| 应用领域 |
其他 |
| 检测样本 |
其他 |
| 检测项目 |
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| 参考标准 |
暂无 |
The mass balance of orchard air-blast sprayers has historically been assessed using an array of samplers
to capture airborne particles. However, these methods only provide an idea of flux with no other information
which is pertinent to understand the movement of droplets and their potential to drift. While
droplet analysis for agricultural sprayers has always been conducted in a laboratory setting with the use
of laser devices, a new phase Doppler approach is being explored to assess droplet spectra, velocity, and
flux in outdoor field conditions. Therefore it is the objective of this study to develop a methodology and
the potential limitations for using a phase Doppler system while in a laboratory setting. Due to the
expected variability of field conditions as well as the turbulence of orchard sprayers, a computational
approach was sought to assess flux from a single scan of a conical spray plume's diameter. Using a
constant scanning speed of 0.0079 m/s, a disc core (D1/DC33) hollow cone nozzle was examined at 310,
410, and 520 kPa pressure at five different heights (10, 20, 30, 40, and 50 cm). Computational flux was
then compared to the actual flow rate, finding a �3.3% average error with a range of �16.9% and 4.7%
illustrating a small underestimation of mass with the phase Doppler which was related to distance and
droplet frequency. Further, comparisons were also assessed including pattern/symmetry, droplet spectra,
velocity, and the overall number of samples. The proposed methodology indicates potential for the use of
phase Doppler technology for in situ measurements of spray equipment using a conical-type spray
nozzle, such as that of the orchard air-blast sprayer.
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