A method of monitoring cleaning of an apparatus for applying a coating medium to an object, the apparatus including a rotatable deflecting element for atomizing the coating medium; and a cleaning medium line for conducting a cleaning medium to the deflecting element; where the method including commanding performance of a cleaning operation including delivery of the cleaning medium through the cleaning medium line towards the deflecting element while rotating the deflecting element; collecting operational values of at least one operational parameter of the apparatus for the cleaning operation; comparing the operational values with reference values of the at least one operational parameter for the cleaning operation; and determining whether the cleaning operation was successful or unsuccessful based on the comparison. A method of cleaning an apparatus for applying a coating medium to an object is also provided.

The invention provides apparatus for spray coating of substrates using a rotary bell cup atomizer equipped with an air-driven main turbine and a supply of pressurized primary shaping air conveyed through primary shaping air channels and nozzles for controlling the shape of the atomized spray pattern exiting the bell cup edge, the apparatus further including an auxiliary, independently air-driven turbine equipped with a rotatable vortex generator, and including a separate air supply of secondary shaping air for supplying secondary shaping air through secondary air channels and nozzles to further control the shape of the atomized spray pattern exiting the bell cup, which secondary shaping air, on passing through the vortex generator, produces a curtain of shaping air in a vortex-like pattern, which, in conjunction with and mixing with the primary shaping air from the primary air nozzles, produces improved pattern control, transfer efficiency and quality of coating on the substrate.

A rotary atomizer for atomizing a coating material for the coating of workpieces having a housing, a turbine wheel which is arranged in the housing and can be driven in two directions of rotation, a bell cup can be set in rotation by the turbine wheel about an axis of rotation and also a device for determining a rotational speed, wherein the device comprises an optical waveguide and a disc, which is indirectly or directly connected to the bell cup or the turbine wheel for rotation therewith and has an optically detectable structure, wherein the optical waveguide is designed for recording the optically detectable structure and for passing on the recorded structure as an optical signal in the housing. The optical waveguide has a first information channel and a second information channel, which are respectively designed for passing on an optical signal independently of one another.

A method of monitoring cleaning of an apparatus for applying a coating medium to an object, the apparatus including a rotatable deflecting element for atomizing the coating medium; and a cleaning medium line for conducting a cleaning medium to the deflecting element; where the method including commanding performance of a cleaning operation including delivery of the cleaning medium through the cleaning medium line towards the deflecting element while rotating the deflecting element; collecting operational values of at least one operational parameter of the apparatus for the cleaning operation; comparing the operational values with reference values of the at least one operational parameter for the cleaning operation; and determining whether the cleaning operation was successful or unsuccessful based on the comparison. A method of cleaning an apparatus for applying a coating medium to an object is also provided.

A spreader for spreading a material including at least one pair of rotating discs having a plurality of generally radially oriented blades attached thereon for disbursing the material in a pre-selected pattern. The discs are rotatably positioned below an end of a funnel unit to receive material passing through the funnel units. The material, as it passes through the funnel units, is directed to a predetermined impact region on each of the rotating discs by a corresponding pair of deflecting vanes integrally fit and movably attached within each funnel of the pair of funnel units. Each deflecting vane is selectably movable by a corresponding actuator from a first position to a second position while the spreader is operating.

Present disclosure provides a substrate processing apparatus, including a rotatable pedestal configured to hold a substrate, a driving mechanism connected to the rotatable pedestal, a liquid pouring nozzle over the pedestal, a temperature sensor configured to probe a temperature of the substrate processing apparatus, and a controller communicating with the temperature sensor and the driving mechanism. Present disclosure also provides a method for processing a substrate, including providing a substrate on a pedestal of a processing chamber, probing a temperature of the processing chamber, calculating a temperature difference between the temperature of the processing chamber and a predetermined temperature, and determining a rotational speed difference with respect to a predetermined rotational speed of the pedestal according to the temperature difference.

A rotary coating sprayer including a spray bowl rotating about an axis of rotation and an air turbine for driving the bowl. The turbine includes a rotor and a body forming a support for the rotor and defining at least one air feedline for a rotation chamber wherein the rotor blades are arranged. The feedline includes an intermediate chamber defined, radially to the rotation axis, between the body and a ring mounted around the body. In this way, lowering of temperature of an element of the sprayer housing due to flow of exhaust air from the turbine, is limited.

A nozzle assembly with a data logger. The nozzle apparatus assembly comprises a housing body and a tubular nozzle shaft coupled to a nozzle head. The tubular nozzle shaft and the nozzle head define a portion of a fluid pathway extending from an inlet end of the housing body to a set of directional nozzles. The tubular nozzle shaft and the nozzle head are configured to rotate together in response to a discharge of a pressurized liquid from the set of directional nozzles. A data logger housed within the housing body includes a rotation sensor configured to detect rotation of the tubular nozzle shaft or the nozzle head, a data storage device configured to store rotation data captured by the rotation sensor or rotational speed data calculated from the rotation data and time data, and a communications interface configured to transmit the stored data to a remote computing device.