Using Experimentally Validated Navier-Stokes CFD to Minimize Tidal Stream Turbine Power Losses Due to Wake/Turbine Interactions

Tidal stream turbines fixed on the seabed can harness the power of tides at locations where the bathymetry and/or coastal geography result in high kinetic energy levels of the flood and/or neap currents. In large turbine arrays, however, avoiding interactions between upstream turbine wakes and downstream turbine rotors may be hard or impossible, and, therefore, tidal array layouts have to be designed to minimize the power losses caused by these interactions. For the first time, using Navier-Stokes computational fluid dynamics simulations which model the turbines with generalized actuator disks, two sets of flume tank experiments of an isolated turbine and arrays of up to four turbines are analyzed in a thorough and comprehensive fashion to investigate these interactions and the power losses they induce. Very good agreement of simulations and experiments is found in most cases. The key novel finding of this study is the evidence that the flow acceleration between the wakes of two adjacent turbines can be exploited not only to increase the kinetic energy available to a turbine working further downstream in the accelerated flow corridor, but also to reduce the power losses of said turbine due to its rotor interaction with the wake produced by a fourth turbine further upstream. By making use of periodic array simulations, it is also found that there exists an optimal lateral spacing of the two adjacent turbines, which maximizes the power of the downstream turbine with respect to when the two adjacent turbines are absent or further apart. This is accomplished by trading off the amount of flow acceleration between the wakes of the lateral turbines, and the losses due to shear and mixing of the front turbine wake and the wakes of the two lateral turbines.

[1]  F. Menter Two-equation eddy-viscosity turbulence models for engineering applications , 1994 .

[2]  Laith A. J. Zori,et al.  NavierStokes Calculations of RotorAirframe Interaction in Forward Flight , 1995 .

[3]  E. S. Politis,et al.  Modelling and Measuring Flow and Wind Turbine Wakes in Large Wind Farms Offshore , 2009, Renewable Energy.

[4]  Seung Ho Lee,et al.  A numerical study for the optimal arrangement of ocean current turbine generators in the ocean current power parks , 2010 .

[5]  Fergal O. Rourke,et al.  Tidal Energy Update 2009 , 2010, Renewable Energy.

[6]  L. E. Myers,et al.  Experimental analysis of the flow field around horizontal axis tidal turbines by use of scale mesh disk rotor simulators , 2010 .

[7]  L. E. Myers,et al.  An experimental investigation simulating flow effects in first generation marine current energy converter arrays , 2012 .

[8]  T. Stallard,et al.  Interactions between tidal turbine wakes: experimental study of a group of three-bladed rotors , 2011, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[9]  Jun Li,et al.  Numerical investigations of the effects of different arrays on power extractions of horizontal axis tidal current turbines , 2013 .

[10]  Paul Mycek,et al.  Experimental study of the turbulence intensity effects on marine current turbines behaviour. Part I: One single turbine , 2014 .

[11]  Paul Mycek,et al.  Experimental study of the turbulence intensity effects on marine current turbines behaviour. Part II: Two interacting turbines , 2014 .

[12]  Alison Williams,et al.  Planning tidal stream turbine array layouts using a coupled blade element momentum – computational fluid dynamics model , 2014 .

[13]  Ross Vennell,et al.  Designing large arrays of tidal turbines: A synthesis and review , 2015 .

[14]  Takafumi Nishino,et al.  Investigation of tidal turbine array tuning using 3D Reynolds-Averaged Navier–Stokes Simulations , 2015 .

[15]  Colin J. Cotter,et al.  Simulating tidal turbines with multi-scale mesh optimisation techniques , 2016 .

[16]  Giovanni Ferrara,et al.  Potential of the Virtual Blade Model in the analysis of wind turbine wakes using wind tunnel blind tests , 2017 .

[17]  Ming Li,et al.  3D modelling of impacts from waves on tidal turbine wake characteristics and energy output , 2017 .

[18]  Longbin Tao,et al.  Three dimensional tidal turbine array simulations using OpenFOAM with dynamic mesh , 2018 .

[19]  T. Stallard,et al.  Actuator-line CFD modelling of tidal-stream turbines in arrays , 2016, Journal of Ocean Engineering and Marine Energy.

[20]  Longbin Tao,et al.  Experimental study of wake characteristics in tidal turbine arrays , 2018, Renewable Energy.

[21]  Magnus J. Harrold,et al.  Analysis of array spacing on tidal stream turbine farm performance using Large-Eddy Simulation , 2019, Journal of Fluids and Structures.

[22]  D. Groulx,et al.  Numerical study into horizontal tidal turbine wake velocity deficit: Quasi-steady state and transient approaches , 2019, Ocean Engineering.

[23]  Changhong Hu,et al.  An actuator line - immersed boundary method for simulation of multiple tidal turbines , 2019, Renewable Energy.

[24]  A. Kiprakis,et al.  Experimental Assessment of Flow, Performance, and Loads for Tidal Turbines in a Closely-Spaced Array , 2020, Energies.

[25]  A. Good,et al.  Wake field study of tidal turbines under realistic flow conditions , 2020 .

[26]  G. Germain,et al.  Three tidal turbines in interaction: An experimental study of turbulence intensity effects on wakes and turbine performance , 2020, Renewable Energy.