Relevant bibliographies by topics / Power Electronics and energy conversion

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  1. Journal articles

Academic literature on the topic 'Power Electronics and energy conversion'

Author: Grafiati
Published: 6 September 2023

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Journal articles on the topic "Power Electronics and energy conversion"

1

Ramya, M. V., G. Ramya, V. Thiruburasundari, and N. Ramadevi. "Recent Trends in Power Electronics for Renewable energy Systems." March 2022 4, no. 1 (2022): 57–64. http://dx.doi.org/10.36548/jeea.2022.1.006.

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The complete world is focused on renewable power to reduce the global energy issue. Power electronic based energy conversion is being used extensively to improve the efficiency of the renewable energy conversion. It has a significant impact on the control and interface of renewable energy systems with both the network and stand-alone applications. As a result, increasing attention is being placed on the design and implementation of power converters. This study discusses the renewable energy systems (wind and solar) and the features of their energy conversion. The fundamental principles underlying their operations are discussed, as well as their recent technological advancements. It is a fact that power electronics is critical for interfacing and thus improving the system capacity.
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2

Ramya, M. V., G. Ramya, V. Thiruburasundari, and N. Ramadevi. "Recent Trends in Power Electronics for Renewable energy Systems." March 2022 4, no. 1 (2022): 57–64. http://dx.doi.org/10.36548/jeea.2022.1.006.

Full text
Abstract:
The complete world is focused on renewable power to reduce the global energy issue. Power electronic based energy conversion is being used extensively to improve the efficiency of the renewable energy conversion. It has a significant impact on the control and interface of renewable energy systems with both the network and stand-alone applications. As a result, increasing attention is being placed on the design and implementation of power converters. This study discusses the renewable energy systems (wind and solar) and the features of their energy conversion. The fundamental principles underlying their operations are discussed, as well as their recent technological advancements. It is a fact that power electronics is critical for interfacing and thus improving the system capacity.
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3

Ramya, M. V., G. Ramya, V. Thiruburasundari, and N. Ramadevi. "Recent Trends in Power Electronics for Renewable energy Systems." March 2022 4, no. 1 (2022): 57–64. http://dx.doi.org/10.36548/jeea.2022.1.006.

Full text
Abstract:
The complete world is focused on renewable power to reduce the global energy issue. Power electronic based energy conversion is being used extensively to improve the efficiency of the renewable energy conversion. It has a significant impact on the control and interface of renewable energy systems with both the network and stand-alone applications. As a result, increasing attention is being placed on the design and implementation of power converters. This study discusses the renewable energy systems (wind and solar) and the features of their energy conversion. The fundamental principles underlying their operations are discussed, as well as their recent technological advancements. It is a fact that power electronics is critical for interfacing and thus improving the system capacity.
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4

Rocha, J. E., and W. D. C. Sanchez. "The Energy Processing by Power Electronics and its Impact on Power Quality." International Journal of Renewable Energy Development 1, no. 3 (2012): 99. http://dx.doi.org/10.14710/ijred.1.3.99-105.

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This paper discusses the electrical architectures adopted in wind turbines and its impact on the harmonic flux at the connected electric network. The integration of wind electric generators with the power grid needs energy processing by power electronics. It shows that different types of wind turbine generator systems use different types of electronic converters. This work provides a discussion on harmonic distortion taking place on the generator side, as well as in the power grid side. Keywords: grid connection, harmonic distortion, power electronics and converters, wind energy conversion systems, wind power, wind technology, wind turbines
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5

Okundamiya, Michael S. "Power Electronics for Grid Integration of Wind Power Generation System." Journal of Communications Technology, Electronics and Computer Science 9 (December 27, 2016): 10. http://dx.doi.org/10.22385/jctecs.v9i0.129.

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The rising demands for a sustainable energy system have stimulated global interests in renewable energy sources. Wind is the fastest growing and promising source of renewable power generation globally. The inclusion of wind power into the electric grid can severely impact the monetary cost, stability and quality of the grid network due to the erratic nature of wind. Power electronics technology can enable optimum performance of the wind power generation system, transferring suitable and applicable energy to the electricity grid. Power electronics can be used for smooth transfer of wind energy to electricity grid but the technology for wind turbines is influenced by the type of generator employed, the energy demand and the grid requirements. This paper investigates the constraints and standards of wind energy conversion technology and the enabling power electronic technology for integration to electricity grid.
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6

Saponara, Sergio, and Lucian Mihet-Popa. "Energy Storage Systems and Power Conversion Electronics for E-Transportation and Smart Grid." Energies 12, no. 4 (2019): 663. http://dx.doi.org/10.3390/en12040663.

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The special issue “Energy Storage Systems and Power Conversion Electronics for E-Transportation and Smart Grid” on MDPI Energies presents 20 accepted papers, with authors from North and South America, Asia, Europe and Africa, related to the emerging trends in energy storage and power conversion electronic circuits and systems, with a specific focus on transportation electrification and on the evolution of the electric grid to a smart grid. An extensive exploitation of renewable energy sources is foreseen for smart grid as well as a close integration with the energy storage and recharging systems of the electrified transportation era. Innovations at both algorithmic and hardware (i.e., power converters, electric drives, electronic control units (ECU), energy storage modules and charging stations) levels are proposed.
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7

Kularatna, Nihal, Kasun Subasinghage, Kosala Gunawardane, Dilini Jayananda, and Thilanga Ariyarathna. "Supercapacitor-Assisted Techniques and Supercapacitor-Assisted Loss Management Concept: New Design Approaches to Change the Roadmap of Power Conversion Systems." Electronics 10, no. 14 (2021): 1697. http://dx.doi.org/10.3390/electronics10141697.

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All electrical and electronic devices require access to a suitable energy source. In a portable electronic product, such as a cell phone, an energy storage unit drives a complex array of power conversion stages to generate multiple DC voltage rails required. To optimize the overall end-to-end efficiency, these internal power conversions should waste minimal energy and deliver more to the electronic modules. Capacitors are one of the main component families used in electronics, to store and deliver electric charges. Supercapacitors, so called because they provide over a million-fold increase in capacitance relative to a traditional capacitor of the same volume, are enabling a paradigm shift in the design of power electronic converter circuits. Here we show that supercapacitors could function as a lossless voltage-dropping element in the power conversion stages, thereby significantly increasing the power conversion stage efficiency. This approach has numerous secondary benefits: it improves continuity of the supply, suppresses voltage surges, allows the voltage regulation to be electromagnetically silent, and simplifies the design of voltage regulators. The use of supercapacitors allows the development of a novel loss-circumvention theory with applicability to a wide range of supercapacitor-assisted (SCA) techniques. These include low-dropout regulators, transient surge absorbers, LED lighting for DC microgrids, and rapid energy transfer for water heating.
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8

Gedra, T. W., S. An, Q. H. Arsalan, and S. Ray. "Unified Power Engineering Laboratory for Electromechanical Energy Conversion, Power Electronics, and Power Systems." IEEE Transactions on Power Systems 19, no. 1 (2004): 112–19. http://dx.doi.org/10.1109/tpwrs.2003.820997.

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9

Fang, Jian, Xun Gai Wang, and Tong Lin. "Power Generation from Randomly Oriented Electrospun Nanofiber Membranes." Advanced Materials Research 479-481 (February 2012): 340–43. http://dx.doi.org/10.4028/www.scientific.net/amr.479-481.340.

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Randomly orientated electrospun poly(vinylidene fluoride) nanofiber membranes were directly used as active layers to make mechanical-to-electrical energy conversion devices. Without any extra poling treatment, the device can generate high electrical outputs upon receiving a mechanical impact. The device also showed long-term working stability and ability to drive electronic devices. Such a nanofiber membrane device may serve as a simple but efficient energy source for self-powered electronics.
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10

Miazga, Tomasz, Grzegorz Iwański, and Marcin Nikoniuk. "Energy Conversion System and Control of Fuel-Cell and Battery-Based Hybrid Drive for Light Aircraft." Energies 14, no. 4 (2021): 1073. http://dx.doi.org/10.3390/en14041073.

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The paper presents a power electronic conversion system and its control for a fuel cell and a battery-based hybrid drive system for a motor glider. The energy conversion system is designed in such a way that the fuel cell gives power equal to the electric drive power demand for horizontal flight, whereas during motor glider take-off and climbing, the fuel cell is supported by the battery. The paper presents the power demand related to the assumed mission profile, the main components of the hybrid drive system and its holistic structure, and details of power electronics control. Selected stationary experimental test results related to the energy conversion and drive system are shown. Some results related to the aircraft tests on a runway are presented.
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