Hydraulic-based fixed spray delivery system: Homogeneity distribution among emitters and internal cleaning performances evaluation

[1]  Heping Zhu,et al.  Advanced spraying systems to improve pesticide saving and reduce spray drift for apple orchards , 2023, Precision Agriculture.

[2]  P. Marucco,et al.  Special Issue on Precision Technologies and Novel Farming Practices to Reduce Chemical Inputs in Agriculture , 2023, Applied Sciences.

[3]  A. Miranda-Fuentes,et al.  Assessment of fine droplets (<10 μm) in primary airborne spray drift: A new methodological approach , 2023, Journal of Aerosol Science.

[4]  R. Salcedo,et al.  Key Technologies for an Orchard Variable-Rate Sprayer: Current Status and Future Prospects , 2022, Agronomy.

[5]  P. Balsari,et al.  Characterization of irrigator emitter to be used as solid set canopy delivery system: which is best for which role in the vineyard? , 2022, Pest management science.

[6]  L. Khot,et al.  Reservoir Units Optimization in Pneumatic Spray Delivery-Based Fixed Spray System for Large-Scale Commercial Adaptation , 2022, Sustainability.

[7]  D. R. Aimonino,et al.  UAV-spray application in vineyards: Flight modes and spray system adjustment effects on canopy deposit, coverage, and off-target losses. , 2022, The Science of the total environment.

[8]  E. Gil,et al.  Use of cover crops in vineyards to prevent groundwater pollution by copper and organic fungicides. Soil column studies. , 2022, Chemosphere.

[9]  Xuemin Wu,et al.  Spray performance evaluation of a six-rotor unmanned aerial vehicle sprayer for pesticide application using an orchard operation mode in apple orchards. , 2022, Pest management science.

[10]  D. Nuyttens,et al.  The effect of fan setting, air-conveyor orientation and nozzle configuration on airblast sprayer efficiency: Insights relevant to trellised vineyards , 2022, Crop Protection.

[11]  L. Khot,et al.  Effect of Emitter Modifications on Spray Performance of a Solid Set Canopy Delivery System in a High-Density Apple Orchard , 2021, Sustainability.

[12]  G. Zanin,et al.  Evaluation of a Fixed Spraying System for Phytosanitary Treatments in Heroic Viticulture in North-Eastern Italy , 2021, Agriculture.

[13]  D. Nuyttens,et al.  Field assessment of a pulse width modulation (PWM) spray system applying different spray volumes: duty cycle and forward speed effects on vines spray coverage , 2021, Precision Agriculture.

[14]  A. Galanty,et al.  Effects of application of plant growth promoters, biological control agents and microbial soil additives on photosynthetic efficiency, canopy vegetation indices and yield of common buckwheat (Fagopyrum esculentum Moench) , 2021, Biological Agriculture & Horticulture.

[15]  J. Arnó,et al.  Spatially variable pesticide application in vineyards: Part II, field comparison of uniform and map-based variable dose treatments , 2020, Biosystems Engineering.

[16]  A. Balafoutis,et al.  Spray Drift Generated in Vineyard during Under-Row Weed Control and Suckering: Evaluation of Direct and Indirect Drift-Reducing Techniques , 2020, Sustainability.

[17]  L. Khot,et al.  Comparison of within canopy deposition for a solid set canopy delivery system (SSCDS) and an axial–fan airblast sprayer in a vineyard , 2020 .

[18]  Y. Lan,et al.  Effect of Droplet Size Parameters on Droplet Deposition and Drift of Aerial Spraying by Using Plant Protection UAV , 2020, Agronomy.

[19]  L. Khot,et al.  Drift potential from a solid set canopy delivery system and an axial–fan air–assisted sprayer during applications in grapevines , 2019 .

[20]  Juan Agüera,et al.  Spray and economics assessment of a UAV-based ultra-low-volume application in olive and citrus orchards , 2019, Precision Agriculture.

[21]  Jiaqiang Zheng,et al.  Analysis of the variability of pesticide concentration downstream of inline mixers for direct nozzle injection systems , 2019, Biosystems Engineering.

[22]  L. Khot,et al.  Feasibility of a Solid set canopy delivery system for efficient agrochemical delivery in vertical shoot position trained vineyards , 2019, Biosystems Engineering.

[23]  M. S. Grando,et al.  A critical review of plant protection tools for reducing pesticide use on grapevine and new perspectives for the implementation of IPM in viticulture , 2017 .

[24]  Enrique Moltó,et al.  Sustainable Use of Pesticide Applications in Citrus: A Support Tool for Volume Rate Adjustment , 2017, International journal of environmental research and public health.

[25]  E. Moltó,et al.  Comparison between standard and drift reducing nozzles for pesticide application in citrus: Part II. Effects on canopy spray distribution, control efficacy of Aonidiella aurantii (Maskell), beneficial parasitoids and pesticide residues on fruit , 2017 .

[26]  Qin Zhang,et al.  Effect of emitter type and mounting configuration on spray coverage for solid set canopy delivery system , 2015, Comput. Electron. Agric..

[27]  I. Eleftherohorinos,et al.  Pesticide Exposure, Safety Issues, and Risk Assessment Indicators , 2011, International journal of environmental research and public health.

[28]  M. C. Butler Ellis,et al.  Bystander exposure to pesticide spray drift: new data for model development and validation. , 2010 .

[29]  M. Porto,et al.  Estimating the social cost of pesticide use: An assessment from acute poisoning in Brazil , 2009 .

[30]  I. Mani,et al.  Ultrasonic sensor-based automatic control volume sprayer for pesticides and growth regulators application in vineyards , 2023, Smart Agricultural Technology.

[31]  Lav R. Khot,et al.  Automated Solid Set Canopy Delivery System for Large-Scale Spray Applications in Perennial Specialty Crops , 2019, Transactions of the ASABE.

[32]  Peter Schulze Lammers,et al.  Residues and Cleaning Effects of a Direct Nozzle Injection System for Pesticide Application , 2011 .

[33]  P. Balsari,et al.  Internal cleaning of sprayers: assessment of cleaning agents use and development of a test bench to evaluate tank cleaning nozzles performance. , 2010 .

[34]  A. Landers,et al.  Current Progress in Development of a Fixed-Spray Pesticide Application System for High-Density Apple Plantings , 2009 .

[35]  Jiri Vondricka,et al.  Measurement of Mixture Homogeneity in Direct Injection Systems , 2009 .

[36]  G. Pergher,et al.  RECOVERY RATE OF TRACER DYES USED FOR SPRAY DEPOSIT ASSESSMENT , 2001 .

[37]  E. Dale Threadgill,et al.  Chemigation Via Sprinkler Irrigation: Current Status and Future Development , 1985 .