A comparative Study to evaluate the Weibull Parameters under the influence of atmospheric stability conditions

Authors

  • Abdulmenam A. Abdalla Department of Mechanical, Faculty of Engineering, Sabratha University, Sabratha, Libya. Author
  • Walid. Husien Department of Mechanical, Faculty of Engineering, Sabratha University, Sabratha, Libya Author
  • Wedad B. El-Osta Center for Solar Energy Research and Studies, Tajoura, Libya Author

DOI:

https://doi.org/10.58916/jhas.v9i1.204

Keywords:

Weibull function, shape and scale Parameters, atmospheric stability conditions

Abstract

Analysing the wind speed distribution and the likelihood of its recurrence throughout the year is crucial for understanding the wind sources and their characteristics at a specific site. This initial and vital step assists in estimating the available energy and guides to the selection of suitable wind turbines and related equipment for wind farms. In this paper, wind speed data was collected over a one-year period in Magron city to evaluate the two Weibull parameters (shape and scale) using five different methods: graphical, empirical, moments, maximum likelihood, and energy pattern factor. These calculations were conducted under different atmospheric stability conditions namely stable, neutral, and unstable conditions. To assess the reliability of these methods, three statistical analyses were applied: root mean square error, correlation coefficient, and the Chi-Square Error. The accuracy of calculating Weibull parameters varies with season and atmospheric stability conditions. The empirical method demonstrates superior accuracy in estimating Weibull parameters for stable conditions during most seasons, while the maximum likelihood method performs well for unstable conditions, and the accuracy of neutral conditions varies depending on the season. Considering the varying accuracy of different methods across different atmospheric stability conditions and seasons, careful selection of appropriate methods is vital for reliable estimation of Weibull parameters and therefore, assessment of wind energy potential.

Downloads

Download data is not yet available.

References

- Khan, J., Ahmed, F., Uddin, Z, Iqbal, S., Jilani, S., Siddiqui, A. & Aijaz, A. (2015). Determination of Weibull Parameter by Four Numerical Methods and Prediction of Wind Speed in Jiwani (Balochistan). Journal of Basic & Applied Sciences. 11, 62-68.

- Bilir, L., Imir, M., Devrim, Y. & Albostan, A. (2015). Seasonal and yearly wind speed distribution and wind power density analysis based on Weibull distribution function. International journal of hydrogen energy, 40, 15301-15310.

- E. Dokur, & M. Kurban. (2015). Wind Speed Potential Analysis Based on Weibull Distribution. balkan journal of electrical & computer engineering, 3, 231-235.

- Burton, T. Sharpe, D, Jenkins, N. & Bossanyi, E. (2001). Wind energy handbook, London, British Library Cataloguing.

- Carrillo, C., Cidrás, J., Díaz-Dorado. E. & Obando-Montaño, A. F. (2014). An Approach to Determine the Weibull Parameters for Wind Energy Analysis: The Case of Galicia (Spain). Energies, 7, 2676-2700.

- Wais, P. (2017). Two and three-parameter Weibull distribution in available wind power analysis, Renew Energy, 103, 15–29.

- Mohammadi, K., Alavi, O., Mostafaeipour, A., Goudarzi, N. & Jalilvand, M. (2016). Assessing different parameters estimation methods of Weibull distribution to compute wind power density, Energy Conversion and Management, 108, 322–335.

- Celeska, M., Najdenkoski, K., Stoilkov, V., Buchkovska, A., Kokolanski, Z. & Dimchev, V. (2015). Estimation of Weibull Parameters from Wind Measurement Data by Comparison of Statistical Methods, International CONFERENCE ON COMPUTER AS A TOOL (EUROCON), Salamanca Spain, September 8-11.

- Boro, D., Elagnon, H., Donnou, V., Kossi, I., Bado, N., Kieno, F.P. & Bathiebo, J. (2019). Vertical Profile of Wind Speed in the Atmospheric Boundary Layer and Assessment of Wind Resource on the Bobo Dioulasso Site in Burkina Faso, Smart Grid and Renewable Energy, 10, 257–278.

- Oner, Y., Ozcira, S., Bekiroglu, N. & Senol, I. (2013). A comparative analysis of wind power density prediction methods for C- anakkale, Intepe region, Turkey, Renewable and Sustainable Energy Reviews, 23, 491–502.

- Teyabeen, A.A., Akkari, F. R. & Jwaid, A. E. (2017). Comparison of Seven Numerical Methods for Estimating Weibull Parameters for Wind Energy Applications, UKSim-AMSS 19th International Conference on Modelling & Simulation, Cambridge, UK, April 05-07. 2017, pp. 173–178.

- Kang, D., Ko, K. & Huh, J. (2018). Comparative Study of Different Methods for Estimating Weibull Parameters: A Case Study on Jeju Island, South Korea, Energies, vol. 11(2), 356.

- Rahman, S. M. & Chattopadhyay, H. (2020). A new approach to estimate the Weibull parameters for wind energy assessment: Case studies with four cities from the Northeast and East India, Int Trans Electr Energy Syst, 30, e12574.

- Kang, S., Khanjari, A., You, S. & Lee, J. (2021). Comparison of different statistical methods used to estimate Weibull parameters for wind speed contribution in nearby an offshore site, Republic of Korea, Energy Reports, 7, 7358-7373.

- Hussain, I., Haider, A., Ullah, Z., Russo, M., Casolino, G. M. & Azeem, B. (2023). Comparative Analysis of Eight Numerical Methods Using Weibull Distribution to Estimate Wind Power Density for Coastal Areas in Pakistan, Energies, 16(3), 66.

- Tong, W. (2010). Wind Power Generation and Wind Turbine Design, Ashurst Lodge, Ashurst, Southampton, SO40 7AA, UK, WIT Press.

- kaimal, J. C., finnican, J. C. (1995). Atmospheric Boundary Layer Flows- their Structure and Measurement. Journal of the royal meteorological society, 121, 289.

– Wharton, S. & Lundquist, J. K. (2010). Atmospheric Stability Impacts on Power Curves of Tall Wind Turbines – An Analysis of a West Coast North American Wind Farm, LLNL-TR-424425, pp. 75.

- Ruedas, F. B., Camacho, C. A. & Marcuello, S. R. (2010). Analysis and validation of the methodology used in the extrapolation of wind speed data at different heights. Renewable and Sustainable Energy Reviews, 14, 2383-2391.

- Wharton, S. & Lundquist, J. K. (2010). Atmospheric Stability Impacts on Power Curves of Tall Wind Turbines – An Analysis of a West Coast North American Wind Farm, LLNL-TR-424425, pp.75.

- Azada, A. K., Rasula, M. G., Alam, M. M., Uddin, S. M. & Mondal, S.K. (2014). Analysis of wind energy conversion system using Weibull distribution. Procedia Engineering, 90, 725-732.

- Werapun, W., Tirawanichakul, Y. & Waewsak, J. (2015). Comparative Study of Five Methods to Estimate Weibull Parameters for Wind Speed on Phangan Island, Thailand. Energy Procedia, 79, 976-981.

- Kaoga, D. K., Yamigno, S. D., Raidandi, D. & Djongyang, N. (2014). Performance analysis of Weibull methods for estimation of wind speed distributions in the adamaoua region of Cameroon. International Journal of Basic and Applied Sciences, 3, 298-306.

- Kidmo, D.K., Danwe, R., Doka, S.Y. & Djongyang, N. (2015). Statistical analysis of wind speed distribution based on six Weibull Methods for wind power evaluation in Garoua, Cameroon. Revue des Energies Renouvelables, 18, 105-125.

Published

2024-03-07

Issue

Section

Articles

How to Cite

Abdulmenam A. Abdalla, Walid. Husien, & Wedad B. El-Osta. (2024). A comparative Study to evaluate the Weibull Parameters under the influence of atmospheric stability conditions . Bani Waleed University Journal of Humanities and Applied Sciences, 9(1), 307-322. https://doi.org/10.58916/jhas.v9i1.204

Most read articles by the same author(s)

<< < 9 10 11 12 13 14 15 16 17 18 > >> 

Similar Articles

1-10 of 50

You may also start an advanced similarity search for this article.