Aerodynamic Performance Enhancement Using Active Flow Control on DU96-W-180 Wind Turbine Airfoil

Halawa, Amr M.; Elhadidi, Basman; Yoshida, Shigeo

doi:10.5109/1929723

Cited by 31 publications

(30 citation statements)

References 13 publications

(16 reference statements)

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“…A zone of dense mesh elements is created around the diffuser to capture the pressure gradient that occurs across it. Figure 4c shows inflation layers, which were also created around the diffuser walls to capture the boundary layer; a similar way was followed by Halawa et al 24) and Ibrahim et al 25) . The mesh elements everywhere else in the domain are unstructured 3D tetrahedral cells, created using Ansys meshing.…”

Section: Computational Domain Descriptionmentioning

confidence: 80%

Wind Lens Performance Investigation at Low Wind Speed

Takeyeldein¹,

Lazim²,

Ishak³

et al. 2020

Evergreen

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Section: Computational Domain Descriptionmentioning

confidence: 80%

Wind Lens Performance Investigation at Low Wind Speed

Takeyeldein¹,

Lazim²,

Ishak³

et al. 2020

Evergreen

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“…6 presents a comparison of the hydraulic gradient of the generalised Reynolds number on a circular pipe and spiral pipe. At low Re', the hydraulic gradient value decreased sharply until Re'=1x10 4 , especially for the circular pipes. Then, the growth occurred when the fluid flow enters the turbulent zone.…”

Section: Resultsmentioning

confidence: 95%

“…Two methods can be applied to obtain drag reduction, which directly relates to energy consumption reduction: active and passive control methods 4) . The active control method adds substances or additives through the working fluid 5,6) , while the passive control method tries to reduce drag by forming or reshaping a channel geometry or structure to obtain more effective flow 7,8) .…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation On The Spiral Pipe Performance For Particle-Laden Liquids

Yanuar¹,

Ibadurrahman²,

Pamitran³

et al. 2020

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Newtonian and non-Newtonian fluids are commonly transported with the piping system, but non-Newtonian fluids with particle-laden are more complicated to be transported due to various factors. A deposition is one of the problems that must be investigated due to affecting flow efficiency. The purpose of this study is to investigate the performance of 3-lobes spiral pipe in relationship with particles effect. The working fluid used had several variations of concentration weight (i.e. Cw 20%, 30% and 40%). Test pipes used had 1550 mm of length which consisted of a spiral pipe with P/Di=7 and a circular pipe with an inner diameter of 25.4 mm; both of the pipes were used to investigate the particles effect where the circular pipe for examining rheological of the working fluid. Slurry particles sized 1-5 μm in this study was obtained from the mud eruption at Semau Island, Kupang-Indonesia. By comparing both working fluids, the critical velocity observed in the spiral pipe was not as high as observed in the circular pipe, and thus the spiral pipe is more efficient to be used in slurry transportation from mud eruption area.

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“…Velocity, coefficient of lift, and total lift force are directly affected by the profile of foil 17) . The NACA 4412 design, which was rated by the National Advisory Committee on Aeronautics (NACA), was chosen as a model in this experiment because it has a relatively high lift coefficient at zero-degree angle of attack [23][24][25] .…”

Section: Design and Experimental Methodsmentioning

confidence: 99%

Analysis of the Use of Stern Foil on the High Speed Patrol Boat on Full Draft Condition

Syahrudin

Budiyanto²,

Murdianto

2020

Evergreen

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Currently in the ship design industry, especially for the patrol boat design and development, researchers continue to try to find designs with high efficiency and good performance. The use of stern foil technology by reducing ship resistance on ships is a way to increase ship performance. This Stern Foil technology has a similar working principle with hydrofoil, but Stern Foil is only located on the stern of the ship. By reducing the wet area at the stern of the ship, it will automatically reduce resistance and have an impact on the characteristics of the ship. The research on the application of Stern Foil was carried out on a 1-meter dimension ship model with a towing test method. The results of this research indicate a change in the characteristics of the ship, starting from the wave pattern created and there are reductions in the total resistance of the ship model, 24.84 % on 2 kg with Fn 1.2 and 1.27% on 3 kg with Fn 0.7-0.75.

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Aerodynamic Performance Enhancement Using Active Flow Control on DU96-W-180 Wind Turbine Airfoil

Cited by 31 publications

References 13 publications

Wind Lens Performance Investigation at Low Wind Speed

Wind Lens Performance Investigation at Low Wind Speed

Experimental Investigation On The Spiral Pipe Performance For Particle-Laden Liquids

Analysis of the Use of Stern Foil on the High Speed Patrol Boat on Full Draft Condition

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