Journal of Advanced Marine Engineering and Technology

The Korean Society of Marine Engineering (한국마린엔지니어링학회)
권호 표지
DOI QR코드

DOI QR Code

A fundamental study on velocity restoration for tidal farm

  • Hoang, A.D. (Division of Marine Engineering, Graduate School, Mokpo National Maritime University) ;
  • Yang, C.J. (Division of Marine Engineering, Mokpo National Maritime University)
  • Received : 2012.09.28
  • Accepted : 2013.04.26
  • Published : 2013.05.31
Download PDF
⟨ Previous Next ⟩

Abstract

With the worldwide trend of controlling the utilization of fossil fuels inducing global climate change, many efforts will have to be made on securing a sustainable energy supply. Tidal current is a concentrated form of gravitational energy, its resource is significant, but limited locations. To effectively capture tidal current energy from the sea, a group of tidal turbines should be formed and positioned with optimal size and spacing for absorbing from multiple points. Thus, the flow field including turbines becomes a huge domain, a so-called tidal farm. It can be very convenient technically and economically if a whole turbine farm is simulated by means of actuator disc thoery. So, the analysis method using actuator discs coupled with a solution of Reynolds Averaged Navier-Stokes (RANS) equations is adopted for actual tidal turbines. Actuator discs have regions where similar forces imposed by actual turbines are applied to a flow. As working in group formation, turbines naturally have interaction effects on one another. Therefore, the present paper investigate the evaluation on the operating performance of tidal farm in terms of the mutual influence among turbine units with various lateral and longitudinal spacing. Authors expect that results of the present study contribute to the development of tidal farm for the future potential energy.

Keywords

References

  1. Carbon Trust Hompage, Marine energy http://www.carbontrust.com/resources/reports/technology/marine-energy, Accessed September 28, 2013.
  2. L. Bai, R. R. G. Spence, and G. Dudziak, "Investigation of the influence of array arrangement and spacing on tidal energy converter (TEC) performance using a 3-dimentional CFD model", Proceeding of the 8th European Wave and Tidal Energy Conference, pp. 1-8, 2009.
  3. C. J. Yang, A. D. Hoang, and Y. H. Lee, "An evaluation for predicting the far wake of tidal turbines positioned in array at different longitudinal spaces", Journal of the Korean Society of Marine Engineering, vol. 36, no. 3, pp. 358-367, 2012. https://doi.org/10.5916/jkosme.2012.36.3.358
  4. J. Whelan, M. Thomson, J. M. R. Graham, and J. Peiro, Modeling of Free Surface Proximity and Wave-Induced Velocities Around a Horizontal Axis Tidal Stream Turbine, Technical Report CS-TR-12-98, Department of Aeronautics, Imperial College, UK, 2012.
  5. G. T. Houlsby, S. Draper, and M. L. G. Oldfield, Application of Linear Momentum Actuator Disc Theory to Open Channel Flow, University of Oxford, Report No. 2296/08, 2008.
  6. M. E. Harrison, W. M. J. Batten, L. E. Myers, and A. S. Bahaj, "Comparison between CFD simulations and experiments for predicting the far wake of horizontal axis tidal turbines", IET Renew Power Generation, vol. 4, pp. 613-627, 2009.
  7. J. I. Whelan, J. M. R. Graham, and J. Peiró, "A free surface and blockage correction for tidal turbines", Journal of Fluid Mechanics, vol. 624, pp. 281-291, 2009. https://doi.org/10.1017/S0022112009005916
  8. ANSYS Incorporated, ANSYS CFX-Solver Theory Guide, 2009.
  9. W. Graebel, Advanced Fluid Mechanics, Academic Press, 2007.
  10. T. Burton, Wind Energy Handbook, John Wiley and Sons Press, 2001.

Cited by

  1. Hydrofoil selection and design of a 50W class horizontal axis tidal current turbine model vol.39, pp.8, 2015, https://doi.org/10.5916/jkosme.2015.39.8.856