The invention concerns a handheld, dynamically movable surface spattering device, comprising at least one nozzle means for an expelling of a spattering material onto a target surface and a nozzle control mechanism to control characteristics of the expelling of the nozzle means. Furthermore, it comprises a spattering material supply, a storage with desired spattering data, which is predefined and comprised in a digital image or CAD-model memorized on the storage, a spatial referencing unit, to reference the spattering device relative to the target surface and a computation means to automatically control the expelling by the nozzle control mechanism according to information gained by the spatial referencing unit and according to the desired spattering data is evaluated and adjusted by changing the characteristics of expelling of the nozzle means in such a way that the target surface is spattered according to the desired spattering data.

A liquid discharge apparatus to apply liquid to an application surface includes a head and processing circuitry. The head applies the liquid discharged from a nozzle to the application surface. The processing circuitry outputs abnormal discharge information of the nozzle. The abnormal discharge information is detected based on a shape of the liquid applied to the application surface.

An agricultural system can include a product application system including one or more nozzle assemblies. A sensing system can include at least one flow sensor operably coupled with the product application system and configured to capture data indicative of a flow condition within the product application system. A computing system is communicatively coupled to the product application system and the sensing system. The computing system can be configured to calculate a spray quality index based on data from the sensing system, detect a pressure drop within the product application system based on the data indicative of a flow condition within the product application system, and generate an output based on the spray quality index and/or the detection of one or more pressure drops in the product application system.

An agricultural system can include a first nozzle assembly positioned along a boom assembly and configured to selectively dispense an agricultural product therefrom. An airflow detection system can be configured to capture data indicative of one or more airflow sources. A computing system can be communicatively coupled to the first nozzle assembly and the airflow detection system. The computing system can be configured to receive, from the airflow detection system, the data associated with the one or more airflow sources and generate a first nozzle vector for the first nozzle assembly based at least in part on the data from the airflow detection system.

A vehicle surface simulation apparatus for mapping a nozzles spray pattern of a water leak tester configured to spray water onto an exterior of a vehicle. A jig of the apparatus can be configured to simulate a plurality of exterior surface portions of two different vehicles. The jig can include at least a first area configured to represent at least a portion of a side-view profile of the first vehicle and the second vehicle, and at least a second area configured to represent at least a portion of a front-view profile of the first vehicle and at least a portion of a rear-view profile of the second vehicle. The funnel can be supported in one of the areas such that a funnel inlet lies in a plane that represents a predetermined surface of the vehicle. The conduit can be in fluid communication with the funnel and the container.

The invention relates to an installation and a method for the metallic coating of a workpiece using a coating device, said coating device comprising a displaceable coating lance, by which a metal plasma jet can be generated to create a coating of metal particles. According to the invention, it is provided that the coating device with the coating lance and a measuring device for measuring the coating thickness are jointly integrated in the installation, and that the coating device with the coating lance as well as the measuring device are enclosed by a housing.

A coating production line system for coating work pieces comprises a coating powder, a coating apparatus, an inspection unit to measure the thickness of the applied coating, a conveyor unit to move the work pieces through the system, and a control unit to use thickness requirements and coating parameters to control the coating apparatus based on said coating parameters with a machine learning instance. A database comprises coating powder characteristics parameter as input vector for the machine learning instance for generating an output vector to control the coating apparatus being a first additional part vector. The control unit determines the coating quality based on a comparison between the thickness data acquired from the inspection unit and the retrieved thickness requirement data as second additional part vector. The first and second additional part vectors are fed back as additional parts to the next input vector for the machine learning instance.

A coating device includes: a stage transfer part including a first long shaft extending in a first direction and a second long shaft extending in a second direction intersecting the first direction; a stage tilting part disposed on the stage transfer part, where the stage tiling part swings about a first swing axis; a stage rotating part disposed on the stage tilting part, where the stage rotating part rotates about a first rotating axis intersecting the first swing axis; a stage aligning part disposed on the stage rotating part, where the stage aligning part includes a first short shaft extending in the first direction and a second short shaft extending in the second direction; and a stage disposed on the stage aligning part, wherein a coating target is seated on the stage, where the stage includes a monitoring camera disposed in a camera seating space defined inside the stage.

In certain embodiments, a system comprises a robot, a spray gun coupled to the robot and operable to spray a first predefined number of passes of a material onto a substrate at a first flow rate, and a measurement device operable to measure one or more properties of the material sprayed onto the substrate while the material is wet. The system further comprises an analyzer operable to determine a thickness of the wet material based on the one or more measured properties and calculate a second flow rate required to achieve a cured thickness of the material within a second predefined number of passes. The calculated second flow rate is based on the first predefined number of passes, an expected thickness of the wet material for one pass of the first predefined number of passes, the determined thickness of the wet material, and the first flow rate.

A coating apparatus and method allow for precise control of the application of a coating material on a substrate and provides a data recording system which is useful for certifying a coating job and assessing when and where any abnormalities occur.