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RESEARCH ARTICLE
Contents Vol 43(8)

Irrigation controlled by a wetting front detector: field evaluation under sprinkler irrigation

R. J. Stirzaker A and P. A. Hutchinson B
+ Author Affiliations
- Author Affiliations

A Corresponding author. CSIRO Land and Water, PO Box 1666, ACT 2601, Australia. Email: Richard.stirzaker@csiro.au

B CSIRO Land and Water, Private Bag 3, Griffith, NSW 2680, Australia.

Australian Journal of Soil Research 43(8) 935-943 https://doi.org/10.1071/SR05005
Submitted: 7 January 2005  Accepted: 8 August 2005   Published: 8 December 2005

Abstract

The accuracy of scheduling irrigation to turf by sprinkler was evaluated using a simple wetting front detector that automatically switched the water off after the wetting front had reached a prescribed depth in the soil. The detector consists of a funnel-shaped container that is buried in the soil. When a wetting front reaches the detector, the unsaturated flow lines are distorted so that the water content at the base of the funnel reaches saturation. The free water produced is detected electronically and this provides the signal to stop irrigation. The performance of the detector was evaluated over 38 consecutive irrigation events to test the theory that the velocity of a wetting front depends on the difference in water content ahead of and behind the front. The experimental data plotting the irrigation amount permitted by the wetting front detectors as a function of the soil water content before and after irrigation yielded a linear relationship with a slope of 0.95 and a correlation coefficient of 0.73. Thus, if the soil is dry before irrigation the front will move slowly and an irrigation of long duration will be permitted, with the converse applying to wet soil. Independent monitoring of soil water content showed that irrigation was, for the most part, scheduled accurately. Irrigation interval was the key variable to control. When the interval was too short then over irrigation occurred.

Additional keywords: irrigation scheduling, soil moisture sensors, irrigation interval, irrigation uniformity, soil water content.


Acknowledgments

We thank Chris Drury for assisting with the field electronics, Chris Smith and Evan Christen for helpful comments on the manuscript and 3 insightful reviewers.


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