Provided is a dual spray nozzle tip assembly having a geometry that is split into several sub components to enable robust manufacturing and assembly of the resulting nozzle. The nozzle tip assembly is configured to be attached to a device configured to provide a pressurized fluid and gas therefrom. The nozzle tip assembly comprising an elongated body defining a fluid lumen and at least one gas lumen between a distal end and a proximal end. The elongated body including at least an attachment profile, a straight portion, and an outlet region. The outlet region defines a shear nozzle in communication with the fluid lumen and at least one gas outlet in communication with the at least one gas lumen, the outlet region is configured to direct pressurized gas from the at least one gas outlet and to produce a desired spray pattern from the shear nozzle.

A sprayer includes a spray gun and a hopper. An air source provides compressed air to the sprayer to both eject fluid from the spray gun as a spray and to pressurize the hopper. The spray gun includes passages for providing compressed air to the nozzle for spraying and to the hopper for pressurizing the hopper. The spray gun further includes a relief valve for venting pressurized air from the hopper. The hopper receives the compressed air through a port in the hopper, and the compressed air assists the flow of material out of the hopper and into the spray gun.

A spray gun, in particular a pressurised air atomisation paint spray gun, in particular a hand-held pressurised air atomisation paint spray gun has at least one material nozzle for discharging a material to be sprayed, at least one air nozzle for outputting air, in particular air for atomising a material to be sprayed, air for changing the shape of a spray jet, and/or air for transporting an atomised spraying medium, and at least one air chamber, in particular an air chamber adjoining the air nozzle or at least one air outlet opening of the air nozzle in the upstream direction, for supplying the air nozzle with air. The spray gun also has at least one device for inputting and/or adjusting and/or detecting and/or determining and/or displaying the air pressure in the air chamber during operation of the spray gun.

An atomizer for applying a coating to a substrate includes a nozzle and at least one electrode. The nozzle defines a plurality of apertures. The nozzle includes a nozzle plate, a nozzle body, and an actuator. The nozzle plate defines the apertures. The nozzle body and an inner side of the nozzle plate define a reservoir in fluid communication with the first apertures. The actuator is configured to vibrate the nozzle plate to eject droplets of a liquid from the reservoir through the first apertures. The at least one electrode is configured to directly or indirectly electrostatically charge the droplets with a charge that repels the droplets from each other to reduce coalescence of the droplets before the droplets reach the substrate.

Various embodiments of a spray gun converter (100) and a spray gun system that includes such converter (100) are disclosed. The spray gun converter (100) includes a body (102) having a first end (104) configured for insertion into an air passage of a spray gun (11), a second end (106) having a converter fitting (108) configured for connection to a reservoir (30), and a reservoir air passage (110) extending through the body (102) from an inlet end (112) at the first end to an outlet end (114) on the converter fitting (108) at the second end. The spray gun converter (100) also includes a reservoir air control valve (116) that opens and closes the reservoir air passage (110).

A lithography apparatus includes a wafer chuck configured to hold a wafer, a fluid source configured to contain a fluid to be applied towards the wafer during a lithography process, a dispensing nozzle positioned above the wafer chuck and in fluid communication with the fluid source, the dispensing nozzle having an adjustable cross-section, and a mechanical mechanism operable to apply a force towards an outer surface of the dispensing nozzle to change the adjustable cross-section.

A system for applying an adhesive includes an air flow path for conveying compressed air and an adhesive flow path for conveying liquid adhesive. The system includes an air heater coupled to the air flow path and configured to heat the compressed air and a liquid adhesive heater coupled to the adhesive flow path and configured to heat the liquid adhesive. The system also includes an applicator positioned downstream from the air and liquid adhesive heaters. The applicator is configured to receive the liquid adhesive from the adhesive flow path and the compressed air from the air flow path. The applicator is further configured to spray the liquid adhesive from the applicator using the compressed air.

A method for analysing a device for spraying a pharmaceutical fluid product including the following steps: providing a spray head of a device for spraying a pharmaceutical fluid product, the spray head having a spray orifice; providing a receiving surface having a plurality of discrete contact zones separated by voids, the contact zones capable of being coated with a heat sensitive material, bringing the receiving surface to a temperature T2, passing a flow of compressed gas through the spray orifice, the flow of compressed gas at a temperature T1 which differs from T2, sending the flow of compressed gas at temperature T1 onto the receiving surface at temperature T2, visualising the impact zone for the flow of compressed gas on the receiving surface, and analysing the visualisation of the impact zone in order to determine whether the spray head complies with predetermined specifications.

A spray gun including a nozzle portion in which a substantially V-shaped groove is formed in a circular section of a truncated conical front end with a cone angle ranging from 20° to 90°, and an internal hole is opened as a liquid ejecting port by forming the substantially V-shaped groove; and a gas cap including a cap face which is provided with an atomized gas opening portion having an opening diameter larger than the circular section, the gas cap forming a circular slit-like gap between the gas cap and an outer periphery of the truncated conical front end, the gap being configured to eject gas for atomizing liquid. The circular section of the truncated conical front end has a diameter ranging from 0.8 mm to 2.8 mm. The atomized gas opening portion has the opening diameter equal to or larger than 1.0 mm and smaller than 3.0 mm.

In front view of the application nozzle, all of the pressurized air flow K and adhesive flow H are made to run parallel to each other in the vertical direction. Of the pressurized air flows K from the pressurized air hole b in the pressurized air plate, the two that are located on one side of the adhesive hole opening a and from a pair in the front-to-back direction are tilted so as to approach each other. The extension lines thereof are located on the side of the adhesive bead, which results from the adhesive flow discharged from the adhesive hole opening, and have directions that converge. The respective pressurized air flows on the two side of the adhesive bead are made to flow downward while uniting in the direction of convergence. A web in which the adhesive bead is elongated while being swung in the transverse direction is formed and, near the bottom surface of the application nozzle, a non-interference space Q is formed between the adhesive bead and the fore pressurized air flow. The adhesive bead, resulting from the adhesive flow discharged from the adhesive hole opening, and the pressurized air flows do not interfere with each other and walls R of pressurized air flows are formed below the non-interference space Q and on either side of the adhesive bead.