Numerical Simulation of the Flow around a Straight Blade Darrieus Water Turbine

Laı́n, Santiago; Cortés, Pablo; López, Omar D.

doi:10.3390/en13051137

Cited by 15 publications

(9 citation statements)

References 37 publications

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“…profiles were used (see references [5,21,33,34]), this interaction was very strong, w directly affected the generated power of the turbine. Although both techniques pred the same behavior of the vorticity, the overset mesh presented a higher resolution, d of the vortices, and unsteadiness of the flow in the near and far wake.…”

Section: Numerical Resultsmentioning

confidence: 99%

Comparison of Sliding and Overset Mesh Techniques in the Simulation of a Vertical Axis Turbine for Hydrokinetic Applications

Mejia

Escorcia

et al. 2021

Processes

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The application of Computational Fluid Dynamics (CFD) to energy-related problems has increased in the last decades in both renewable and conventional energy conversion processes. In recent years, the application of CFD in the study of hydraulic, marine, tidal, and hydrokinetic turbines has focused on the understanding of the details of the complex turbulent flow and also in improving the prediction of the performance of these devices. There are several complexities involved in the simulation of Vertical Axis Turbine (VAT) for hydrokinetic applications. One of them is the necessity of a dynamic mesh model. Typically, the model used in the simulation of these devices is the sliding mesh technique, but in recent years the fast development of the overset (also known as chimera) mesh technique has caught the attention of the academic community. In the present paper, a comparison between these two techniques is done in order to establish their advantages and disadvantages in the two-dimensional simulation of vertical axis turbines. The comparison was done not only for the prediction of performance parameters of the turbine but also for the capabilities of the models to capture complex flow phenomena in these devices and computational costs.

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Section: Numerical Resultsmentioning

confidence: 99%

Comparison of Sliding and Overset Mesh Techniques in the Simulation of a Vertical Axis Turbine for Hydrokinetic Applications

Mejia

Escorcia

et al. 2021

Processes

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“…The most relevant metrics of each mesh are summarized in Table 2 . The coarse mesh was built based on reference [ 1 ]; for the fine mesh, the density of elements near the walls of each blade was increased.…”

Section: Geometry and Meshmentioning

confidence: 99%

“…In the analysis, incompressible and isothermal flow is considered, gravitational effects are neglected, and the water is assumed as a Newtonian fluid. Therefore, the governing equations correspond to the averaged mass and momentum conservation equations (Unsteady Reynolds Averaged Navier Stokes or URANS equations) coupled with the k-ω SST turbulence model, while the problem is solved in a transient state, based on the references [ 1 , 18 , 24 ]. Figures 4 and 5 show the boundary conditions in the background and rotational domains, respectively, and Table 5 shows the operational parameters of the simulation.…”

Section: Computational Set-upmentioning

confidence: 99%

“…CFWTs allow energy to be extracted independently of the flow direction, this is an important characteristic of these turbines when are compared to AFWTs. However, CFWTs are less efficient than AFWTs because the flow in CFWTs becomes unsteady and is characterized by the shedding of vortices in certain azimuthal positions of the turbine that interact downstream with the blades [ 1 ].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Synthetic jets as a flow control device for performance enhancement of vertical axis hydrokinetic turbines: A 3D computational study

Botero

Ratkovich

Laı́n

et al. 2022

Heliyon

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“…Shi et al studied the internal flow and performance of the axial flow pump and found that the main part of the pump for energy conversion is the front third of the impeller and the energy conversion capacity of the impeller near the rim is stronger than that of the hub [32,33]. Laín et al revealed that the torque transferred from the fluid to each blade for the Darrieus water turbine was mainly in the upstream semicircle, while such a transfer was very small in the downstream semicircle, and the peak value reduces with the increase of the rotational speed for each blade [34].…”

Section: Introductionmentioning

confidence: 99%

Performance Characteristics in Runner of an Impulse Water Turbine with Splitter Blade

et al. 2021

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The impulse water turbine is a promising energy conversion device that can be used as mechanical power or a micro hydro generator, and its application can effectively ease the current energy crisis. This paper aims to clarify the mechanism of liquid acting on runner blades, the hydraulic performance, and energy conversion characteristics in the runner domain of an impulse water turbine with a splitter blade by using experimental tests and numerical simulations. The runner was divided into seven areas along the flow direction, and the power variation in the runner domain was analyzed to reflect its energy conversion characteristics. The obtained results indicate that the critical area of the runner for doing the work is in the front half of the blades, while the rear area of the blades does relatively little work and even consumes the mechanical energy of the runner to produce negative work. The high energy area is concentrated in the flow passage facing the nozzle. The energy is gradually evenly distributed from the runner inlet to the runner outlet, and the negative energy caused by flow separation with high probability is gradually reduced. The clarification of the energy conversion performance is of great significance to improve the design of impulse water turbines.

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Numerical Simulation of the Flow around a Straight Blade Darrieus Water Turbine

Cited by 15 publications

References 37 publications

Comparison of Sliding and Overset Mesh Techniques in the Simulation of a Vertical Axis Turbine for Hydrokinetic Applications

Comparison of Sliding and Overset Mesh Techniques in the Simulation of a Vertical Axis Turbine for Hydrokinetic Applications

Synthetic jets as a flow control device for performance enhancement of vertical axis hydrokinetic turbines: A 3D computational study

Performance Characteristics in Runner of an Impulse Water Turbine with Splitter Blade

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