Reliability Analysis of a Typical 33kV Distribution Network Using MATLAB (A Case Study of Ile-Oluji 33kV Distribution Line)
Article Sidebar
Main Article Content
Abstract
The significance of a dependable and sufficient electrical power supply in societal development cannot be overstated. The distribution of electrical power holds a crucial position in the power system chain, representing the final stage where it reaches consumers. At this phase, various types of losses, including technical loss and theft, among others are associated. The Ile-Oluji community is situated in Ondo State, a south-western part of Nigeria, A region which is host to federal, state, local and private institutions. This community grapples with inconsistent power supply experiencing intermittent trips without a clear originating cause from components in the Ile-Oluji injection substation and its feeder in Ondo. This study analyses the power distribution patterns in this locality focusing on three primary elements (transformer, switch gear and supply line) extracting data on; failures, outage time, numbers of customers and total hours for the year 2019 to 2022. Reliability indices were employed to assess its performance utilising the MATLAB software. Codes were crafted to extract these indices; Availability, Failure rates, Mean Time to Repair (MTTR), Mean Time Between failure (MTBF), System Average Interruption Duration Index (SAIDI), System Average Interruption Frequency Index (SAIFI), and Customer Average Interruption Duration Index (CAIDI). The results show that there is a strong relationship among the reliability indices. It is adduced that the lower the failure rate, the higher the availability of a system. It was concluded that the power system switchgear recorded the highest failure rate amongst the three elements with 0.037341 hrs/year followed by supply line with 0.022541 hrs/year and the transformer with 0.0148 hrs/year in 2022. In corollary, transformer has the highest availability of 0.94441 followed by supply line with 0.81681 and switchgear with 0.78004 in 2021, switchgear recorded the highest failure rates because it is responsible for executing both forced and planned outages.
Article Details
This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.
References
[2] Roystone, A. (2014). Reliability Analysis of Distribution Network. Faculty of Electrical and Electronics Engineering, University of Tun-Hussein, Onn, Malaysia, 6-9.
[3] Theraja, B.L. & Theraja, A.K. (2005). A Textbook of Electrical Technology. Basic Electrical Engineering in S.I. System of Units. New Delhi: S. Chand & Company Ltd., London, 1(1), 855-864.
[4] Gonen, T. (2014). Electric Power Distribution Engineering. Boca Ration: CRC Press, Taylor and Francis group.
[5] Olumuyiwa, A.A., Evans, C.A., & Emmanuel, E. (2020). Reliability Assessment on Secondary Distribution Network: Case study of Karu substation in Abuja, Nigeria. Academic Journal of Current Research, 7(8), 73-85.
[6] Tempa, D. (2009). Reliability Assessment of Distribution Systems. A Case Study of Wangdue Distribution System in Bhutan, Masters Disssertation, Norwegian University of Science and Technology (NTNU), 1-9.
[7] Uhunmwangho, R. and Omorogiuwa, E. (2014). Reliability Prediction of Port-Harcourt Electricity Distribution Network using Neplan. The International Journal of Engineering and Science. 3(12), 68-79.
[8] Emjedi, M.R., Awode, K., and Chowdhury, S.P. (2010). Reliability Evaluation of distribution Network using Fuzzy Logic, IEEE PES General Meeting, 10.1109, 1-8.
[9] Perekebina, E. & Patrick, A. U. (2022). Reliability Analysis of a Distribution Network using ETAP software. Journal of Science, Technology and Education, 10(2), 228-236.
[10] Olumuyiwa, A.A., Evans, C.A., & Emmanuel, E. (2020). Reliability Assessment on Secondary Distribution Network: Case study of Karu substation in Abuja, Nigeria. Academic Journal of Current Research, 7(8), 73-85
[11] Akhikpemelo, A., Eyibo, N., Adeyi, A. (2016). Reliability Analysis of Power Distribution Network. Continental Journal of Engineering Sciences, 11 (2), 53 - 63.
[12] Jaya, C. K., Rajan P., Sunitha, and Matthew, Dr. (2017). Reliability Analysis of 11Kv Distribution feeder: A case study, 10(1), 1382-1385.
[13] Onime, F. and Adegboyega, G. A. (2014). Reliability Analysis of Power Distribution System in Nigeria. A case Study of Ekpoma Networks, Edo State. International Journal of Electronics and Electrical Engineering. 2(3), 175-182
[14] Goel, L. (2000). Monte Carlo Simulation-based Reliability Studies of a Distribution Tests System. Electric Power Systems Research, 54(1), 55-56.