Movement of Irrigation Water in Soil from a Surface Emitter

Authors

  • Ibrahim Abbas Dawood, MSc student College of Engineering-University of Baghdad
  • Safa Noori Hamad, Prof. Dr. College of Engineering-University of Baghdad

DOI:

https://doi.org/10.31026/j.eng.2016.09.07

Keywords:

wetting patterns, trickle irrigation, wetted diameter, wetted depth.

Abstract

Trickle irrigation is one of the most conservative irrigation techniques since it implies supplying water directly on the soil through emitters. Emitters dissipate energy of water at the end of the trickle irrigation system and provide water at emission points. The area wetted by an emitter depends upon the discharge of emitter, soil texture, initial soil water content, and soil permeability. The objectives of this research were to predict water distribution profiles through different soils for different conditions and quantify the distribution profiles in terms of main characteristics of soil and emitter. The wetting patterns were simulated at the end of each hour for a total time of application of 12 hrs, emitter discharges of 0.5, 0.75, 1, 2, 3, 4, and 5 lph, and five initial volumetric soil water contents. Simulation of water flow from a single surface emitter was carried out by using the numerically-based software Hydrus-2D/3D, Version 2.04. Two approaches were used in developing formulas to predict the domains of the wetted pattern. In order to verify the results obtained by implementing the software Hydrus-2D/3D a field experiment was conducted to measure the wetted diameter and compare measured values with simulated ones. The results of the research showed that the developed formulas to express the wetted diameter and depth in terms of emitter discharge, time of application, and initial soil water content are very general and can be used with very good accuracy.

 

 

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How to Cite

“Movement of Irrigation Water in Soil from a Surface Emitter” (2016) Journal of Engineering, 22(9), pp. 103–114. doi:10.31026/j.eng.2016.09.07.

Publication Dates

Published

2016-09-01

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