Study of horizontal axis tidal turbine performance and investigation on the optimum fixed pitch angle using CFD

Purpose The purpose of this paper is to design, investigate and optimize a horizontal axis tidal turbine (HATT) using computer-aided numerical simulation and computational fluid dynamics (CFD). This is the first step of research and development (R&D) for implementation in the Persian Gulf condition. To do so, suitable locations are reviewed. Then, the optimization is focused on determining the optimum fixed pitch angle (β) of a three-bladed HATT based on the widespread multiple reference frame (MRF) technique to calculate power and thrust coefficients at different operational rotating speeds. Design/methodology/approach To simplify the problem and reducing the computational costs due to cyclic symmetry only one blade, accordingly one-third of the whole computational domain is considered in the modeling. Due to flow’s nature involving rotating, separation and recirculation, a realizable κ-ε turbulence model with standard wall function is selected to capture flow characteristics influenced by the rotor and near the wall region. Simulations are conducted for two free-stream velocities, then compared with their dependencies through the dimensionless tip speed ratio (TSR) parameter. Findings The validation process of the simulations is carried out by the use of AeroDyn BEM code, which has been evaluated by comparing with two experimental data. As results, the highest coefficient of power is achieved at ß = 19.3° at TSR = 4 with the value around 0.41 and 0.816 for thrust coefficient. Furthermore, to comprehend the rotor’s performance and simulation method, flow characteristics due to the rise in angular velocity is discussed in detail. Moreover, the major phenomenon, cavitation occurrence, is also checked at the critical situation where it is found to be safe. Originality/value By comparing and evaluating the results to other HATTs, it implies that the proposed rotor of this study is feasible and proved by CFD evaluation at this step. However, the current rotor is awaiting a justification through experimental assessment.

[1]  Tahir Yavuz,et al.  Performance analysis of double blade airfoil for hydrokinetic turbine applications , 2012 .

[2]  Wenlong Tian,et al.  Design, test and numerical simulation of a low-speed horizontal axis hydrokinetic turbine , 2017, International Journal of Naval Architecture and Ocean Engineering.

[3]  Zhengwei Wang,et al.  Numerical simulation of cavitation for a horizontal axis marine current turbine , 2015 .

[4]  Daphne Maria O'Doherty,et al.  The impact of axial flow misalignment on a tidal turbine , 2017 .

[5]  A. Hadjadj,et al.  Boundary layer transition over a concave surface caused by centrifugal instabilities , 2018, Computers & Fluids.

[6]  Goodarz Ahmadi,et al.  Investigation of pollutant reduction by simulation of turbulent non-premixed pulverized coal combustion , 2014 .

[7]  Robert J. Poole,et al.  Non-dimensional scaling of tidal stream turbines , 2012 .

[8]  T. N. Croft,et al.  An enhanced disk averaged CFD model for the simulation of horizontal axis tidal turbines , 2017 .

[9]  Brenden P. Epps,et al.  Hydrokinetic energy conversion: Technology, research, and outlook , 2016 .

[10]  T. G. Thomas,et al.  Coarse resolution large‐eddy simulation of turbulent channel flows , 2001 .

[11]  Rezvan Alamian,et al.  Evaluation of technologies for harvesting wave energy in Caspian Sea , 2014 .

[12]  Jan Hofman,et al.  The potential of (waste)water as energy carrier , 2013 .

[13]  R. Shafaghat,et al.  Wave energy potential along the southern coast of the Caspian Sea , 2017 .

[14]  Hongwei Liu,et al.  Review on the blade design technologies of tidal current turbine , 2016 .

[15]  M. Shadloo,et al.  A parallel high-order compressible flows solver with domain decomposition method in the generalized curvilinear coordinates system , 2019, International Journal of Numerical Methods for Heat & Fluid Flow.

[16]  Ghislain Lartigue,et al.  Mesh adaptation for large‐eddy simulations in complex geometries , 2016 .

[17]  Blas Zamora,et al.  Tool development based on FAST for performing design optimization of offshore wind turbines: FASTLognoter , 2013 .

[18]  Andreas Uihlein,et al.  Wave and tidal current energy – A review of the current state of research beyond technology , 2016 .

[19]  Philip Sewell,et al.  Current tidal power technologies and their suitability for applications in coastal and marine areas , 2016 .

[20]  Anthony F. Molland,et al.  Power and thrust measurements of marine current turbines under various hydrodynamic flow conditions in a cavitation tunnel and a towing tank , 2007 .

[21]  Mark Z. Jacobson,et al.  Review of solutions to global warming, air pollution, and energy security , 2009 .

[22]  Mostafa Safdari Shadloo,et al.  Assessment of subgrid-scale modeling for large-eddy simulation of a spatially-evolving compressible turbulent boundary layer , 2017 .

[23]  Multiscale subgrid models of large eddy simulation for turbulent flows , 2016 .

[24]  M. Paraschivoiu,et al.  Large‐eddy simulation of a compressible free jet flow on unstructured elements , 2013 .

[25]  Tim Stallard,et al.  Design and manufacture of a bed supported tidal turbine model for blade and shaft load measurement in turbulent flow and waves , 2017 .

[26]  Gregorio Iglesias,et al.  Device interactions in reducing the cost of tidal stream energy , 2015 .

[27]  George A. Aggidis,et al.  Tidal range technologies and state of the art in review , 2016 .

[28]  A. Badarudin,et al.  Investigation of Heat Transfer Enhancement in a Forward-Facing Contracting Channel Using FMWCNT Nanofluids , 2014 .

[29]  Alireza Riasi,et al.  Design, analysis and predicting hydrokinetic performance of a horizontal marine current axial turbine by consideration of turbine installation depth , 2015 .

[30]  I. Afgan,et al.  CFD simulations of a full-scale tidal turbine: comparison of LES and RANS with field data , 2015 .

[31]  Ali Rashid,et al.  Status and potentials of tidal in-stream energy resources in the southern coasts of Iran: A case study , 2012 .

[32]  T. Stallard,et al.  Comparison of a RANS blade element model for tidal turbine arrays with laboratory scale measurements of wake velocity and rotor thrust , 2016 .

[33]  Ceri A. Morris,et al.  Evaluation of the swirl characteristics of a tidal stream turbine wake , 2016 .

[34]  Rezvan Alamian,et al.  Multi-Objective Optimization of a Pitch Point Absorber Wave Energy Converter , 2019, Water.

[35]  M. Ketabdari,et al.  Feasibility study on tidal and wave energy conversion in Iranian seas , 2015 .

[36]  Daphne Maria O'Doherty,et al.  The effect of tidal flow directionality on tidal turbine performance characteristics , 2015 .

[37]  Mohamed Machmoum,et al.  Attraction, Challenge and Current Status of Marine Current Energy , 2018, IEEE Access.

[38]  Ju Hyun Lee,et al.  Computational methods for performance analysis of horizontal axis tidal stream turbines , 2012 .

[39]  Bang-Fuh Chen,et al.  On design and performance prediction of the horizontal-axis water turbine , 2012 .

[40]  Mostafa Safdari Shadloo,et al.  Direct Numerical Simulation of flow instabilities over Savonius style wind turbine blades , 2017 .

[41]  Emad Sadeghinezhad,et al.  Numerical simulation of laminar to turbulent nanofluid flow and heat transfer over a backward-facing step , 2014, Appl. Math. Comput..

[42]  Gregorio Iglesias,et al.  Performance assessment of Tidal Stream Turbines: A parametric approach , 2013 .

[43]  Mohamed Benbouzid,et al.  Developments in large marine current turbine technologies – A review , 2017 .

[44]  Jing Liu,et al.  Wake field studies of tidal current turbines with different numerical methods , 2016 .

[45]  Thorsten Stoesser,et al.  Hydrodynamic loadings on a horizontal axis tidal turbine prototype , 2017 .

[46]  Beom-Soo Hyun,et al.  Numerical and experimental investigation on the performance of three newly designed 100 kW-class tidal current turbines , 2012 .

[47]  Z. L. Jiang,et al.  The deployment of the first tidal energy capture system in Taiwan , 2018 .

[48]  Goodarz Ahmadi,et al.  Investigation of nanofluid mixed convection in a shallow cavity using a two-phase mixture model , 2014 .

[49]  I. Afgan,et al.  Turbulent flow and loading on a tidal stream turbine by LES and RANS , 2013 .

[50]  Rezvan Alamian,et al.  Feasibility study of wave energy harvesting along the southern coast and islands of Iran , 2019, Renewable Energy.

[51]  Bingwen Liu,et al.  Design and hydrodynamic analysis of horizontal axis tidal stream turbines with winglets , 2017 .

[52]  C. Nayeri,et al.  QBLADE : AN OPEN SOURCE TOOL FOR DESIGN AND SIMULATION OF HORIZONTAL AND VERTICAL AXIS WIND TURBINES , 2013 .

[53]  S. Tatum,et al.  CFD modelling of a tidal stream turbine subjected to profiled flow and surface gravity waves , 2016 .

[54]  Tahir Yavuz,et al.  Hydrodynamics performance of hydrofoil-slat arrangements in 3D analysis , 2013 .

[55]  Guojun Li,et al.  Numerical analysis of the hydrodynamic performance and wake field of a horizontal axis tidal current turbine using an actuator surface model , 2015 .

[56]  Mostafa Safdari Shadloo,et al.  Large-eddy simulation of a spatially-evolving supersonic turbulent boundary layer at M∞=2 , 2018 .

[57]  R. Panahi,et al.  A comprehensive insight into tidal stream energy farms in Iran , 2017 .