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

Omar D Lopez Mejia,Santiago Laín,Oscar E Mejia,Fabian Suarez,Karol M Escorcia

doi:10.3390/pr9111933

Omar D Lopez Mejia, Santiago Laín + Show 3 more

Open Access

https://doi.org/10.3390/pr9111933

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Abstract

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.

Highlights

Due to the global concern related to climate change, some worldwide challenges and international warnings revolve around the usage of fossil fuels
The most common computational technique used in the simulation of Vertical Axis Turbines (VAT) is Computational Fluid Dynamics (CFD) in which the governing equations of the dynamics of flow are solved in a computational domain that needs to be discretized in elements (Control volumes)
The variable used for the convergence analysis was the total torque generated by the of it12 which was computed as an average in the last (10th) rotation of the turbine. 5As is shown in Figure 5, the total torque had a periodic evolution in time with three peaks per revolution

Summary

Introduction

Due to the global concern related to climate change, some worldwide challenges and international warnings revolve around the usage of fossil fuels. The most common are performed in scale prototypes either in water tunnels/channels [5,6,7] or towing tanks [8,9,10]. These experimental techniques require large-scale facilities and precise measurement systems, which, in general, are expensive. The most common computational technique used in the simulation of Vertical Axis Turbines (VAT) is Computational Fluid Dynamics (CFD) in which the governing equations of the dynamics of flow are solved in a computational domain that needs to be discretized in elements (Control volumes)

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