A spray pump is disclosed. A spray pump according to one aspect of the present invention comprises: a housing which has an inflow space and which is coupled to a container inlet; a housing cover coupled to the upper end portion of the housing; a disc for opening or closing the housing according to the pressure of the inflow space; a valve which is movably inserted into the housing cover and which has a valve head and a valve body communicating with the valve head; a guide having a portion inserted into the valve body and the remaining portion positioned outside the valve body, and having a guide passage corresponding to a flow path through which contents are discharged; a valve spring for providing elastic force for upwardly pressing the valve; a piston which is movably inserted into the outer peripheral surface of the guide, and which opens or closes the guide passage by means of the vertical movement of the valve; a nozzle which is coupled to the valve head and which has an insert protrusion; and an insert which is inserted into the circumference of the insert protrusion and which has an orifice, wherein a spiral nozzle helix groove is formed on the outer peripheral surface of the insert protrusion.

A fluid atomizer and methods of atomizing fluids are disclosed. The fluid atomizer may comprise an inner member and one or more outer members. The inner member defines an interior conduit for providing a first-fluid flowpath from a supply end of the atomizer to a discharge end of the atomizer along a central axis. The one or more outer members are positioned radially outward of the inner member from the central axis. The inner and outer members define a second-fluid flowpath extending from a second-fluid supply conduit to a second-fluid discharge plenum. The second-fluid flowpath comprises a tangential conduit spiraling along the axis from the second-fluid supply conduit to a terminal end; an annulus downstream from and in fluid communication with the tangential conduit; and a second-fluid discharge plenum downstream from and in fluid communication with the annulus.

A fluid supply apparatus according to an embodiment of the invention includes a housing and an internal structure which is housed in the hosing. The internal structure includes a shaft portion and a plurality of protrusions protruding from the outer circumferential surface of the shaft portion. A plurality of flow paths are formed between the plurality of protrusions, and a groove having a predetermined depth from the outer circumferential surface of the shaft portion is formed in each of at least a part of the plurality of flow paths.

A fluid atomizer and methods of atomizing fluids are disclosed. The fluid atomizer may comprise an inner member and one or more outer members. The inner member defines an interior conduit for providing a first-fluid flowpath from a supply end of the atomizer to a discharge end of the atomizer along a central axis. The one or more outer members are positioned radially outward of the inner member from the central axis. The inner and outer members define a second-fluid flowpath extending from a second-fluid supply conduit to a second-fluid discharge plenum. The second-fluid flowpath comprises a tangential conduit spiraling along the axis from the second-fluid supply conduit to a terminal end; an annulus downstream from and in fluid communication with the tangential conduit; and a second-fluid discharge plenum downstream from and in fluid communication with the annulus.

An air/oil mist generator (1A) including an accumulation chamber (2) inside which a mist of oil particles in air accumulates, the accumulation chamber (2) being provided with at least a first mist outlet (4), the generator (1A) comprising a nebulizer (3, 3A) feeding into the said accumulation chamber (2), the nebulizer (3) being optimised to operate at a first pressure level and being fed by a first line (BA) of compressed air at the said first pressure level, the generator (1A) further including a further nebulizer (3A) which also feeds into the accumulation chamber (2) optimised to operate at a second pressure level which is higher than the first pressure level, the further nebulizer being fed by a second line (AL) of compressed air at the second pressure level; the first line (BA) being optionally associated with a non-return valve (807) which prevents a backflow coming from the accumulation chamber (2).

Atomizing nozzle which combines two or more substances introduced through at least a first inlet (10) and a second inlet (50), and sprays the resulting atomized droplets through an outlet (110), capable of optimized flow rate and droplet size through a modular design based on interchangeable disk-shaped modules. When stacked in a hollow cylindrical casing conformed by a first housing (20) and a second housing (120), the plurality of modules conform a first mixing chamber (200) and a second mixing chamber (210) connected through a swirl module (60). Furthermore, when said stacking occurs, the first inlet (10) is connected to the first mixing chamber (200), the outlet (110) is connected to the second mixing chamber (210); and the second outlet may be connected to the first mixing chamber (200) or the second mixing chamber (210) depended on the configuration selected by the user.

A fluid atomizer and methods of atomizing fluids are disclosed. The fluid atomizer may comprise an inner member and one or more outer members. The inner member defines an interior conduit for providing a first-fluid flowpath from a supply end of the atomizer to a discharge end of the atomizer along a central axis. The one or more outer members are positioned radially outward of the inner member from the central axis. The inner and outer members define a second-fluid flowpath extending from a second-fluid supply conduit to a second-fluid discharge plenum. The second-fluid flowpath comprises a tangential conduit spiraling along the axis from the second-fluid supply conduit to a terminal end; an annulus downstream from and in fluid communication with the tangential conduit; and a second-fluid discharge plenum downstream from and in fluid communication with the annulus.

An atomizing and vortex generating vane for cooperation with a nozzle of a shower head includes a cylindrical body having a central longitudinal axis and a vane blocker centered about the axis. The vane blocker has a cross-sectional profile rotated about the axis in a helical path from top to bottom, forming helical flow boundary walls. Fluid flows through flow paths defined by the flow boundary walls, in a swirling path around the central longitudinal axis. A splash nozzle including the vane generates fluid jets ranging from full cone to the hollow cone fluid jets, for showering purposes. A shower head including a storage tank and a plurality of the splash nozzles is designed to conserve water while providing a warm and comfortable shower experience.

What is proposed is a nasal dispenser (10) for the nasal application of liquids in atomized form, in particular for children.

The nasal dispenser (10) has a nasal applicator (40) which is for dispensing the liquid and is formed by an outer component and an inner component, which together define a vortex chamber and at least one inlet channel into the vortex chamber.

In the case of components that are stationary in relation to one another, especially tapered inlet channels (96) for generating a high liquid velocity in the vortex chamber (98) are proposed. The cross-sectional area of the inlet channel (96), that is aligned transversely to the flow direction (4) in the inlet channel, at its narrowest point or the sum of the cross-sectional areas of the inlet channels, that are aligned transversely to the flow direction (4) in the inlet channels (96), at their respective narrowest points is at most 0.05 mm.sup.2.

In the case of a design in which the inner component (60) is arranged movably in the outer component (50), in particular for the purpose of obtaining a valve function, it is conversely proposed to design the outlet opening (54) with a narrowest cross section of at most 0.05 mm.sup.2.

A fluid supply apparatus according to an embodiment of the invention includes a housing and an internal structure which is housed in the hosing. The internal structure includes a shaft portion and a plurality of protrusions protruding from the outer circumferential surface of the shaft portion. A plurality of flow paths are formed between the plurality of protrusions, and a groove having a predetermined depth from the outer circumferential surface of the shaft portion is formed in each of at least a part of the plurality of flow paths.