Blade Number Effect for A Horizontal Axis River Current Turbine at A Low Velocity Condition Utilizing A Parametric Study with Mathematical Model of Blade Element Momentum

Balaka, Ridway; Rachman, Aditya; Delly, Jenny

doi:10.7763/jocet.2014.v2.79

Cited by 5 publications

(8 citation statements)

References 17 publications

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“…The gap between the machines' performances induces a couple of considerations. The first one involves the C p : as mentioned in Table 3, for the three blades turbine, it is 0.40, 6 meanwhile, as per Table 4, for the open centre one the C p is 0.45, 17 12.5% higher; secondly, the different flow speed (2.55 vs 2.67 m/s), related to the different installation depth, accounts a further 4.7%, so the whole difference between the turbines performances is about 18%, similar to the energy output (308 vs 362 MWh/year).…”

Section: Results and Considerationsmentioning

confidence: 99%

“…In position 1, the turbine hooks the rod. The new tidal stream, in the opposite direction, allows the rod to rotate so that the turbine is ready to work in the new direction, performing again the above described phases ( Figure 6), positions 6,7,8,9). Further details can be found in.…”

Section: Tide Reversal: Transientsmentioning

confidence: 99%

“…Although the environmental impact is still felt considerable and under deep investigation, these technologies achieved a satisfactory level of performance and reliability. ( Peter et all 4 ) investigated new potential sites in Scotland (2004), meanwhile in Reference 6, the authors take in consideration the river purposes. One of the examples of full study on a pilot power plants was published on 2006 by Polagye and Previsic 7 : a feasibility study, starting from site assessment up to the public utility network connection and cost analysis, treated on the performances of seabed tidal turbines, at Knik Arm, Alaska, demonstrating the suitability for small communities, at that time, and sustainability even toward the seasonal ice formation.…”

Section: Introductionmentioning

confidence: 99%

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Open center tidal turbine: How a new mooring system concept affects the performances

et al. 2020

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The huge manufacturing and installations costs, together with the adverse impact of the mooring systems and structures on the environment, flora and fauna have become one of the major constraints for the application of many marine technologies. An innovative mooring system coupled to an open centre turbine has been developed, adopting a full floating concept, which allows a kite like connection between the turbine and the coast. Replacing the huge underwater mooring structures with such kite flying system dramatically reduces the environmental impact and effects, meanwhile the lightweight open centre turbine coupled to this mooring system, assures a self-adaptive optimal orientation, achieving a new equilibrium arrangement at given depth and distance to the coast, following only the fluid dynamics rules. In addition, the synergy between the two machine components makes also suitable the adoption of low aspect ratio blades, characterized by lower specific loads, and leads to a reduction of the manufacturing cost. To optimize the kite concept, the connecting rope has been replaced with heavy and light nodes connected by tubular elements, where the light ones accommodate the deflectors to increase the lateral force responsible of the machine positioning, facilitating the machine transients, and manoeuvring and leading to improve the output reliability, reducing also the mooring line length. A case study shows that a 12 m diameter open centre turbine with the new mooring line produces, at Messina Strait site (Italy), an output of 362 MWh/year, 17.5% higher than, at same operating conditions, a classic 3 blades turbine moored on the seabed. It confirms the high suitability of this solution for marine purposes.

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Section: Results and Considerationsmentioning

confidence: 99%

Section: Tide Reversal: Transientsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Open center tidal turbine: How a new mooring system concept affects the performances

et al. 2020

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“…It was due to the blockage effect on ten blades number wind turbines which causes the rotation speed smaller about 27% than a turbine with five blades number. The decreasing in rotational speed causes a decrease in mechanical power produced by the axial flow wind turbine [12]. CP is a ratio between the mechanical power of a turbine and mechanical power contained in the airflow.…”

Section: Discussionmentioning

confidence: 99%

“…The blade numbers and the blade pitch angles were varied to obtain the maximum Cp and the maximum exhaust air recovery. The reason underlying the variation of the blades number and the blade pitch angles is because the addition of blades number can increase the torque and mechanical power followed by decreasing the value of cut-in speed and increasing starting torque from axial-flow wind turbine, while the change of blade pitch angle will affect the magnitude of drag and lift force generated by the blade so that the greater blade pitch angle, the lower resulting lift force, but the drag force will be even bigger [12][13][14].…”

Section: Introductionmentioning

confidence: 99%

Performance Evaluation of Axial Flow Wind Turbine Integrated with The Condenser

Santoso

Tjahjana

Widodo

2020

ARFMTS

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This study investigated the application of an axial flow wind turbine integrated with a condenser. The exhaust air from condenser was used to drive the wind turbine by a ducted turbine system. There were two parameters varied in this work: the blade number and the blade pitch angle. The blade number used was two blades, five blades, and ten blades, while the blade pitch angles were 5°, 10°, 15°, 20°, 30°, and 45°. The diameter of the wind turbine was 495 mm. The model of the condenser had a fan diameter of 600 mm and the range of the average air velocity of 2.01 m/s - 7.86 m/s. The maximum mechanical power was 10.72 W for air velocity of 7.86 m/s. The maximum power coefficient recorded was 0.38 for the tip speed ratio of 1.3 on the blade number of five blades and a pitch angle of 10°. The maximum exhaust air energy recovery was 13.64% of the power consumption of the condenser fan.

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