Numerical study of straight-bladed Darrieus-type tidal turbine

Yong Ming Dai, Wei Haur Lam

Research output: Contribution to journalArticlepeer-review

Abstract

This paper presents developments in numerical simulations of a cross-flow vertical-axis marine current turbine (straight-bladed Darrieus type) with particular emphasis on rotor-performance prediction and hydrodynamic loads for structural design calculations. This study initially used theoretical double-multiple-streamtube models, followed by physical testing on a scaled-down model turbine and primarily numerical simulations. Numerical investigations of a proposed full-scale turbine(power coefficient, blade loads and flow behaviour) were undertaken using the developed computational models. The turbine design was studied using a time-accurate Reynolds-averaged Navier–Stokes (RANS) commercial solver. A transient-rotor-stator model with a moving mesh technique was used to capture the change in flow field at a particular time step. A shear stress-transport k-omega turbulence model was used to model turbulent features of the flow. The numerical results show good agreement with experimental measurements and the theoretical double-multiple-streamtube model. Turbine sensitivity to parametric variations was also demonstrated in the full-scale numerical study. This work concludes that the developed model can effectively predict hydrodynamic performance and structural design blade loads of a vertical-axis marine current turbine.
Original languageEnglish
Pages (from-to)67-76
Number of pages0
JournalProceedings of the Institution of Civil Engineers, Energy
Volume162
Issue number0
DOIs
Publication statusPublished - May 2009

Keywords

  • mathematical modelling
  • Marine Current Turbine
  • CFD
  • Vertical Axis
  • Tidal Turbine
  • Darrieus

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