This paper deals mainly to study and solve field drainage problems in Kamal El-Den Hessen new reclaimed area (1650 hectares), North Sinai Egypt, where many farmers complain about the formation of water ponds in their lands, bad soil drainage, soil salinity, and low yields rate. Intensive field investigations were carried out regarding, topographic survey, digging 22 boreholes, instilling observation wells, measuring groundwater salinity and assessing the existing drainage network. The results showed that ground surface levels were ranging from 1.5 m to 4.28 m above mean sea level, predominated soil was sandy with a permeability coefficient ranged from 0.82 to 2.68 m/day, an impervious clay layer lies at 6.0 to 7.0 m below ground surface, and the groundwater salinity ranges from 4 to 12 dS/m high salinity for water ponds were observed at the observation wells that lay in the lift side of Kamal El-Den Hessen Canal. Lands surrounding Kamal El-Den Hessen Canal have high levels. The measured groundwater depths of the western observation wells were 0.50 m below ground surface and in the eastern wells ranging from 1.0 to 1.50 m. The analysis of results showed that field drainage problems that increased groundwater levels were: 1) infiltration water coming from the high-cultivated areas at the lift bank of Kamal El-Den Hessen Canal, 2) the impervious clay layers increasing the horizontal infiltration towards low lands and increase ponds areas. 3) Main Gelbana Drain cross-section needs dredging. It is recommended to dredge the Main Gelbana Drain and modified its cross-section to collect water from water ponds, filling the lowland areas utilizing sandy soil in the high lands, adopting types of crops grown to match with crop salt tolerant levels and soil and water salinity levels and constructing subsurface drainage network to decrease groundwater levels.
References
[1]
Mohamed, G. and Medhat, E.L. (2018) Study of the Quality of Irrigation Water in South-East El-Kantara Canal, North Sinai, Egypt. IJESD, 9, 142-146. https://doi.org/10.18178/ijesd.2018.9.6.1089
[2]
Abel, C., Dumisani, K., Tapiwanashe, M., and Pardon C. (2014) An Assessment of Irrigation Water Quality and Selected Soil Parameters at Mutema Irrigation Scheme, Zimbabwe. Journal of Water Resource and Protection, 6, 132-140. https://doi.org/10.4236/jwarp.2014.62018
[3]
Adris, B., Recep, C., Suat, N. and Pinar, B. (2008) Estimating the Effect of Controlled Drainage on Soil Salinity and Irrigation Efficiency in the Harran Plain Using SaltMod. Turkish Journal of Agriculture and frosty, 32, 101-109.
[4]
Ayars, J.E., Christenb, E.W. and Hornbuckleb, J.W. (2006) Controlled Drainage for Improved Water Management in Arid Regions Irrigated Agriculture. Agricultural Water Management, 86, 128-139. https://doi.org/10.1016/j.agwat.2006.07.004
[5]
Bahceci, I. and Nacar, A.S. (2008) Subsurface Drainage and Salt Leaching in Irrigated Land in South East Turkey. International Journal of Irrigation and Drainage, 58, 346-356.
[6]
Hefdhallah, A., Shahien, M., Ogila, W. and Rabie, N. (2013) Drainage Management of Excess Irrigation Water in Arid Area. Proceedings of the Sixth International Perspective on Water Resources and Environment, ASCE, Izmir.
[7]
Ritzema, H., Kselik, R. and Fernando, C. (1996) Drainage of Irrigation Lands. Irrigation Water Management Training Manual No. 9, FAO.
[8]
Ayars, J., Richard, Ir. and Evan, W. (2003) Managing Salinity for Sustainability of Irrigation in Areas With Shallow Saline Ground Water. Proceedings of the 9th International Drainage Workshop, Paper No. 062, Utrecht.
[9]
Brouwer, C., Goffeau, A. and Heibloem, M. (1985) Irrigation Water Management: Training Manual No. 1—Introduction to Irrigation, FAO—Food and Agriculture Organization of the United Nations, Rome.
[10]
Abdel-Dayem, S. (2000) Drainage Experiences in Arid And Semi-Arid Regions. The World Bank, Washington DC.
[11]
Sharma, P. and Tyagi, K. (2004) On-Farm Management of Saline Drainage Water in Arid and Semi-Arid Regions. International Journal of Irrigation and Drainage, 53, 87-103. https://doi.org/10.1002/ird.115
[12]
Boumans, J.H. (1987) Drainage in Arid Regions. Proceedings of the 25th International Course on Drainage, Arnhem, Keynote Lectures, 22-43.
Lambert, K., Willem, F. and David, W. (2004) Modern Land Drainage Planning, Design and Management of Agricultural Drainage Systems. A.A. Balkema.
[15]
Craig, R. (2004) Craig’s Soil Mechanics. 7th Edition, Taylor & Francis Group.
[16]
John, M., Michael, R., Eugene, H., Michael, K. and Richard, M. (1999) Forest Drainage Engineering. A Design Manual, COFORD National for Forest Research and Development, Agriculture Building, University Collage Dublin, Ireland.
[17]
Fox, G.A., Wilson, G.V., Simon, A., Langendoen, E.J., Akay, O. and Fuchs, J.W. (2007) Measuring Stream Bank Erosion Due to Ground Water Seepage: Correlation to Bank Pore Water Pressure, Precipitation and Stream Stage. Journal of Earth Surface Processes and Landforms, 32, 1558-1573. https://doi.org/10.1002/esp.1490
[18]
Ouria, A. and Toufigh, M. (2009) Application of Nelder-Mead Simplex Method for Unconfined Seepage Problems. Journal of Applied Mathematical Modeling, 33, 3589-3598. https://doi.org/10.1016/j.apm.2008.12.001
[19]
Perzlmaier, S., Muckenthaler, P. and Koelewijn, A.R. (2007) Hydraulic Criteria for Internal Erosion in Cohesionless Soil. Proceedings of Assessment of the Risk of Internal Erosion of Water Retaining Structures: Dams, Dykes and Levees—Intermediate Report of the European Working Group of ICOLD, Contributions to the Symposium in Freising, Germany.
[20]
Shaban (2017) Statistical Framework to Assess Water Quality for Irrigation and Drainage Canals. International journal of Irrigation and Drainage, 66, 103-117. https://doi.org/10.1002/ird.2042
APHA, AWWA and WEF (2012) Standards Methods for the Examination of Water and Wastewater. 22nd Edition.
[23]
Phocaides, A. (2007) Technical Hand Book on Pressurized Irrigation Techniques. 2nd Edition, Food and Agriculture Organization of the United Nations (FAO), Rome. http://www.fao.org/docrep/010/a1336e/a1336e00.htm
