A diffuser outlet duct for a pressurized container fitted with a valve, equipped with: a passage between a first end and a second end. The first end is configured to collaborate with the valve of the pressurized container. The second end is configured for expelling the product contained in the pressurized container. The passage is defined by a first section, a second section, and a junction connecting the first section and the second section. The first section begins begins at the first end and terminates at the junction. The second section at the junction and terminates at the second end. The first section extends over a first length (l1), and the second section extends over a second length (l2) The second length is less than 10 mm, preferably less than 9 mm, more preferably less than 8 mm.

Provided are an ejection member and an aerosol product using the same capable of obtaining a desired shape of an ejection material by suppressing adhesion of the ejection ejection materials to each other. An ejection member 20 to be connected to an aerosol container 10 filled with a foaming content is provided with an expansion chamber E for promoting foaming of the foaming content from the aerosol container 10 and a plurality of nozzles 22c for ejecting the foaming content in the expansion chamber E to the outside. The expansion chamber E is provided with an introduction port 21e for introducing the foaming content from the aerosol container 10 and a delivery port 22b for delivering the foaming content to the nozzle 22c side. The nozzles 22c each have a slit-shaped ejection port 22d. The communication path that communicates the ejection port 22d and the delivery port 22b has a slit-shaped slit portion 22e. A length L1 of the slit portion 22e in the ejection direction is greater than a slit width W1 of the ejection port 22d.

The present invention discloses a discharge container that is provided with the following: a container body in which contents are stored; a securing member; a discharge vessel including a stem; an exterior section including a top wall section penetrated by molded holes and that discharges the contents from the perforation holes onto a discharge surface of the top wall section; and an inner plate which is provided so as to be freely movable inside the exterior section and which forms a diffusion chamber in the space that is formed with a supply surface of the top wall section.

A discharge container includes: a container body in which contents are stored; a securing member; a discharger including a stem; an exterior portion that includes a top wall portion through which a molded hole passes, and that discharges the contents from the molding hole onto a discharge surface of the top wall portion; and an inner plate in the exterior section to be movable and which forms a diffusion chamber between the inner plate and a supply surface of the top wall portion.

A conformal, cup-shaped fluidic nozzle engineered to generate an oscillating spray is configured as a (e.g., 100, 400, 600 or 700). Preferably, the fluidic circuit's oscillation inducing geometry 710 is molded directly into the cup's interior wall surfaces and the one-piece fluidic cup may then fitted into an actuator (e.g., 340). The fluidic cup (e.g., 100, 400, 600 or 700) conforms to the actuator stem used in typical aerosol sprayers and trigger sprayers and so replaces the prior art swirl cup 70 that goes over the actuator stem (e.g., 320), With the fluidic cup (e.g., 100, 400, 600 or 700) and method of the present invention, vendors of liquid products and fluids sold in commercial aerosol sprayers 20 and trigger sprayers 800 can now provide very specifically tailored or customized sprays.

A spray orifice structure for which, when spraying liquid contents onto a body part, such as a face, hair, an upper body or a lower body, by using a spray type container, it is possible to provide a user with a differentiated spray performance depending on each body part to be sprayed by manufacturing a spray orifice in consideration of an injection angle to which liquid contents are sprayed.

A fluid dispenser head including a spray wall (1) that defines a central axis (X) and that is perforated with holes (O1, O2) through which the fluid under pressure passes so as to form jets of fluid, the holes (O1, O2) extend along axes (Y1, Y2) that correspond to the path of the jets of fluid; the dispenser head being characterized in that at least some of the axes (Y1, Y2) intersect, such that the jets of fluid that extend along the intersecting axes (Y1, Y2) meet at at least one collision point (P).

A remote operation spray device configured to depress-operate a spray nozzle of a spray device from a remote location. Device generates adequate pushing force required for depression and, by achieving weight reduction of the device proper, enables easy mounting on an aerial vehicle or other mobile unit. Device includes a main body fixedly attached to a mobile unit, a holder fixedly retaining a spray cartridge and a spray mechanism for jetting spray. The spray mechanism includes a base member, a depressing member pivotably attached to the base member for pressing down a spray nozzle, a pushed member provided at a distal end of the depressing member, and a pusher installed on the base member for pushing the pushed member to move horizontally. The horizontal pushing action of the pusher pushes and moves the pushed member to pivot the depressing member and press the spray nozzle vertically downward.

Aerosol sprays, methods of generating air freshener aerosol sprays, and devices for dispensing such aerosol sprays. The aerosol sprays have properties that are highly desirable for products such as air fresheners, including sizes of particles in the sprays and span factors of the particles. The methods and systems that provide the aerosol sprays use a membrane having micropores that forms Rayleigh jets that subsequently break up into the aerosol particles. The systems used to generate the aerosol sprays have a non-pressurized container for the product to be dispensed and a pump to provide the force to push the product through the micropores of the membrane.

A dispenser cap includes a shell, a scraper coupled to the shell, and a fluid-delivery controller. The dispenser cap mounts on a spray can, and the fluid-delivery controller engages with a valve of the spray can to selectively dispense pressurized fluid from the spray can.