Investigate Air Well Turbines Performance for Power Generation by Tidal Waves in River

Authors

  • Elaff F. Sharif Dept. of Mechanical Eng., College of Engineering, Al-Nahrain University, Baghdad-Iraq.
  • Mahmoud Sh. Mahmoud Dept. of Mechanical Eng., College of Engineering, Al-Nahrain University, Baghdad-Iraq.
  • Abdullah A. K AL-Maskari University of Technology and Applied Science - UTAS – Ibra, College of Engineering & Technology, Sultanate of Oman

DOI:

https://doi.org/10.29194/NJES.26030150

Keywords:

Wave Energy, Air Turbine Performance, Power Generation

Abstract

The phenomenon of climate change resulting from the increase of global warming has become one of the main problems facing the world. Where researchers and specialists have worked for many years to find a solution that reduces this phenomenon and limits its risks. It is likely that clean energy is an alternative to fossil fuel sources, which are the main source of global warming. One of the clean energy sources is ocean wave energy, which is a huge and untapped energy source, despite the possibility of extracting large energy from waves. This paper focuses on the study of deep-sea turbines and their results. A study was conducted on the capture chamber. Where this paper presents an experimental model of a water tank with certain dimensions in the university laboratories to describe the dynamic behavior of the capture chamber. The Froude number scale was used to model the dimensions and depth of the water as well as the wave properties.  Through experimental work and its results show, and it was found that the power generated by the motion of the wave strength is related to the height and frequency of the wave.

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References

H. J. Vermaak, K. Kusakana, and S. P. Koko, “Status of micro-hydrokinetic river technology in rural applications: A review of literature,” Renew. Sustain. Energy Rev., vol. 29, pp. 625–633, 2014.

D. J. Bertsch, “Hydrokinetic energy: trying to navigate the energy and wave law framework to develop new renewable energy technology,” Accessed June, vol. 8, 2012.

J. M. P. Conde and L. M. C. Gato, “Numerical study of the air-flow in an oscillating water column wave energy converter,” Renew. energy, vol. 33, no. 12, pp. 2637–2644, 2008.

D. Ross, Power from the Waves. Oxford University Press, USA, 1995.

Y. Masuda, “An experience of wave power generator through tests and improvement,” in Hydrodynamics of ocean wave-energy utilization, Springer, 1986, pp. 445–452.

T. W. Thorpe, “A brief review of wave energy,” 1999.

A. Ilyas, S. A. R. Kashif, M. A. Saqib, and M. M. Asad, “Wave electrical energy systems: Implementation, challenges and environmental issues,” Renew. Sustain. Energy Rev., vol. 40, pp. 260–268, 2014.

J. Cruz, Ocean wave energy: current status and future prespectives. Springer Science & Business Media, 2007.

N. Delmonte, D. Barater, F. Giuliani, P. Cova, and G. Buticchi, “Review of oscillating water column converters,” IEEE Trans. Ind. Appl., vol. 52, no. 2, pp. 1698–1710, 2015.

T. O. Aderinto, F. Haces-Fernandez, and H. Li, “Design and Potential Application of Small Scale Wave Energy Converter,” in ASME International Mechanical Engineering Congress and Exposition, 2017, vol. 58417, p. V006T08A084.

A. J. Garrido et al., “Mathematical modeling of oscillating water columns wave-structure interaction in ocean energy plants,” Math. Probl. Eng., vol. 2015, 2015.

A. El Barakaz and A. El Marjani, “Water Oscillation Modelling Inside OWC Chamber for Wave Energy Conversion,” Int. J. Renew. Energy Res., vol. 11, no. 2, pp. 826–841, 2021.

M. Folley, R. Curran, and T. Whittaker, “Comparison of LIMPET contra-rotating wells turbine with theoretical and model test predictions,” Ocean Eng., vol. 33, no. 8–9, pp. 1056–1069, 2006.

E. Affandi and L. A. Anzar, “Study on Wave Energy Conversion by Using Oscillating Water Column in Alindau Waters,” in MATEC Web of Conferences, 2020, vol. 331, p. 3001.

R. K. Sykes, A. W. Lewis, and G. P. Thomas, “Predicting hydrodynamic pressure in fixed and floating owc using a piston model,” 2011.

A. F. de O. Falcão and A. Sarmento, “Wave generation by a periodic surface pressure and its application in wave-energy extraction,” 1980.

D. V Evans, “Wave-power absorption by systems of oscillating surface pressure distributions,” J. Fluid Mech., vol. 114, pp. 481–499, 1982.

A. J. N. A. Sarmento and A. F. de O. Falcão, “Wave generation by an oscillating surface-pressure and its application in wave-energy extraction,” J. Fluid Mech., vol. 150, pp. 467–485, 1985.

G. Chatry, “Développement et simulation d’une méthode de régulation auto-adaptative pour l’absorption dynamique des ondes de gravité.” Nantes, 2032.

A. F. De O Falcão and R. J. A. Rodrigues, “Stochastic modelling of OWC wave power plant performance,” Appl. Ocean Res., vol. 24, no. 2, pp. 59–71, 2002.

T. Aderinto and H. Li, “Review on power performance and efficiency of wave energy converters,” Energies, vol. 12, no. 22, p. 4329, 2019.

M. Takao and T. Setoguchi, “Air turbines for wave energy conversion,” Int. J. Rotating Mach., vol. 2012, 2012.

F. Thiebaut et al., “Testing of a floating OWC device with movable guide vane impulse turbine power take-off,” 2011.

M. Takao, Y. Fujioka, and T. Setoguchi, “Effect of pitch-controlled guide vanes on the performance of a radial turbine for wave energy conversion,” Ocean Eng., vol. 32, no. 17–18, pp. 2079–2087, 2005.

T. Setoguchi, S. Santhakumar, M. Takao, T. H. Kim, and K. Kaneko, “A performance study of a radial turbine for wave energy conversion,” Proc. Inst. Mech. Eng. Part A J. Power Energy, vol. 216, no. 1, pp. 15–22, 2002.

M. Takao, A. Takami, S. Okuhara, and T. Setoguchi, “A twin unidirectional impulse turbine for wave energy conversion,” J. Therm. Sci., vol. 20, no. 5, pp. 394–397, 2011.

M. Takao, T. Setoguchi, K. Kaneko, T. H. Kim, H. Maeda, and M. Inoue, “Impulse turbine for wave power conversion with air flow rectification system,” Int. J. offshore polar Eng., vol. 12, no. 02, 2002.

V. Jayashankar et al., “A twin unidirectional impulse turbine topology for OWC based wave energy plants,” Renew. energy, vol. 34, no. 3, pp. 692–698, 2009.

T. Setoguchi and M. Takao, “Current status of self rectifying air turbines for wave energy conversion,” Energy Convers. Manag., vol. 47, no. 15–16, pp. 2382–2396, 2006.

S. Natanzi, J. A. Teixeira, and G. Laird, “A novel high-efficiency impulse turbine for use in oscillating water column devices,” 2011.

S. Raghunathan, C. P. Tan, and O. O. Ombaka, “Performance of the Wells self-rectifying air turbine,” Aeronaut. J., vol. 89, no. 890, pp. 369–379, 1985.

H. Zhou, “Maximum power point tracking control of hydrokinetic turbine and low-speed high-thrust permanent magnet generator design,” Missouri Univ of Science And Technology Rolla, 2012.

L. G. Scherer and R. F. de Camargo, “Control of micro hydro power stations using nonlinear model of hydraulic turbine applied on microgrid systems,” in XI Brazilian Power Electronics Conference, 2011, pp. 812–818.

B. A. Singh, S. B. Singh, M. Singh, R. Dixit, N. Mittal, and A. Baranwal, “Stand Aloe power generation by 3ø asynchronous generator: a comprehensive survey,” Int. J. Rev. Comput., vol. 10, pp. 36–51, 2012.

J. C. C. Henriques, J. C. C. Portillo, W. Sheng, L. M. C. Gato, and A. F. de O. Falcão, “Dynamics and control of air turbines in oscillating-water-column wave energy converters: Analyses and case study,” Renew. Sustain. Energy Rev., vol. 112, pp. 571–589, 2019.

R. Waters, J. Engström, J. Isberg, and M. Leijon, “Wave climate off the Swedish west coast,” Renew. energy, vol. 34, no. 6, pp. 1600–1606, 2009.

Q. Jianglei, X. Lie, L. Wang, Q. Lin, and L. Yongdong, “The modulation of common mode voltage suppression for a three-level matrix converter,” in 2016 IEEE International Conference on Aircraft Utility Systems (AUS), 2016, pp. 533–538.

S. Khwan-On, L. De Lillo, L. Empringham, P. Wheeler, and C. Gerada, “Fault-tolerant, matrix converter, permanent magnet synchronous motor drive for open-circuit failures,” IET Electr. power Appl., vol. 5, no. 8, pp. 654–667, 2011.

D. R. Kiran, A. Palani, S. Muthukumar, and V. Jayashankar, “Steady grid power from wave energy,” IEEE Trans. Energy Convers., vol. 22, no. 2, pp. 539–540, 2007.

G. D. Marques, “Stability study of the slip power recovery generator applied to the sea wave energy extraction,” in PESC’92 Record. 23rd Annual IEEE Power Electronics Specialists Conference, 1992, pp. 732–738.

A. F. de O. Falca˜ o, L. C. Vieira, P. A. P. Justino, and J. André, “By-pass air-valve control of an OWC wave power plant,” J. Offshore Mech. Arct. Eng., vol. 125, no. 3, pp. 205–210, 2003.

B. Neammanee, K. Krajangpan, S. Sirisumrannukul, and S. Chatratana, “Maximum peak power tracking-based control algorithms with stall regulation for optimal wind energy capture,” IEEJ Trans. Ind. Appl., vol. 128, no. 4, pp. 411–417, 2008.

M. Amundarain, M. Alberdi, A. J. Garrido, I. Garrido, and J. Maseda, “Wave energy plants: Control strategies for avoiding the stalling behaviour in the Wells turbine,” Renew. Energy, vol. 35, no. 12, pp. 2639–2648, 2010.

N. A. Orlando, M. Liserre, R. A. Mastromauro, and A. Dell’Aquila, “A survey of control issues in PMSG-based small wind-turbine systems,” IEEE Trans. Ind. Informatics, vol. 9, no. 3, pp. 1211–1221, 2013.

T.-H. Kim, M. Takao, T. Setoguchi, K. Kaneko, and M. Inoue, “Performance comparison of turbines for wave power conversion,” Int. J. Therm. Sci., vol. 40, no. 7, pp. 681–689, 2001.

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Published

31-10-2023

How to Cite

[1]
E. F. Sharif, M. S. Mahmoud, and A. A. K. AL-Maskari, “Investigate Air Well Turbines Performance for Power Generation by Tidal Waves in River”, NJES, vol. 26, no. 3, pp. 150–156, Oct. 2023, doi: 10.29194/NJES.26030150.

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