GUEST EDITORS
- Ahmed Al Mansur Associate Professor, Green University of Bangladesh (GUB), Dhaka, Bangladesh Email: mansur@eee.green.edu.bd, ahmedalmansur@outlook.com
Google Scholar: https://scholar.google.com/citations?user=GGR7HJ8AAAAJ&hl=en
Scopus Page: https://www.scopus.com/authid/detail.uri?authorId=55669292500
- MohdShawalJadin Assistant Professor, Faculty of Electrical & Electronics Engineering Technology, Universiti Malaysia Pahang Al-Sultan Abdullah (UMPSA), Pahang, Malaysia Email: mohdshawal@umpsa.edu.
Google Scholar: https://scholar.google.com/citations?user=MLbWLIwAAAAJ&hl=en
Scopus Page: https://www.scopus.com/authid/detail.uri?authorId=24733653900
- Mohammad Shoaib Shahriar, Associate Professor, Department of Electrical Engineering, University of Hafr Al Batin, Hafr Al Batin, Kingdom of Saudi Arabia (KSA).
Email: mshoaib@uhb.edu.sa
Google Scholar: https://scholar.google.com/citations?user=_bZ8Bm0AAAAJ&hl=en
Scopus Page: https://www.scopus.com/authid/detail.uri?authorId=56073493100
Guest Editor (s):
AIMS AND SCOPE In order to match the voltage levels between system components, such as the solar panel or wind turbine output and the battery storage or grid connection, DC/DC converters are frequently employed in both wind and solar systems. Based on the input and output voltages, there are many different types of converters. These can be divided into four categories: rectifiers, or AC to DC converters; cycloconverters, or AC to AC frequency changers; DC to DC voltage or current converters; and DC to AC inverters. The current will be taken and passed through a “switching element” by the basic DC-DC converter. As a result, the signal becomes a real AC square wave. After that, the wave goes through one more filter, which converts it back into a DC signal with the required voltage. In wind energy conversion systems that rely on variable speed, power electronic circuits are an essential enabler. Fixed speed wind turbines are strong, dependable, and easy to operate. Nonetheless, the grid frequency sets the rotor’s speed. They are therefore unable to adhere to the ideal aerodynamic efficiency threshold. Between the electrical power supply and the electric motor is where the power electronics converter is used. Its main function is to regulate the motor’s speed, torque, current, and other parameters. This is accomplished by regulating the power converter’s output voltage and current. An electrical or electro-mechanical device used to convert electrical energy is called a power converter. A power converter has the ability to adjust the voltage or frequency of the current, as well as convert alternating current (AC) into direct current (DC) and vice versa. Converters are used in a variety of settings, including commercial offices, industrial settings, and homes. Applications for converters can be found in solar panels, factory equipment, LED lighting, mobile equipment (such as laptops and cell phones), and transportation (such as cars and trains). The switch mode action of a converter’s switches forms the basis of its operation principle. The transient behaviour of the sources is crucial for converter design because the switches’ commutations produce extremely quick voltage and/or current transients. Voltage converters are quite advantageous in many different contexts. In addition to playing a crucial role in industries including renewable energy, communications, and medical equipment, voltage converters offer power adaptation, portability, flexibility, energy efficiency, and device protection. Any electrical equipment that can convert electric power between different forms is called a converter. A converter transforms one form of energy into another since there are two main kinds: direct current (DC) and alternating current (AC). Furthermore, when the absolute difference between the input and output voltages is lower, DC/DC converters perform better overall. Efficiency is calculated as a percentage for an electrical power conversion process by simply dividing the output power in watts by the input power in watts. The sun, tides, and wind are examples of infinite, naturally replenishing resources that provide renewable energy. Transportation, space and water heating and cooling, and electricity generation are all possible with renewable energy. We encourage contributions from a variety of fields and viewpoints, such as but not limited to: Design and Analysis of High-Efficiency Power Electronics Converters for Renewable Energy Systems. LIST OF TOPICS: · A new high-gain boost converter is designed and analysed for use in renewable energy systems. · Reliability and power electronics in renewable energy systems. · A novel DC/DC converter with excellent efficiency and step-up for use in renewable energy applications. · Multilevel flying-capacitor DC/DC converter with high efficiency for distributed renewable energy applications. · In systems that use renewable energy, power electronics should be designed for dependability. · Technology for power electronics in large-scale renewable energy production. · An essential technology for renewable energy systems is power electronics. · High-step-up, high-efficiency interleaved converter for renewable energy systems equipped with a voltage multiplier module. · The essential technology for integrating renewable energy systems is power electronics. · Power electronics and green energy system control. · A converter design that is low-stress and optimal for renewable energy systems. Induction generator design and analysis for renewable energy systems.
INSTRUCTIONS TO AUTHORS ARE AT: https://www.newmaterials.ca/instructions-for-authors/ Communications and send the manuscripts to: ahmedalmansur@outlook.com Or To: JNMES@polymtl.ca; Please add the special issue title on each document of correspondence including the manuscripts to be submitted. The submitted manuscripts should not have been previously published, nor should they be currently under consideration for publication elsewhere. IMPORTANT DATES • Manuscript submissions due: 2026-07-30 • First round of reviews completed: 2025-09-31 • Revised manuscripts due: 2026-11-31 • Final manuscripts due: 2027-0-15 |