Effect of the Number of Stages on the Performance of Savonius Vertical Axis Wind Turbines: Part II — Using Twisted Blades

Saad, Ahmed S.; Elwardany, Ahmed; El-Sharkawy, Ibrahim I.; Ahmed, Mahmoud

doi:10.1115/imece2020-23574

Cited by 6 publications

(3 citation statements)

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“…One of the parameters subject to change in blade design is the angle of twist [95]. The performance of a Savonius wind turbine was significantly improved by modifying the twist angle in a study of a two-stage Savonius rotor [101]. By using a two-stage Savonius rotor with twisted blades, an increase of 53.5% was achieved in the coefficient of power compared to the conventional single-stage rotor.…”

Section: Angle Of Twistmentioning

confidence: 99%

Recent Progress in Design and Performance Analysis of Vertical-Axis Wind Turbines—A Comprehensive Review

Didane,

Behery,

Al-Ghriybah

et al. 2024

Processes

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Vertical-axis wind turbines (VAWTs) are receiving more and more attention as they involve simple design, cope better with turbulence, and are insensitive to wind direction, which has a huge impact on their cost since a yaw mechanism is not needed. However, VAWTs still suffer from low conversion efficiency. As a result, tremendous efforts are being exerted to improve their efficiency, which mainly focus on two methods, regardless of whether the study is a CFD simulation, a field test, or a lab test experiment. An active approach involves modification of the rotor itself, such as the blade design, the angle, the trailing and leading edges, the inner blades, the chord thickness, the contra-rotating rotor, etc., while the second approach involves passive techniques where the flow is directed to optimally face the downwind rotor by mounting guiding vanes such as a diffuser or other shapes at the upwind position of the rotor. Among all the techniques undertaken, the counter-rotating wind turbine (CRWT) rotor technique seems to be the most effective, with an output comparable to that of horizontal-axis wind turbines (HAWTs), while the Savonius rotor has received more attention compared to other VAWT designs. Apart from technological issues, it has also been suggested that geographical issues, such as proper site siting of a wind turbine rotor at a particular location where a uniform flow can be guaranteed, are of paramount importance to ensure an effective conversion capacity of wind turbines. Thus, this study has successfully highlighted the latest improvements in augmentation methods and has established a solid foundation for future research aimed at improving the efficiency of VAWTs.

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Section: Angle Of Twistmentioning

confidence: 99%

Recent Progress in Design and Performance Analysis of Vertical-Axis Wind Turbines—A Comprehensive Review

Didane,

Behery,

Al-Ghriybah

et al. 2024

Processes

View full text Add to dashboard Cite

show abstract

“…One of the parameters change in blade design is the angle of twist [95]. The performance of a Savonius wind turbine was significantly improved by the twist angle in a study of two-stage Savonius rotor [101]. By using a two-stage Savonius rotor with twisted blades, an increase of 53.5% was achieved in the coefficient of power compared to the conventional singlestage rotor.…”

Section: Angle Of Twistmentioning

confidence: 99%

Recent Progress in Design and Performance Analysis of Vertical-Axis Wind Turbines (VAWTs) - A comprehensive Review

Didane,

Behery,

Al-Ghriybah

et al. 2024

Preprint

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Vertical-axis wind turbines (VAWTs) are receiving more and more attention as they involve simple design, cope better with turbulence and are insensitive to wind direction which has a huge impact on the cost since the yaw mechanism is not needed. However, VAWTs still suffer from low conversion efficiency. As a results tremendous efforts are exerted to improve its efficiency which mainly focus on two methods regardless of whether the study is a CFD simulation or a field test or lab test experiment. An active approach which involves the modification of the rotor itself such as the blade design, angle, trailing and leading edges, inner blades, chord thickness, contra-rotating rotor, etc. While the second approach involves passive techniques where the flow is directed to optimally face the downwind rotor by mounting a guiding vane such as a diffuser or other shapes at the upwind position of the rotor. Among all techniques undertaken, the CRWT rotor technique seems to be the most effective with an output even comparable to that of Horizontal Axis Wind Turbines (HAWT), while the Savonius rotor received more attention compared to other designs of VAWTs. Apart from technological issues, it was also suggested that geographical issues such as proper site siting of the wind turbine rotor at a particular location where a uniform flow could be guaranteed is of paramount importance to ensure an effective conversion capacity of wind turbines.

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“…In order to increase the Power Coefficient and self-starting capability of a multistage Savonius rotor, Ahmed et al [12] evaluated its aerodynamic performance. In their research, twisted blade Savonius rotors with one, two, three, and four stages were examined.…”

Section: Introductionmentioning

confidence: 99%

Comparison of Non-Overlap and Overlap Savonius Wind Turbines in the Physics Aspect Using Computational Fluid Dynamics Method

Nensy Irawan,

Yamashita,

Fujita

2024

J. Phys.: Conf. Ser.

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Wind energy has good potential as a renewable energy source. Savonius-type wind turbines can provide power generation at a low cost with minimal environmental impact. Due to its low efficiency, researchers were focused on increasing it through many methods, such as applying twisted-bladed, optimizing the blade shape, and applying overlap. Most researchers have studied the effects of overlap on Savonius blades only in terms of performance improvements. This study evaluates the effect of overlap on the Savonius blade from a physics perspective using the Computational Fluid Dynamics method to get a new approach based on the improvement. The models are 2-bladed Savonius with non-overlap and 0.2 overlap. The main software used is Ansys Student 2023 R2. The turbulent model chosen is a realizable k- enhanced wall treatment. Then, pressure and velocity coupling were done using SIMPLE: 2nd order upwind, 1st order implicit. As a result, the overlap model has a higher reverse flow but lower pressure for all Tip Speed Ratio. Another finding shows that turbulent kinetic energy decreases with overlap. For the non-overlap model, the amount of turbulence is greater downstream, which causes vortices to form and lowers turbine performance. So, the effects of the overlap blade result in higher average Torque Coefficient than non-overlap.

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Effect of the Number of Stages on the Performance of Savonius Vertical Axis Wind Turbines: Part II — Using Twisted Blades

Cited by 6 publications

References 0 publications

Recent Progress in Design and Performance Analysis of Vertical-Axis Wind Turbines—A Comprehensive Review

Recent Progress in Design and Performance Analysis of Vertical-Axis Wind Turbines—A Comprehensive Review

Recent Progress in Design and Performance Analysis of Vertical-Axis Wind Turbines (VAWTs) - A comprehensive Review

Comparison of Non-Overlap and Overlap Savonius Wind Turbines in the Physics Aspect Using Computational Fluid Dynamics Method

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