A gas atomization nozzle includes a through-hole formed along a center line; a nozzle portion configured of a Laval nozzle which is disposed around the center line and provided to be inclined at a predetermined angle toward the center line; and swirling motion imparting means for imparting a swirling flow around the center line to gas which is injected from the nozzle portion. The nozzle portion is formed in a ring shape which is continuous around the center line, and the swirling motion imparting means is configured as a fin provided in the nozzle portion to impart a swirling flow.

A delivery nozzle for aerosol and solvent includes a nozzle body defining an aerosol passage and a solvent passage therethrough. The aerosol and solvent passages each extend from an inlet end of the nozzle body to an outlet end thereof. The nozzle body can include a solid, unitary structure with the aerosol and solvent passages both defined through the solid, unitary structure. The inlet end of the nozzle body can include a mounting flange configured to mount the nozzle body in a device for delivering aerosol through the aerosol passage and for delivering solvent through the solvent passage. The solvent passage can define a smaller cross-sectional flow area than that of the aerosol passage.

A method for producing a printer nozzle (12, 122, 200) for dispensing a molten material, which has a nozzle body with a receiving section (20) and an outlet section (22, 222) which is, in particular, in the shape of a cone or truncated cone, characterized by the method steps of injection molding powder containing metal and sintering.

Systems, apparatuses, and methods for reducing humidity of air adjacent to a nozzle of an electrospinning apparatus, charged solution output by the nozzle, a solution path between the nozzle and a deposit surface, and/or the deposit surface. The apparatus can be configured to controllably output the charged solution and gas of a predetermined dryness for deposit of the charged solution on the deposit surface. The gas of the predetermined dryness can be provided adjacent to a nozzle tip of the nozzle from where the charged solution is output. The gas of the predetermined dryness may be output in a predetermined direction toward a focal point at, in front of, or behind the nozzle tip.

The present invention provides a potable pneumatic atomizing device. It includes a mounting seat, a small type fan, a water tank, an ultrasonic atomizing piece and a fixing clip. The small type fan and the water tank are respectively installed on the upper part and the side part of the mounting seat, and an air passage is formed among the small type fan, the water tank and the mounting seat; the mounting seat is provided with a lifting support frame, the lifting support frame stretches the clothes to extend the gap between the clothes and the human body. The ultrasonic atomizing piece is arranged on the top of the water tank and atomizes water in the water tank to release into the gap between clothes and the human body. The small type fan transfers outside air into the air passage, then passing the air passage, into the gap.

The present invention provides a potable pneumatic atomizing device. It includes a mounting seat, a small type fan, a water tank, an ultrasonic atomizing piece and a fixing clip. The small type fan and the water tank are respectively installed on the upper part and the side part of the mounting seat, and an air passage is formed among the small type fan, the water tank and the mounting seat; the mounting seat is provided with a lifting support frame, the lifting support frame stretches the clothes to extend the gap between the clothes and the human body. The ultrasonic atomizing piece is arranged on the top of the water tank and atomizes water in the water tank to release into the gap between clothes and the human body. The small type fan transfers outside air into the air passage, then passing the air passage, into the gap.

A dispenser for dispensing liquid material while attenuating the liquid material and controlling the pattern of the liquid material with process air has a manifold with a plurality of process air passages for providing the process air to one or more liquid dispensing modules. The pressure of process air to one or more of the modules may be separately controlled to be different from the pressure provided to other modules on the dispenser. Accordingly, the air pressure provided to each module can be optimized to accommodate a particular dispensing die.

A Cold spray nozzle assembly for depositing powder material onto a component surface includes a primary spray nozzle, two or more secondary spray nozzles, and a support mechanism supporting each spray nozzle. Each spray nozzle deposits powder material on a single target point on the surface, a reference plane being defined normal to a surface plane at the target point. The primary nozzle is in a primary plane that is normal to the surface plane, and that defines a primary dihedral angle with the reference plane. An axis of the primary nozzle defines a primary nozzle angle with the surface plane. Each of the secondary spray nozzles is in a corresponding secondary plane, with each being normal to the surface plane and defining a respective secondary dihedral-angle with the reference plane. An axis of each secondary spray nozzle defines a respective secondary nozzle angle with the surface plane.

A static spray mixer is proposed for the mixing and spraying of at least two flowable components, having a tubular, one-piece mixer housing (2) which extends in the direction of a longitudinal axis (A) up to a distal end (21) which has an outlet opening (22) for the components, having at least one mixing element (3) arranged in the mixer housing (2) for the mixing of the components as well as having an atomization sleeve (4) which has an inner surface which surrounds the mixer housing (2) in its end region, wherein the atomization sleeve (4) has an inlet (41) for a pressurized atomization medium. A plurality of grooves are provided in the outer surface of the mixer housing (2) or in the inner surface of the atomization sleeve (4) which respectively extend in the direction of the longitudinal axis (A) and through which the atomization medium can flow from the inlet (41) of the atomization sleeve (4) to the distal end (21) of the mixer housing (2).

A feeding mold is provided with a charging runner for coating, a feeding runner connected to the charging runner, and a mold base adjacent to the feeding runner. The feeding runner is provided with a splitting manifold communicated with the charging runner, a discharging end face located at the end of feeding runner and apart from an atomizing knife edge of ultrasonic oscillating element by a gap, and a slit channel connected to the splitting manifold and discharging end face. The mold base is connected at a side edge thereof to the bottom of discharging end face, and inclined at a first angle toward the discharging end face. The side edge is located at the lowest position. Accordingly, the backflow of coating on the discharging end face to the mold base from the side edge and formation of trickle are impossible, so as to use coating adequately and avoid pollution.