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Hydrokinetic Energy Opportunity for Rural Electrification in Nigeria

Power Energy Machine and Drives (PEMD) Research Group, Electrical and Electronic Engineering Department, Faculty of Technology, University of Ibadan, Nigeria

Published: 10 Jul 2018.
Editor(s): H Hadiyanto

Citation Format:
Abstract

This paper is part of the ongoing research by the Power, Energy, Machine and Drive (PEMD) research group of the Electrical Engineering Department of the University of Ibadan. The paper presents various sites with possible hydrokinetic energy potential in Nigeria with the aim of quantifying their energy potential for rural electrification application. Overview of hydrokinetic technology is also presented with the view of highlighting the opportunities and the challenges of the technology for rural electrification. A case study of using hydrokinetic turbine technology in meeting the energy demand of a proposed civic center in a remote community is demonstrated.  Some of the key findings revealed that Nigeria has many untapped hydrokinetic potential site and if adequately harnessed can improve the energy poverty and boost economic activities especially in the isolated and remote rural communities, where adequate river water resource is available. The total estimated untapped hydrokinetic energy potential in Nigeria is 111.15MW with the Northern part of the country having 68.18MW while the Southern part has 42.97MW. The case study shows that harnessing hydrokinetic energy of potential site is promising for rural electrification. This paper is important as it will serve as an initial requirement for optimal investment in hydrokinetic power development in Nigeria.

Article History: Received November 16th 2017; Received in revised form April 7th 2018; Accepted April 15th 2018; Available online

How to Cite This Article: Olatunji, O.A.S., Raphael, A.T. and Yomi, I.T. (2018) Hydrokinetic Energy Opportunity for Rural Electrification in Nigeria. Int. Journal of Renewable Energy Development, 7(2), 183-190.

https://doi.org/10.14710/ijred.7.2.183-190

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Keywords: Hydrokinetic; Hydro-turbine; Nigeria;Rural Electrification
Funding: Nil

Article Metrics:

  1. Anyi, M., Ali, S. & Kirke, B., (2009). Remote community electrification. International Conference on Renewable Energies and Power Quality, (ICREPQ'09). Valencia,Spain, 15-17
  2. Anyi, M., Kirke, B. & Ali, S., (2010). Remote community electrification in sarawak, malaysia. Renewable and Sustainable Energy Reviews, 35 (7), 609–613.
  3. Ayodele, T.R., (2014). Feasibility study of stand-alone hybrid energy system for rural electrification in nigeria: The case study of ala-ajagbusi community. International Journal of Renewable Energy Resources, 4, 1-12
  4. Ayodele, T.R., Ogunjuyigbe, A.S.O. & Babatunde, J.B., (2016). Sustainable electricity generation in rural communities using hybrid energy system: The case study of ojataye village. International Journal of Renewable Energy, 11 (1), 43-56
  5. Bertsch, D.J., (2015). Hydrokinetic energy: Trying to navigate the energy and wave law frame work to develop new renewable energy technology. Available from: . http://www.elizabethburleson.com/HydrokineticEnergyDerekBertsch.pdf, accessed 15th May 2015., Available from:
  6. Chen, F., Duic, N., Aives, L.M. & Carvalho, M.G., (2007). Renewable energy solutions for islands. Renew Sustainable Energy Reviews, 11 (8), 1888-1892
  7. Coiro, D.P., (2007). Experiments on horizontal and vertical axis water turbines for harnessing marine currents: Technological and economical aspects. www.dpa.unina.it/adag/. Available from: www.dpa.unina.it/adag/
  8. F.A.O, (2012). Food and agriculture organization of the united nations, hydrology and inland water resources of nigeria, retrieved august 2012 http://www.fao.org/docrep., 1-50
  9. Faure, T.D., Pratte, B.D. & Swan, D., (1986). The darrieus hydraulic turbine-model and field experiments. Fourth International Symposium on Hydro Power Fluid Machinery: presented at the Winter Annual Meeting of the American Society of Mechanical Engineers. Anaheim, California: American Society of Mechanical Engineers, 123-127
  10. Gorban, A.N., Gorlov, A.M. & Silantyev, V.M., (2001). Limits of the turbine efficiency for free fluid flow. Journal of Energy Resources Technology, Transactions of the ASME, 123 (2-4), 311-317
  11. Güney, M.S. & Kaygusuz, K., (2010). Hydrokinetic energy conversion systems. Renewable Sustainable Energy Reviews, 14, 2996–3004
  12. Kaygusuz, K. & Kaygusuz, A., (2002). Renewable energy and sustainable development in turkey. Renewable Energy 25, 431–453
  13. Khan, M., J., Bhuyan, G., Iqbal, M.T. & Quaicoe, J.E., (2008). River current energy conversion systems: Progress, prospects and challenges. Renewable and Sustainable Energy Reviews, 12, 2177-2193
  14. Khan, M.J., Bhuyan, G., Iqbal, M.T. & 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. Applied Energy, 1823 – 1835
  15. Kusakana, K., (2015). Feasibility analysis of river off-grid hydrokinetic systems with pumped hydro storage in rural application. Energy Conversion and Management, 96, 352-362
  16. Manohar, K. & Adeyanju, A.A., (2009). Hydropower energy resources in nigeria. Journal of Engineering and Applied Sciences, 4 (1), 68-73
  17. Ogunjuyigbe, A.S.O., Ayodele, T.R. & Ibitoye, T.Y., (2015). Review of hydrokinetic energy potential in nigeria. First Faculty of Technology Conference. University of Ibadan, Nigeria, 129-134
  18. Olatunde, S.O. & Oladele, O., (2013). Eco-partitioning and indices of heavy metal accumulation in sediment and tilapia zillii fish in water catchment of river niger at ajaokuta, north central nigeria. International Journal of Physical Sciences, 8 (20), 1111-1117
  19. Sambo, A.S., (2009). Strategic developments in renewable energy in nigeria
  20. Vermaak, H.J., Kusakana, K. & S.P., K., (2014). Status of micro-hydrokinetic river technology in rural applications. Renewable and Sustainable Energy Reviews, 29, 625 - 633
  21. Zarma, I.H., (2006). Hydropower resources in nigeria. 2nd Hydropower for Today Conference of the International Centre for Small Hydropower (ICSHP), Hangzhou, China. Canada, 3-7
  22. Zomers, A., (2003). The challenges of rural electrification. Energy for Sustainable Development 7(1), 69–76

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