Improving aerial topdressing in New Zealand through particle ballistics modelling and accuracy trials

dc.citation.volume29en_US
dc.contributor.authorChok, SEen_US
dc.contributor.authorGrafton, MCEen_US
dc.contributor.authorYule, IJen_US
dc.contributor.editorCurrie, Len_US
dc.contributor.editorSingh, Ren_US
dc.coverage.spatialPalmerston North, New Zealanden_US
dc.date.available1/06/2016en_US
dc.date.finish-date11/02/2016en_US
dc.date.issued1/06/2016en_US
dc.date.start-date9/02/2016en_US
dc.description.abstractFixed wing aircraft are utilised in New Zealand to apply dry bulk fertiliser on hill country farms. The fertiliser is most often applied manually as a blanket rate over the entire farm. Previous study indicates that this yields a field coefficient of variation (CV), which is the standard deviation over the mean application rate, of 63 – 70%. The CV decreased to 44% when the hopper door was automatically controlled using aircraft installed global positioning system (GPS) in lieu of manual intervention by the pilot. This is comparable to fertiliser application by fully GPS enabled truck spreaders. Spreadmark® specifies that the transverse overlap CV should be 15% for nitrogen-based fertilisers and 25% for all other products; however transverse overlap tested CV is considerably different to field CV. Variation in aerial topdressing is a barrier to achieving these CV. These variables include wind conditions, topography, aircraft speed and fertiliser properties. Ravensdown Limited is upgrading their topdressing aircraft fleet with differential rate application technology (DRAT), which uses the automated hopper door and GPS to apply various application rates over specified target areas within a farm. The advantage of this system is that fertiliser can be applied to these areas with the largest potential benefit in terms of increase pasture productivity and reduced environmental impact. Two trials utilising cone shaped collectors were carried out at coastal sheep and beef farms to determine the DRAT system’s accuracy when applying two application rates. Proof of release maps, which is deduced from aircraft recorded data, showed the system was able to vary rate. The CV ranged between 34% and 56%. The CV can be further improved by using a granular fertiliser ballistics model that predicts the transverse and longitudinal spread patterns based on wind conditions, fertiliser properties and aircraft operation. Validation data for this model was collected in validation trials for superphosphate, urea and di-ammonium phosphate. A validated model can provide guidelines on the optimum conditions and settings for aerial topdressing.en_US
dc.description.confidentialFALSEen_US
dc.format.extent1-Sepen_US
dc.identifier.citationIntegrated nutrient and water management for sustainable farming, 2016, 29 pp. 1 - 9en_US
dc.identifier.eissn2230-3944en_US
dc.identifier.elements-id261930
dc.identifier.harvestedMassey_Dark
dc.identifier.issn0112-9902en_US
dc.identifier.urihttps://hdl.handle.net/10179/7908
dc.publisherFertilizer & Lime Research Centre Massey Universityen_US
dc.relation.isPartOfIntegrated nutrient and water management for sustainable farmingen_US
dc.source29th Annual Fertilizer and Lime Research Conference Workshopen_US
dc.titleImproving aerial topdressing in New Zealand through particle ballistics modelling and accuracy trialsen_US
dc.typeConference Paper
pubs.notesNot knownen_US
pubs.organisational-group/Massey University
pubs.organisational-group/Massey University/College of Sciences
pubs.organisational-group/Massey University/College of Sciences/School of Agriculture & Environment
pubs.organisational-group/Massey University/College of Sciences/School of Agriculture & Environment/Agritech
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