Journal of Recent Trends in Electrical Power System (e-ISSN: 2584-2404)

This paper focused on wind energy potential assessment of Abuloma community at 70m height. The wind speed data used for this work was measured at 2m and 10m height from 2018 – 2022 obtained from the National Aeronautic Space Agency (NASA) weather database. The power law with wind shear exponent value of 0.592 was used to extrapolate the wind speed data to height of 70m. The wind speed data was evaluated using two-parameter Weibull distribution model and Power Density Method (PDM). The result shows that the annual mean wind speed is 7.21m/s. The monthly mean wind speeds vary from 5m/s and 10m/s. The shape parameter for the five years has an annual average value of 4.65. The scale parameter has an annual average value of 7.88m/s for the five years. The annual average most probable wind speed (Vmp) for the five years was found to be 7.48m/s. The Vmp values span from 6.41 to 9.02m/s. The annual average maximum energy carrying wind speed (VmaxE) for the five years was calculated to be 8.51m/s. The annual mean wind power density was 235.27W/m² at height of 70m. The mean wind energy density was 171.75kWh/m² at height of 70m. According to wind power classification, the study site was classified as marginal and good in terms of the wind power density and wind speed respectively. The study revealed that Abuloma community has good wind energy potential for power generation for grid integration.

J.B. Gupta (2013). S. K. Katara & Sons, Publisher of Engineering and Computer Books, New Delhi.

H. N. Amadi (2015a). “Impact of Power Outages on Developing Countries: Evidence from Rural Households in Niger Delta, Nigeria.” Journal of Energy Technologies and Policy, Vol.5, No.3, 2015: 27-38.

Chineke, C.T. (2009). Boosting Electricity Supply in Nigeria: Wind Energy to the Rescue? The Pacific Journal of Science and Technology, Volume 10. Number 2. November 2009 (Fall).

Chineke, T.C. and E.C. Igwiro. 2008. “Urban and Rural Electrification: Enhancing the Energy Sector in Nigeria using Photovoltaic Technology”. African Journal of Science and Tech. 9(1):102–108.

International Energy Outlook. 2006. Available Online at: http://en.wikipedia.org/wiki/Energy_Information_Administration.

H.N. Amadi (2015b). “Power Outages in Port Harcourt City: Problems and Solutions”, IOSR Journal of Electrical and Electronics Engineering, 10(2), Vers. III, pp.59-66.

Iwayemi, A., Nigeria’s dual energy problems: Policy issues and challenges, International Association for energy economics, Fourth Quarter, 2008, available online at http//:www.iaee.org/en/publications/newsletterdl.aspx? id=53.

Uchendu, O.A. (1993). Economic costs of electricity outages: evidence from sample study of industrial and commercial firms in Lagos area of Nigeria. CBN Economic and Financial Review. 31:183 195.

Amadi, H. N. (2018). Wind Energy Potential Assessment of Coastal States in South-South Nigeria Based on the Weibull Distribution Model. European Journal of Electrical and Computer Engineering (EJECE), 2(7), pp. 1-6.

Ajayi, O. O., Fagbenle, R. O., James, K., JuliusNdambuki, M., Omole, D. O., and Badejo, A. A. (2014). Wind energy study and energy cost of wind electricity generation in Nigeria: Past and recent results and a case study for South West Nigeria. Energies 7 (12), 8508–8534. doi:10.3390/en7128508.