A sealant discharging nozzle includes a nozzle body, a through hole, a discharge port, and a cutout. The through hole is provided in the nozzle body and extends along a central axis of the nozzle body. The discharge port is an opening of the through hole provided in an end surface of the nozzle body. Compared with a width of the discharge port in a first direction orthogonal to the central axis, a width of the discharge port in a second direction orthogonal to the central axis and the first direction is small. The cutout is formed on a first side in a first direction with respect to the discharge port.

An agricultural application is provided herein that includes a nozzle assembly positioned along a boom assembly and configured to selectively dispense an agricultural product therefrom. One or more sensors can be operably coupled with the boom assembly and can be configured to capture data associated with one or more application variables. A computing system can be communicatively coupled to the one or more sensors and to a display. The computing system can be configured to receive the data associated with the one or more application variables; convert the one or more application variables to a scaled integer to determine a spray quality index; generate a geo-located application map of the scaled integer; and present the geo-located application map on the display.

An agricultural application system can include a nozzle assembly positioned along a boom assembly and can be configured to selectively dispense an agricultural product therefrom. One or more sensors can be operably coupled with the boom assembly and configured to capture data associated with first and second application variables. A controller can be communicatively coupled to the one or more sensors. The controller can include a processor and associated memory. The memory can store instructions that, when implemented by the processor, configure the controller to receive the data associated with the one or more application variables and calculate the spray quality index. The first application variable can have a first scaling factor and a second application variable can have a second scaling factor. The second scaling factor may differ from the first scaling factor.

The invention relates to a coating method for coating a component surface (4) with a coating agent, in particular for painting a motor vehicle body component with a paint, having the following steps: ⋅ emitting a spray jet (1) of the coating agent onto the component surface (4) of the component to be coated by means of an atomizer (2), said spray jet (1) having a main axis (5) and having an asymmetry with respect to the main axis (5) such that the spray jet (1) generates a spray pattern with a corresponding asymmetry on the component surface (4), and ⋅ at least partially compensating for the asymmetry of the spray jet (1) such that the asymmetry of the resulting spray pattern on the component surface (4) is reduced. The invention further relates to a corresponding coating device.

A method and a device for evaluating atomization efficiency of an electric atomizer. The method includes: obtaining an idling power consumption according to an idling voltage and an idling current of an electric atomizer to be measured when idling; obtaining a working power consumption according to a working voltage and a working current of the electric atomizer when liquid pesticide flows into the electric atomizer; obtaining atomization parameters after the electric atomizer atomizes the liquid pesticide; and calculating the atomization efficiency of the electric atomizer according to the idling power consumption, the working power consumption and the atomization parameters. The atomization efficiency of the electric atomizer for aerial application of pesticides during application process is quantitatively evaluated, which provides important indicators for testing the working performance of the electric atomizer and fills in the technical gaps in the testing of traditional equipment for aerial application of pesticides.

Aerosol jet printing is a popular digital fabrication method for flexible and hybrid electronics, but it lacks sophisticated process control architectures that would enable more widespread adoption in manufacturing environments. An optical measurement system can be used to track the aerosol density upstream of the printhead. For example, the measured optical extinction combined with the aerosol flow rate, is directly related to deposition rate and accurately predicts functional properties, for example electrical resistance. This real-time system offers a compelling solution for process drift and batch-to-batch variability, a valuable tool for more fundamental studies of the process science, and a viable technology to support real-time control of aerosol jet printing.

A method for optimizing a rotation angle of an outlet of an atomizing nozzle is provided. The atomizing nozzle includes a nozzle core and a nozzle body. The method includes the following steps: measuring an outlet flow rate Q.sub.0 of the atomizing nozzle under a rated working pressure when an outlet clearance between the nozzle core and the nozzle body is δ=0; setting the outlet clearance between the nozzle core and the nozzle body by changing a phase angle between the nozzle core and the nozzle body, and measuring an outlet flow rate Q.sub.1 of the atomizing nozzle in a stable working state under the rated working pressure; calculating a flow coefficient of the atomizing nozzle; calculating the outlet clearance of the atomizing nozzle according to an expected outlet flow rate Q.sub.2 of the atomizing nozzle and the flow coefficient of the atomizing nozzle.

An agricultural spreader includes at least one delivery conduit that carries material to be spread from a bin to an exit end of the delivery conduit under the influence of air blown through the delivery conduit by a fan. A deflector is mounted proximate the exit end of the delivery pipe and deflects the material onto agricultural field in a dispersal area. A radio frequency (RF) transmitter is disposed to generate an RF signal that passes through the dispersal area. The RF signal is detectably changed when interacting with the material passing through the dispersal area. An RF receiver is disposed to receive the RF signal after the RF signal passes through the dispersal area and provides an output indicative of the RF signal. A controller is coupled to RF receiver and detects plugging of the delivery conduit based on the output of the RF receiver.

The disclosure relates to a coating installation for coating components with a coating agent, in particular for painting motor vehicle body components, with a nozzle applicator, in particular a print head, with at least one nozzle for delivering a coating agent jet of the coating agent onto the component to be coated. The disclosure provides a device for preventing and/or detecting clogging of the nozzle.

A system having a boom; a plurality of cameras attached to the boom; and a plurality of lenses on each camera; wherein not all lenses have a same field of view.