Abstract
The energy crisis of the modern era may be overcome by hydrokinetic energy, the most readily and free source of energy available, to provide basic electricity needs to remote and urban areas at a low cost. The kinetic energy of flowing water at low speed could be extracted effectively by designing an appropriate design of the blade, as the turbine’s performance is dependent upon the shape of its blade. In this study, the wind turbine model with some modifications was used to design a blade for the hydrokinetic turbine. The horizontal axis turbine model with propeller type configuration was selected for obtaining higher efficiency. The optimum hydrofoil was selected and designed with an optimal twist angle for the maximum energy extraction process. The model was designed in three-dimensional (3D) modeling software solidworks, and then the power analysis was carried out through numerical simulations using the commercial computational fluid dynamics package ansys fluent. The power output was analyzed with a different number of blades, and performance curves were generated for the most efficient system. The calculations exhibited that for 1.5 m/s rated speed of water with the rotor diameter of 0.6096 m provides the rated power of approximately 150 W at 110 RPMs. The power curve of the turbine was analyzed for the selection of an efficient Permanent Magnet Synchronous Generator, and a direct drive system was preferred to reduce the weight and losses. The turbine model was 3D printed for testing and experimentation. The analytical efficiency calculated was 30.52%, and the experimental efficiency achieved was 28.24%. This study shows that the optimum design of hydrokinetic turbines could be integrated into series to provide energy to remote areas where the construction of dams and other resources are not available.
Issue Section:
Energy Systems Analysis
References
1.
Tunio
, I. A.
, Shah
, M. A.
, Hussain
, T.
, Harijan
, K.
, Mirjat
, N. H.
, and Memon
, A. H.
, 2020
, “Investigation of Duct Augmented System Effect on the Overall Performance of Straight Blade Darrieus Hydrokinetic Turbine
,” Renew. Energy
, 153
, pp. 143
–154
. 2.
Mohammadi
, S.
, Hassanalian
, M.
, Arionfard
, H.
, and Bakhtiyarov
, S.
, 2020
, “Optimal Design of Hydrokinetic Turbine for Low-Speed Water Flow in Golden Gate Strait
,” Renew. Energy
, 150
, pp. 147
–155
. 3.
Mon
, E. E.
, 2019
, “Design of Low Head Hydrokinetic Turbine
,” Int. J. Trend Sci. Res. Dev.
, 3
(3
), pp. 2106
–2109
. 4.
Riglin
, J. D.
, 2016
, Design, Modeling and Prototyping of a Hydrokinetic Turbine Unit for River Application
, Theses and Dissertations 2783, Lehigh University
, 180
. http://preserve.lehigh.edu/etd/27835.
Motley
, M. R.
, and Barber
, R. B.
, Apr. 2014
, “Passive Control of Marine Hydrokinetic Turbine Blades
,” Compos. Struct.
, 110
(1
), pp. 133
–139
. 6.
Anyi
, M.
, and Kirke
, B.
, 2011
, “Hydrokinetic Turbine Blades: Design and Local Construction Techniques for Remote Communities
,” Energy Sustainable Dev.
, 15
(3
), pp. 223
–230
. 7.
Lago
, L. I.
, Ponta
, F. L.
, and Chen
, L.
, 2010
, “Advances and Trends in Hydrokinetic Turbine Systems
,” Energy Sustainable Dev.
, 14
(4
), pp. 287
–296
. 8.
Hu
, Z.
, and Du
, X.
, 2012
, “Reliability Analysis for Hydrokinetic Turbine Blades
,” Renew. Energy
, 48
, pp. 251
–262
. 9.
Khan
, M. J.
, Bhuyan
, G.
, Iqbal
, M. T.
, and Quaicoe
, J. E.
, 2009
, “Hydrokinetic Energy Conversion Systems and Assessment of Horizontal and Vertical Axis Turbines for River and Tidal Applications: A Technology Status Review
,” Appl. Energy
, 86
(10
), pp. 1823
–1835
. 10.
Johnson
, G. L.
, 2001
, “Wind Turbine Power
,” Wind Energy Syst.
, pp. 1
–54
.11.
Mofei
, L.
, 2014
, “Hydrokinetic Turbine Power Converter and Controller System Design and Implementation
,” Doctoral dissertation
, University of British Columbia
. http://docplayer.net/37143202-Hydrokinetic-turbine-power-converter-and-controller-system-design-and-implementation-mofei-liu.html12.
Góralczyk
, A.
, and Adamkowski
, A.
, 2018
, “Model of a Ducted Axial-Flow Hydrokinetic Turbine—Results of Experimental and Numerical Examination
,” Polish Marit. Res.
, 25
(3
), pp. 113
–122
. 13.
Shashikumar
, C. M.
, and Madav
, V.
, 2021
, “Numerical and Experimental Investigation of Modified V-Shaped Turbine Blades for Hydrokinetic Energy Generation
,” Renew. Energy
, 177
, pp. 1170
–1197
. 14.
Wang
, Y.
, Zhao
, M.
, Chang
, J.
, Wang
, X.
, and Tian
, Y.
, 2019
, “Study on the Combined Operation of a Hydro-Thermal-Wind Hybrid Power System Based on Hydro-Wind Power Compensating Principles
,” Energy Convers. Manage.
, 194
, pp. 94
–111
. 15.
dos Santos
, I. F. S.
, Camacho
, R. G. R.
, and Tiago Filho
, G. L.
, 2021
, “Study of the Wake Characteristics and Turbines Configuration of a Hydrokinetic Farm in an Amazonian River Using Experimental Data and CFD Tools
,” J. Clean. Prod.
, 299
, p. 126881
. 16.
Medimorec
, D.
, and Tomšić
, Ž
, 2015
, “Portfolio Theory Application in Wind Potential Assessment
,” Renew. Energy
, 76
, pp. 494
–502
. 17.
Ibrahim
, W. I.
, Mohamed
, M. R.
, Ismail
, R. M. T. R.
, Leung
, P. K.
, Xing
, W. W.
, and Shah
, A. A.
, 2021
, “Hydrokinetic Energy Harnessing Technologies: A Review
,” Energy Rep.
, 7
, pp. 2021
–2042
. 18.
Sarma
, N. K.
, Biswas
, A.
, and Misra
, R. D.
, 2014
, “Experimental and Computational Evaluation of Savonius Hydrokinetic Turbine for Low Velocity Condition With Comparison to Savonius Wind Turbine at the Same Input Power
,” Energy Convers. Manage..
, 83
, pp. 88
–98
. 19.
Kang
, C.
, Zhao
, H.
, Zhang
, Y.
, and Ding
, K.
, 2021
, “Effects of Upstream Deflector on Flow Characteristics and Startup Performance of a Drag-Type Hydrokinetic Rotor
,” Renew. Energy
, 172
, pp. 290
–303
. 20.
Schleicher
, W. C.
, Riglin
, J. D.
, and Oztekin
, A.
, 2015
, “Numerical Characterization of a Preliminary Portable Micro-Hydrokinetic Turbine Rotor Design
,” Renew. Energy
, 76
, pp. 234
–241
. 21.
Cavalari Labigalini
, L.
, de V. Salvo
, R.
, Sene de Lima
, R.
, Corrêa da Silva
, R.
, and de Marchi Neto
, I.
, 2021
, “Hydrokinetic Turbine Design Through Performance Prediction and Hybrid Metaheuristic Multi-Objective Optimization
,” Energy Convers. Manage.
, 238
, p. 114169
. 22.
Mahmuddin
, F.
, 2017
, “Rotor Blade Performance Analysis With Blade Element Momentum Theory
,” Energy Procedia
, 105
, pp. 1123
–1129
. 23.
Døssing
, M.
, Madsen
, H. A.
, and Bak
, C.
, 2012
, “Aerodynamic Optimization of Wind Turbine Rotors Using a Blade Element Momentum Method With Corrections for Wake Rotation and Expansion
,” Wind Energy
, 15
(4
), pp. 563
–574
. 24.
Madsen
, H. Aa.
, Riziotis
, V.
, Zahle
, F.
, Hansen
, M. O. L.
, Snel
, H.
, Grasso
, F.
, Larsen
, T. J.
, Politis
, E.
, and Rasmussen
, F.
, 2012
, “Blade Element Momentum Modeling of Inflow with Shear in Comparison With Advanced Model Results
,” Wind Energy
, 15
(1
), pp. 63
–81
. 25.
MacNeill
, R.
, and Verstraete
, D.
, 2017
, “Blade Element Momentum Theory Extended to Model Low Reynolds Number Propeller Performance
,” Aeronaut. J.
, 121
(1240
), pp. 835
–857
. 26.
Van Treuren
, K.
, 2015
, “Small-Scale Wind Turbine Testing in Wind Tunnels Under Low Reynolds Number Conditions
,” ASME J. Energy Resour. Technol.
, 137
(5
), p. 051208
. 27.
Sanderse
, B.
, Van Der Pijl
, S. P.
, and Koren
, B.
, 2011
, “Review of Computational Fluid Dynamics for Wind Turbine Wake Aerodynamics
,” Wind Energy
, 14
(7
), pp. 799
–819
. 28.
Chica
, E.
, Ṕerez
, F.
, Rubio-Clemente
, A.
, and Agudelo
, S.
, 2015
, “Design of a Hydrokinetic Turbine
,” WIT Trans. Ecol. Environ.
, 195
, pp. 137
–148
. 29.
Ingram
, G.
, 2011
, “Wind Turbine Blade Analysis Using the Blade Element Momentum Method
,” October
, 1.1
(c
), pp. 1
–21
, https://community.dur.ac.uk/g.l.ingram/download/wind_turbine_design.pdf30.
Manwell
, J. F.
, McGowan
, J. G.
, and Rogers
, A. L.
, 2010
, Wind Energy Explained: Theory, Design and Application
, 2nd ed., John Wiley & Sons Ltd.
31.
Muratoglu
, A.
, and Yuce
, M. I.
, 2015
, “Performance Analysis of Hydrokinetic Turbine Blade Sections
,” Avestia Publ. Adv. Renew. Energy
, 2
, pp. 1
–10
.32.
Muratoglu
, A.
, and Yuce
, M. I.
, 2017
, “Design of a River Hydrokinetic Turbine Using Optimization and CFD Simulations
,” J. Energy Eng.
, 143
(4
), p. 04017009
. 33.
Nachtane
, M.
, Tarfaoui
, M.
, El Moumen
, A.
, Saifaoui
, D.
, and Benyahia
, H.
, 2019
, “Design and Hydrodynamic Performance of a Horizontal Axis Hydrokinetic Turbine
,” Int. J. Automot. Mech. Eng.
, 16
(2
), pp. 6453
–6469
. 34.
Zhao
, L.
, Liang
, J.
, Tang
, L.
, Yang
, Y.
, and Liu
, H.
, 2015
, “Enhancement of Galloping-Based Wind Energy Harvesting by Synchronized Switching Interface Circuits
,” Active and Passive Smart Structures and Integrated Systems
, 9431
pp. 116
–125
.35.
Gao
, Z.
, Yu
, Z.
, and Wang
, J.
, 2013
, “An Optimization-Based Iterative Approach to Tetrahedral Mesh Smoothing
,” Lect. Notes Comput. Vis. Biomech.
, 3
, pp. 143
–157
. 36.
Al-Bahadly
, I.
, and Al-Bahadly
, I.
, 2018
, “An Integrated Wind and Hydro Power System Using Switched Reluctance Generator
,” J. Power Energy Eng.
, 6
(2
), pp. 1
–19
.37.
Ekanayake
, J. B.
, Holdsworth
, L.
, Wu
, X. G.
, and Jenkins
, N.
, 2003
, “Dynamic Modeling of Doubly Fed Induction Generator Wind Turbines
,” IEEE Trans. Power Syst.
, 18
(2
), pp. 803
–809
. 38.
Jeffcoate
, P.
, Whittaker
, T.
, Boake
, C.
, and Elsaesser
, B.
, 2016
, “Field Tests of Multiple 1/10 Scale Tidal Turbines in Steady Flows
,” Renew. Energy
, 87
, pp. 240
–252
. 39.
Atcheson
, M.
, MacKinnon
, P.
, and Elsaesser
, B.
, 2015
, “A Large Scale Model Experimental Study of a Tidal Turbine in Uniform Steady Flow
,” Ocean Eng.
, 110
, pp. 51
–61
. 40.
Tian
, W.
, Mao
, Z.
, and Ding
, H.
, 2018
, “Design, Test and Numerical Simulation of a Low-Speed Horizontal Axis Hydrokinetic Turbine
,” Int. J. Nav. Archit. Ocean Eng.
, 10
(6
), pp. 782
–793
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