Evaluation of Potential Reservoir Deficiency Due to Climate Change, Kesem Kebena Dam, Ethiopia

Main Article Content

Melese Chanie Shumie

Abstract

Flood is an excess inundation of water on a surface and difficult to manage. The flood occurred in previous decades of Afar region of Ethiopia, consequently, leads to the death of human beings, destruction of infrastructures, an annihilation of massive hydraulic structures, and downstream properties. The main responsible factors for the flood incidences of the region are climate change, global warming, deforestation, and desertification. Climate change, however, is the foremost reason of increasing flood hazard. To coincide with this, hydraulic structures are designed based on the previously recorded flow data of a river. In Ethiopia, numerous earthen dams are constructed. The water storage capacity of dams is determined by the appraised flood of the upstream catchment: however, when the catchment flood increases due to climate extremes, the constructed structures cannot carry and going to demolish. The extra water that rises due to climate change from the catchment has to be removed before joins to the reservoir. This study has evaluated the potential reservoir deficiency of Kesem Kebena dam due to climate change. The study has comprehended different methods based on scientific criteria and selects the appropriate measure. As per the research output, the excess water that will arise from the catchment and add to the reservoir can be controlled by diversion floodways (Emergency spillways). The study has determined the amount of excess flood join to the reservoir for the excess rainfall incident month (August) for 100 years return period. Its magnitude is 85.76m3/s. The emergency spillway is the best means to divert such unwanted water before joining to the reservoir. Its hydraulic design is discussed in the study.

Downloads

Download data is not yet available.

Article Details

How to Cite
Shumie, Melese Chanie. 2019. “Evaluation of Potential Reservoir Deficiency Due to Climate Change, Kesem Kebena Dam, Ethiopia”. Journal of Environmental Geography 12 (1-2):33-40. https://doi.org/10.2478/jengeo-2019-0004.
Section
Articles

References

Abaya, S. W. 2008. Floods and Health in Gambella region, Ethiopia: An Assessment of the strength and weakness of the coping mechanism. M.Sc. Thesis, Lund University. Available at: https://www.lumes.lu.se/sites/lumes.lu.se/files/samson_abaya.pdf

Arora, K. R. 2012. Irrigation, Water Power and Water Resources Engineering. Standard Publisher Distribution, Delhi. ISBN: 81-8014-007-5. 1106 p

Asfaw, H. B., Essen, P. V., Tsige, T.Z. 2014. Background Information for a Program Approach Challenges and possible cooperation between Dutch and Ethiopia counterparts Integrated water resources management Upper Awash River Basin, Central Ethiopia. Waterschap. Online available at: http://www.waterethiopia.org/wp-content/uploads/2014/03/Background-information-for-a-Program-Approach-Challenges-and-Possible-Cooperation-between-Dutch-and-Ethiopia-counterparts.pdf

Botto, A., Ganora, D., Laio, F., Claps, P. 2014. Uncertainty compliant design flood estimation. Water Resources Research 50 (5) 4242–4253. DOI: 10.1002/2013wr01498110.1002/2013wr014981

Chow, V. T., Maidment, D. R., Mays, L. W. 1988. Applied Hydrology. The McGraw-Hill Companies. New York, 572.

Cowin, M. W., Bardini, G. B. 2011. Central Valley Flood Protection Plan. Floodsafe, California. Online available at: https://water.ca.gov/LegacyFiles/floodsafe/fessro/docs/flood_tab_cvfpp.pdf

Garg, S.K. 2006. Irrigation Engineering And Hydraulic Structures. Khanna Publishers, Delhi, India. 1184 p.

Haile, A. T., Kusters, K., Wagesho, N. 2013. Loss and damage from flooding in the Gambela region, Ethiopia. International Journal of Global Warming 5(4) 483–497. DOI: 10.1504/ijgw.2013.05729010.1504/ijgw.2013.057290

Hudson, H. R., Harding, J. S. 2004. Drainage management in New Zealand. Wellington: Department of Conservation. 39p.

Onwuka, S., Ikekpeazu, F. O., Onuoha, D. C2015. Assessment of the causes of 2012 floods in Aguleri and Umuler, Anambra East local government area of anambra sstate, Nigeria. British Journal of Environmental Sciences 541, 43–57.

Ranghunath, H. 2006. Hydrology: Principle, design and Analysis.: New Age International (P) Limited, New Delhi, 476 p.

Salas, J. D., Govindaraju, R. S., Anderson, M., Arabi, M., France´s, F., Suarez, W. 2014. Introduction to Hydrology. In: Wang L.K., Yang C. T. Modern Water Resources Engineering, 1–126.. DOI: 0.1007/978-1-62703-595-8_1

Shemeles, P. 1998. Establishing water release rules for Koka reservoir for wet seasons. MSc Theses, Addis Ababa: Addis Ababa University, Online available at: http://etd.aau.edu.et/handle/123456789/2070?show=full

Shaw, E. M. 2005. Hydrology in Practice. London, Taylor and Francis e-Library, 613 p.

Stephens, D. B. 2012. Sonoma Valley Stormwater Management and Groundwater Recharge Scoping Study Screening Evaluation and Prioritization Memorandum, 1-46. Online available at: http://www.scwa.ca.gov/files/docs/projects/stormwater-groundwater/Sonoma_Scoping_Screening_Memo_Final-Memo+Plates.pdf

Suykens, C., Priest, S. J., van Doorn-Hoekveld, W. J., Thuillier, T., Rijswick, M. V. 2016. Dealing with flood damages: will prevention, mitigation, and ex post compensation provide for a resilient triangle? Ecology and Society 21(4), 1–17. DOI: 10.5751/es-08592-21040110.5751/es-08592-210401

Wobus, C., Gutmann, E., Jones, R., Rissing, M., Mizukami, N., Lorie, M. 2017. Climate change impacts on flood risk and asset damages within mapped 100-year floodplains of the contiguous United States. Natural Hazards and Earth System Sciences 17, 2199–2211. DOI: 10.5194/nhess-17-2199-201710.5194/nhess-17-2199-2017

WWDSE, 2006. Hydrologic Design Report of Kesem Kebena Dam and Irrigation Project. Water Works Design Supervision Enterprise, Addis Ababa, Ethiopia.