Authors: A. Amogpai

Abstract:

Hydropower and solar photovoltaic (PV) generation are crucial in sustainability and transitioning from fossil fuel to clean energy. Integrating renewable energy sources such as hydropower and solar PV into the distributed networks contributes to achieving energy balance, pollution mitigation, and cost reduction. Frequent power outages and a lack of load reliability characterize the current South Sudan electricity distribution system. The country’s electricity demand is 300 MW; however, the installed capacity is around 212.4 MW. Insufficient funds to build new electricity facilities and expand generation are the reasons for the gap in installed capacity. The South Sudan Ministry of Energy and Dams gave a contract to an Egyptian Elsewedy Electric Company that completed the construction of a solar PV plant in 2023. The plant has a 35 MWh battery storage and 20 MW solar PV system capacity. The construction of Juba Solar PV Park started in 2022 to increase the current installed capacity in Juba City to 53 MW. The plant will begin serving 59000 residents in Juba and save 10,886.2 t of carbon dioxide (CO2) annually.

Keywords: Renewable energy, hydropower, solar energy, photovoltaic, South Sudan.

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 19

References:

[1] Adekanmi M. Adeyinka, Onyedika V. Mbelu, Yaqub B. Adediji, Daniel I. Yahya, A review of current trends in thin film solar cell technologies, International Journal of Energy and Power Engineering, vol: 17, No: 1, 2023.
[2] Salih. Z, Hasan. G, Mohammed. M, study the effect of integrating the solar energy source on the stability of electrical distribution system, 22nd, International conference on control systems and Computer Science (CSCS), 2019.
[3] Nwaigwe. K, Mutabilwa. P, Dintwa. E, an overview of solar power (PV systems) integration into electricity grids, Material Science for Energy Technologies 2 (2019) 629 – 633.
[4] Adefarati. T, Bansal. R, Integration of renewable distributed generators into the distribution system: a review, Journal of the Institute of Engineering and Technology, vol: No; 10, 973–884, 2016.
[5] Deng J 2022 Privatization and deregulation of electricity sector in South Sudan, International Journal of Strategic Energy and Environmental Planning, 4 18-34.
[6] Whiting, K, Amogpai, A., and Carmona, L G 2015, South Sudan: A review of Sustainable Energy Policy and Practices development. Investigación ambiental 7.
[7] Nhial M and Jok G 2018, Transitioning to renewable energy: An analysis of energy situation in Juba, South Sudan, Special report, the SUDD Institute.
[8] Liu, H Masera D, and Esser, L 2013 World Small Hydropower Development Report 2013. United Nations Industrial Development Organization; International Centre on Small Hydro Power.
[9] Amogpai A 2011. LED lighting combined with solar panels in developing countries. Doctoral Dissertation 110/2011 (Aalto University publication series) Finland.
[10] Amogpai A 2007 Energy and lighting usage in Sudan, (Helsinki University of Technology Press), Master Thesis, Finland.
[11] Lemi L 2020 Co-supplying the National Grid: An Assessment of Private Off-grid Electricity Generation in Juba-South Sudan, American Journal of Electrical Power and Energy Systems (2020) 9 47-59.
[12] Ayik. A, Ijumba. N, Kabiri. C, and Goffin. P (2023). Preliminary assessment of small hydropower potential using the soil and water assessment to model: a case study of central Equatoria state, South Sudan. Energy Reports 9 (2023) 229-2246.
[13] International Energy Agency 2003 Renewable for power generation: Status and prospects, OECD, Paris, France.
[14] World Bank (2021). South Sudan electricity sector diagnostic, Draft, Republic of South Sudan.
[15] Asr, F.T., Kazemeni, A.: ‘Modelling the impact of an automated and control on the reliability distribution system’. Proc. IEEE Electrical Power & Energy Conf., 2008.
[16] Atwa, Y.M., El-Saadany, E.F., Salama, M.M.A., Seethapathy, R.: ‘Optimal renewable resources mix distribution system energy loss minimisation’, IEEE Trans. Power Syst., 2010, 86, (1), pp. 360–370.
[17] Shobole. A, Baysal. M, Wadi. M, and Tur. M, Effects of distributed generations, integration to the distributed networks, case study of solar power plant, International Journal of Renewable Energy Research, Vol. No. 2, 2017.
[18] Michael. C, Mackay. M, Katz. J, Grid-Integrated Distributed Solar: Addressing Challenges for Operations and Planning, Greening the Grid, 2016.
[19] Belcher. B, Petry. B.J, Davis. T, Hatipoglu. K., The effects of major solar integration on a 21-Bus system: technology review and PSAT simulations, Conf. Proc. - IEEE SOUTHEASTCON, 2017.
[20] Gonzalez-Longatt, F.: ‘Impact of distributed generation over power losses on distribution system’. Proc. Ninth Int. Conf. Electrical Power Quality and Utilization (EPQU 2007), Barcelona, Spain, October 2007, pp. 1–6.
[21] Electric Power Research Institute. Available at http://www.epri.com/, accessed December 2023.
[22] CIGRE study committee: ‘Impact of increasing the contribution of dispersed generation on the power system’. Final Report, Technical Report, 37, 2003.
[23] Institute of Electrical and Electronics Engineers. Available at http://www.ieee.org, accessed December 2023.
[24] International Energy Agency (IEA): ‘Distributed generation in liberalized electricity markets’. OECD/IEA, Paris, France, 2002.