Variable air assistance system for orchard sprayers; concept, design and preliminary testing

Conventional air-assisted sprayers with hydraulic nozzles generate large radial spray plumes which produce significant off-target losses and can consume high power (20–30 kW). Also, it is not uncommon to see these machines treating dwarf orchards, where the spray losses at the full leaf stage may be...

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Bibliographic Details
Published in:Biosystems engineering 2017-11, Vol.163, p.134-149
Main Authors: Hołownicki, Ryszard, Doruchowski, Grzegorz, Świechowski, Waldemar, Godyń, Artur, Konopacki, Paweł J.
Format: Article
Language:English
Subjects:
Adjustable impeller
Air-jet system
Precision agriculture
Variable rate technology
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Summary:Conventional air-assisted sprayers with hydraulic nozzles generate large radial spray plumes which produce significant off-target losses and can consume high power (20–30 kW). Also, it is not uncommon to see these machines treating dwarf orchards, where the spray losses at the full leaf stage may be over 80% of applied spray volume. Significant reductions in spray losses can be obtained with targeted and wind-oriented airflow adjustment. The objectives of the presented studies were to develop an energy saving variable air assistance (VAA) system with continuous real-time adjustment of air volume and with spraying systems mounted on both sides of the sprayer. The system is based on a double axial fan system which allows for remote adjustment of air volume. The nominal air output was 20,000 m3 h−1, for use in typical dwarf and semi-dwarf orchards, and this was designed to be obtained with 10 kW power consumption. The system used variable speed impellers with fixed blades which showed greater suitability than a method with adjustable pitch blades working at constant speed because it provided a wider range of air volumes (±35%). The air volumes produced could be continuously adjusted to obtain airflow profiles, on both sides of the sprayer that were almost symmetrical. The results obtained in tests appear to meet the objectives and, therefore, the VAA system can be considered as a suitable prototype platform for variable rate technology and future intelligent orchard sprayers. •Asymmetric variable air-flow discharge system for orchard sprayers was developed.•Better air distribution uniformity was obtained than for conventional sprayers.•Variable speed impeller showed greater suitability for intelligent sprayers.•The proposed system decrease the power consumptions of the sprayer by 50%.
ISSN:1537-5110
1537-5129
DOI:10.1016/j.biosystemseng.2017.09.004