The disclosure relates to a coating method for coating a component with a coating agent, comprising the following steps: moving an application device over a component surface of the component to be coated, delivering a coating agent jet (9) from the application device to the component surface that is to be coated, defining switching points on the component surface for initiating a switching action, in particular for switching on or switching off a coating agent jet, and performing the switching action when one of the switching points is reached. The disclosure provides the following steps: marking the switching points on the component surface by generating a switching marking on the component surface at the individual switching points, detecting the switching markings corresponding to the individual switching points during movement of the application device, and performing the switching actions when the switching markings are detected on the component surface. The disclosure further includes a corresponding coating installation.

An assembly 10 for dispensing sanitiser fluid. The assembly 10 includes a post 12 having opposed ends 14, 16, a pedal 18 pivotally securable adjacent one of the ends 16 of the post 12, a platform 20 dimensioned to be received within the post 12, the platform 20 configured to support a reservoir containing the sanitiser fluid, an elongate member 22 dimensioned to extend between the pedal 18 and the platform 20 such that pivoting the pedal 18 moves the elongate member 22 to cause the platform 20 to be displaced along the post 12, a stop 24 securable to the post 12 to be operatively above the platform 20 such that, in use, the reservoir is urged against the stop 24 when the platform 20 is displaced to cause sanitiser fluid to be dispensed from the reservoir, and an open-topped receptacle 26 defining an internal space 28, the receptacle 26 securable to the post 12 to be operatively below the stop 24 to allow collecting dispensed fluid in the internal space 28.

A reaction apparatus comprising at least one tubular reaction unit (23), a container (41) configured to accommodate the tubular reaction unit (23) and a temperature control medium (51) used in heat exchange with the tubular reaction unit (23), and a nozzle (31) configured to eject the temperature control medium (51) toward the tubular reaction unit (23) in the container. The reaction apparatus further comprising a movable part (34) configured to adjust an ejection direction of the nozzle (31) is preferred. The reaction apparatus allows for effectively performing the temperature control even when the tubular reaction unit is immersed in a temperature control medium.

A fluid sprayer includes a housing defining a reservoir attachment portion, a pump supported within the housing, a nozzle assembly supported by the housing and located in fluid communication with the pump, and an electrostatic charging circuit configured to impart an electrostatic charge in a fluid pumped out of the nozzle assembly by the pump. The fluid sprayer also includes a first reservoir including a first latch configured to releasably secure the first reservoir to the reservoir attachment portion to fluidly couple the first reservoir to the pump. The fluid sprayer further includes a second reservoir including a tank, an adapter, and a hose fluidly connecting the tank to the adapter, the adapter including a second latch configured to releasably secure the adapter to the reservoir attachment portion to fluidly couple the tank to the pump.

A controller performs an adjustment processing including: forming a film on a surface of a substrate by a film forming unit; removing a peripheral portion of the film by the film forming unit; acquiring surface information indicating a state of the surface of the substrate including the film, from which the peripheral portion has been removed, by a surface inspection unit and adjusting a cut width of the peripheral portion based on the surface information; and peeling the film, from which the peripheral portion has been removed, by the film forming unit, and a process processing including: forming the film on the surface of the substrate by the film forming unit; and removing the peripheral portion by the cut width adjusted in the adjustment processing in the film forming unit.

A hydrogen production system according to an embodiment includes an evaporator that evaporates seawater to generate water vapor, an electrolytic device that electrolyzes the water vapor supplied from the evaporator to produce hydrogen, and a removal mechanism that is provided between the evaporator and the electrolytic device and removes a seawater component from the water vapor.

In order to provide an aerosol device (100) that makes it possible to provide an aerosol having an optimised composition, in particular optimised droplet size distribution, it is proposed that the aerosol device (100) should include the following: an aerosol casing (102); one or more aerosol nozzles (104) for generating an aerosol stream from a carrier gas and a liquid, wherein the one or more aerosol nozzles (104) are directed into an interior (106) of the aerosol casing (102) and/or are arranged in the aerosol casing (102); one or more carrier duct connection points (156) for connecting one or more carrier ducts (158), by means of which the aerosol is guidable away from the interior (106) of the aerosol casing (102).

In order to provide an aerosol device (100) that makes it possible to provide an aerosol having an optimised composition, in particular optimised droplet size distribution, it is proposed that the aerosol device (100) should include the following: an aerosol casing (102); one or more aerosol nozzles (104) for generating an aerosol stream from a carrier gas and a liquid, wherein the one or more aerosol nozzles (104) are directed into an interior (106) of the aerosol casing (102) and/or are arranged in the aerosol casing (102); one or more carrier duct connection points (156) for connecting one or more carrier ducts (158), by means of which the aerosol is guidable away from the interior (106) of the aerosol casing (102).

A method and apparatus include a housing, a metered core, and an air vortex core. The housing includes a first end and a second end. The housing includes an air inlet opening at the first end to receive air from a blower distinct from the apparatus and a fogging outlet opening to output a fog at the second end. The housing couples to a liquid container that stores a fogging liquid and to the blower. The metered core, disposed within the housing, includes a first plurality of radial angled fins to create a low-pressure zone within the housing which draws the fogging liquid from the liquid container into the housing. The air vortex core, disposed between the metered core and the fogging outlet opening, includes a second plurality of radial angled fins to mix the fogging liquid with the air and guide the fog exiting the housing at the fogging outlet opening.

A system and method for providing an electrostatic sprayer nozzle assembly for dispensing a fluid in a stream of charged particles. The nozzle assembly includes an interior chamber, a nozzle opening on the rear side for receiving a nozzle therethrough, an electrode within the interior chamber for providing a charge to the fluid particles, and a visor connected to an outer surface configured to redirect lost fluid that collects on the outer surface of the assembly back into the fluid stream.