Abstract

This study presents a high boost DC–DC converter, integrates voltage multiplier cell, voltage lift capacitor, and coupled-inductor techniques to achieve a high-voltage gain. The proposed topology has the capability of extension without utilising any additional winding for a very large voltage conversion ratio. With utilising a passive clamp circuit and without requiring higher duty cycle values, the suggested converter obtains a large conversion ratio, low conduction losses, and reduced voltage stress of semiconductors with a steady value for the whole range of duty cycle. The converter operation principle is discussed and its steady-state operation is analysed in detail. Also, theoretic efficiency calculation and design guidelines of the topology are explained. Then, the proposed DC–DC converter is compared with similar configurations to indicate its advantages. Eventually, the validity of theoretic analysis is verified using experimental measurement results of the implemented prototype with a power rating of 226 W.

Published

2020

2. Design and implementation of an ultra‐high voltage DC‐DC converter based on coupled inductor with continuous input current for clean energy applications

Author

Mohammad Reza Soltanpour, Hamid Radmanesh, and Mahmoodreza Eskandarpour Azizkandi

Subjects

Ultra high voltage, Materials science, business.industry, Applied Mathematics, Clean energy, Electrical engineering, Electrical and Electronic Engineering, Current (fluid), business, Inductor, Dc dc converter, Computer Science Applications, Electronic, Optical and Magnetic Materials

Published

2020

3. Extendable topology of step‐up DC–DC converter with continuous input current for renewable energy applications

Author

Mahmoodreza Eskandarpour Azizkandi and Farzad Sedaghati

Subjects

Leakage inductance, Materials science, 020209 energy, 020208 electrical & electronic engineering, Topology (electrical circuits), High voltage, 02 engineering and technology, Topology, Inductor, Power rating, Duty cycle, 0202 electrical engineering, electronic engineering, information engineering, Voltage multiplier, Electrical and Electronic Engineering, Voltage

Abstract

A single-switch high boost DC–DC converter is introduced in this work. In the suggested topology, a voltage multiplier cell and three-winding coupled inductor (CL) are integrated to obtain an ultra-large conversion ratio. Using a passive clamp circuit and also, no requirement of larger duty cycle values enable the converter to have a very high voltage gain, low conduction loss, and reduced voltage stress of semiconductors. Moreover, the leakage inductance of the CL alleviated diodes reverse recovery problem. Some important merits include ultra-high voltage gain, operating in low duty cycles, reduced voltage stress of semiconductors, continuous input current, high efficiency, and low turn ratio of the CL makes the introduced converter very suitable for renewable energy applications. Steady-state analysis and operation principles of the presented topology are expressed completely in the study. Moreover, the theoretical efficiency analysis and design guidelines of the suggested configuration are presented. Also, the superiority of the presented topology over the state-of-the-art similar DC–DC converters is demonstrated in the comparison study. Eventually, the validity of theoretical analysis is verified using experimental measurement results of the implemented prototype with a power rating of 240 W and an output voltage of 440 V.

Published

2020

4. A High Voltage Gain DC–DC Converter Based on Three Winding Coupled Inductor and Voltage Multiplier Cell

Author

Farzad Sedaghati, Hossein Shayeghi, Mahmoodreza Eskandarpour Azizkandi, and Frede Blaabjerg

Subjects

three winding, Leakage inductance, single switch, Materials science, business.industry, coupled inductor, Voltage multiplier cell, Electrical engineering, High voltage, Topology (electrical circuits), Inductor, dc-dc power converters, Duty cycle, Voltage multiplier, high-voltage gain, Electrical and Electronic Engineering, business, low voltage stress, Low voltage, Voltage

Abstract

This article introduces a single-switch, high step-up, dc-dc converter based on coupled-inductor with three winding and voltage multiplier cell to obtain a very high-voltage conversion ratio. A passive clamp circuit is applied in the converter to recycle the energy of leakage inductance and reduce voltage stress of the main power switch. This leads to utilize a power switch with low on-state resistance and low voltage rating that decreases the conduction losses. Several advantages include low operating duty cycle, high voltage conversion ratio, low turn ratio of the coupled inductor, leakage inductance reverse recovery, reduced voltage stress of semiconductors, alleviation of diodes reverse recovery issue and high efficiency, which make the presented topology appropriate for sustainable energy applications such as photovoltaic systems. The operation principle and steady-state analysis of the suggested topology in continuous conduction mode are expressed in detail. Also, design procedure and theoretical efficiency analysis of the proposed topology are presented. Moreover, a comparison study is performed to demonstrate the superiority of the presented converter over several similar recently proposed dc-dc converters. Finally, the proposed dc-dc converter feasibility and performance are justified through a fabricated 216-W laboratory prototype at 50 kHz switching frequency.

Published

2020

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

Author

Hossein Shayeghi, Farzad Sedaghati, Frede Blaabjerg, and Mahmoodreza Eskandarpour Azizkandi

Subjects

Leakage inductance, Materials science, 020209 energy, 020208 electrical & electronic engineering, High voltage, 02 engineering and technology, Converters, Inductor, Clamper, Duty cycle, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Voltage multiplier, Electrical and Electronic Engineering, Voltage

Abstract

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.

Published

2020

6. 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

Author

Mahmoodreza Eskandarpour Azizkandi, Hossein Shayeghi, and Farzad Sedaghati

Subjects

Stress (mechanics), Materials science, business.industry, Applied Mathematics, Electrical engineering, Electrical and Electronic Engineering, Inductor, business, Low voltage, Dc dc converter, Computer Science Applications, Electronic, Optical and Magnetic Materials, Pv power

Published

2019

7. A Continuous Input Current DC-DC Converter Based on Coupled Inductor for Renewable Energy Applications

Author

Mohammad Reza Soltanpour, Mahmoodreza Eskandarpour Azizkandi, and Hamid Radmanesh

Subjects

Materials science, business.industry, MOSFET, Energy conversion efficiency, Electrical engineering, High voltage, Topology (electrical circuits), Inductor, business, Power (physics), Diode, Voltage

Abstract

A high-efficiency and a high conversion gain DC-DC converter is introduced in this paper to apply sustainable energy sources into dc nano-grid. The introduced topology takes the property of the coupled inductor (CL) method to obtain a declined voltage stress of the semiconductor devices and high voltage conversion ratio. The MOSFET voltage stress is remarkably decreased constracted to the output high voltage. Thus, a low on resistance MOSFET and low rating voltage is used to increase the efficiency of the suggested topology. Moreover, the CL application obviates the reverse recovery losses of diodes. The steady-state analysis and operation principle of the suggested configuration are elaborated. Besides, the introduced configuration superiority is illustrated over many alike most momentous recently proposed DC-DC configurations in the section 5. The simulation results demonstrate coherence with the theoretical study with a 340 V output voltage and a 340 W output power. The topology demonstrates a 96.5% peak conversion efficiency.

Published

2021

8. A Single-Switch High Step-Up DC-DC Converter Based on Integrating Coupled Inductor and Voltage Multiplier Cell for Renewable Energy Applications

Author

Hossein Shayeghi, Morteza Dezhbord, Mahmoodreza Eskandarpour Azizkandi, and Farzad Sedaghati

Subjects

Leakage inductance, Materials science, business.industry, 020208 electrical & electronic engineering, Electrical engineering, High voltage, Hardware_PERFORMANCEANDRELIABILITY, 02 engineering and technology, Inductor, Hardware_GENERAL, Hardware_INTEGRATEDCIRCUITS, 0202 electrical engineering, electronic engineering, information engineering, Voltage spike, Voltage multiplier, 020201 artificial intelligence & image processing, business, Low voltage, Voltage, Leakage (electronics)

Abstract

In this paper, a high step-up, single switch, non-isolated, coupled inductor based DC-DC converter is proposed for sustainable energy applications. A high voltage gain is achieved by applying a coupled inductor and two voltage multiplier cells in the structure of proposed converter. The passive clamp that is connected to the main switch recovers the coupled inductor leakage inductance energy and limits the voltage spike on the power switch. Thus, low on-state resistance of the power switch can be adapted to decrease the conduction loss. The features such as coupled inductor with a low turn ratio, high voltage conversion ratio in suitable duty cycles, , high efficiency, recycled energy of leakage inductor and low voltage stress on the power switches and diodes make the presented converter appropriate for sustainable energy applications. The steady state analysis and voltage stress of the power switch and diodes of the converter are expressed in detail. Finally, simulation results in PSIM software have been presented to confirm the performance of the suggested structure.

Published

2019

9. A High-Efficiency Non-Isolated High-Gain Interleaved DC-DC Converter with Reduced Voltage Stress on Devices

Author

Farzad Sedaghati, Seyed Hadi Latifi Majareh, Hossein Shayeghi, and Mahmoodreza Eskandarpour Azizkandi

Subjects

Materials science, 020208 electrical & electronic engineering, Ripple, Ćuk converter, 020206 networking & telecommunications, Topology (electrical circuits), 02 engineering and technology, Converters, Inductor, Power (physics), 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Voltage, Diode

Abstract

This paper proposes a new high-efficiency, non-isolated, interleaved DC-DC converter. The suggested structure consists of two interleaved modified step-up KY converters, to obtain a high voltage conversion ratio without the use of coupled inductors. The presented converter has a higher voltage gain than traditional interleaved boost, CUK, buck-boost, ZETA and SEPIC converters, and in suitable duty cycles, a high voltage conversion ratio can be obtained for the converter. Voltage stress of the power switches and diodes is low. Therefore, switches with low on-state resistance and low conduction losses can be used to enhance efficiency. Moreover, with the utilization of interleaving techniques the ripple of input current in the suggested topology is reduced. The steady-state analysis and operating principles of the suggested topology are expressed in this paper. Finally, in order to verify theoretical analysis and performance of the proposed converter, experimental measurement results are presented.

Published

2019