Simulating water distribution patterns for fixed spray plate sprinkler using the ballistic theory

<p>Ballistic simulation of the spray sprinkler for self-propelled irrigation machines requires the incorporation of the effect of the jet impact with the deflecting plate. The kinetic energy losses produced by the jet impact with the spray plate were experimentally characterized for different...

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Bibliographic Details
Main Authors: Sofiane Ouazaa, Javier Burguete, M. Pilar Paniagua, Raquel Salvador, Nery Zapata
Format: Article
Language:English
Published: Instituto Nacional de Investigación y Tecnología Agraria y Alimentaria 2014-07-01
Series:Spanish Journal of Agricultural Research
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Online Access:http://revistas.inia.es/index.php/sjar/article/view/5507
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Summary:<p>Ballistic simulation of the spray sprinkler for self-propelled irrigation machines requires the incorporation of the effect of the jet impact with the deflecting plate. The kinetic energy losses produced by the jet impact with the spray plate were experimentally characterized for different nozzle sizes and two working pressures for fixed spray plate sprinklers (FSPS). A technique of low speed photography was used to determine drop velocity at the point where the jet is broken into droplets. The water distribution pattern of FSPS for different nozzle sizes, working at two pressures and under different wind conditions were characterized in field experiments. The ballistic model was calibrated to simulate water distribution in different technical and meteorological conditions. Field experiments and the ballistic model were used to obtain the model parameters (<em>D<sub>50</sub></em>, <em>n</em>, <em>K<sub>1</sub></em>and <em>K<sub>2</sub></em>). The results show that kinetic energy losses decrease with nozzle diameter increments; from 80% for the smallest nozzle diameter (2 mm) to 45% for nozzle diameters larger than 5.1 mm, and from 80% for the smallest nozzle diameter (2 mm) to 34.7% for nozzle diameters larger than 6.8 mm, at 138 kPa and 69 kPa working pressures, respectively. The results from the model compared well with field observations. The calibrated model has reproduced accurately the water distribution pattern in calm (r=0.98) and high windy conditions (r=0.76). A new relationship was found between the corrector parameters (<em>K<sub>1</sub><sup>’</sup></em> and <em>K<sub>2</sub><sup>’</sup></em>) and the wind speed. As a consequence, model simulation will be possible for untested meteorological conditions.</p>
ISSN:2171-9292