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Ech-Charqaouy, Nizar, Ech-Charqaouy, Sidi Salah, Boulezhar, Abdelkader, Ech-Charqaouy, Amjad, Mihramane, Redouane. (1404). Solar-Wind Complementarity and Vortex Bladeless Turbines: A Review of VIV-Based Micro-Wind Systems for Distributed Renewable Energy. , 11(1), 2867-2890. doi: 10.22059/jser.2026.404353.1654
Nizar Ech-Charqaouy; Sidi Salah Ech-Charqaouy; Abdelkader Boulezhar; Amjad Ech-Charqaouy; Redouane Lekbir Mihramane. "Solar-Wind Complementarity and Vortex Bladeless Turbines: A Review of VIV-Based Micro-Wind Systems for Distributed Renewable Energy". , 11, 1, 1404, 2867-2890. doi: 10.22059/jser.2026.404353.1654
Ech-Charqaouy, Nizar, Ech-Charqaouy, Sidi Salah, Boulezhar, Abdelkader, Ech-Charqaouy, Amjad, Mihramane, Redouane. (1404). 'Solar-Wind Complementarity and Vortex Bladeless Turbines: A Review of VIV-Based Micro-Wind Systems for Distributed Renewable Energy', , 11(1), pp. 2867-2890. doi: 10.22059/jser.2026.404353.1654
Ech-Charqaouy, Nizar, Ech-Charqaouy, Sidi Salah, Boulezhar, Abdelkader, Ech-Charqaouy, Amjad, Mihramane, Redouane. Solar-Wind Complementarity and Vortex Bladeless Turbines: A Review of VIV-Based Micro-Wind Systems for Distributed Renewable Energy. , 1404; 11(1): 2867-2890. doi: 10.22059/jser.2026.404353.1654

Solar-Wind Complementarity and Vortex Bladeless Turbines: A Review of VIV-Based Micro-Wind Systems for Distributed Renewable Energy

Journal of Solar Energy Research
دوره 11، شماره 1، فروردین 2026، صفحه 2867-2890    اصل مقاله (1.04 M)
نوع مقاله: Review Article
شناسه دیجیتال (DOI): 10.22059/jser.2026.404353.1654
نویسندگان
Nizar Ech-Charqaouy* ؛ Sidi Salah Ech-Charqaouy؛ Abdelkader Boulezhar؛ Amjad Ech-Charqaouy؛ Redouane Lekbir Mihramane
Department of Physics, Faculty of Sciences Ain Chock (FSAC), Hassan II University of Casablanca, Morocco
چکیده
Vortex bladeless turbines (VBTs), which extract energy from vortex-induced vibrations (VIV), represent a promising class of micro-wind generators characterized by low acoustic impact, simple mechanics, and minimal wake interactions. This review consolidates advances reported between 2018 and 2025, covering Strouhal-driven shedding mechanisms, nonlinear lock-in dynamics, and recent developments in CFD-FSI simulation and reduced-order modeling. The analysis formalizes aerodynamic forcing and resonance-based power extraction, emphasizing how geometry, damping, and effective mass govern the stability, bandwidth, and durability of the oscillatory response. Progress in materials engineering - such as high-modulus composites, hybrid piezoelectric–electromagnetic converters, and tunable-stiffness architectures - strengthens fatigue resistance under harsh desert or coastal climates.
Performance evaluation is synthesized using IEC-inspired indicators and compared with conventional small HAWT and VAWT technologies. Adaptive resonance-tracking concepts, including sliding-mass systems and semi-active stiffness modules, are reviewed for maintaining synchronization under transient wind inflows. Owing to their inherently weak wake, VBTs support compact arrays and AI-assisted optimization strategies. Finally, the review discusses how the nocturnal wind profile characteristic of arid regions enables VBTs to complement daytime photovoltaic production, supporting hybrid microgrids. Key research needs include endurance testing, standardized certification, and transparent LCOE frameworks for future multi-kilowatt VBT deployment.
کلیدواژه‌ها
Vortex Bladeless Turbines؛ Vortex-Induced Vibrations؛ Solar-Wind Hybrid Systems؛ Distributed Renewable Microgrids؛ CFD-FSI Modeling
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