Class / Patent application number | Description | Number of patent applications / Date published |
239589100 | Fluidic oscillator | 9 |
20090236449 | High efficiency, multiple throat fluidic oscillator - An improved fluidic oscillator, that operates on a pressurized liquid flowing through the oscillator to generate a liquid jet that flows into the surrounding gaseous environment to form of an oscillating spray of liquid droplets, includes: a member into which is fabricated a two-portion, flow channel, with its first portion configured so as to create the flow phenomena in the member that yields the spray's oscillating nature, and its second portion includes a splitter that is used to divide the jet into component sprays whose centerlines assume a specified yaw or pitch angle relative to the centerline of the oscillator. | 09-24-2009 |
20100072307 | Enclosures for multiple fluidic oscillators - An improved fluidic device that operates on a pressurized liquid flowing through it at a specified flow rate to generate an oscillating spray of liquid droplets having desired properties (e.g., average spatial distribution, size, velocity, frequency and wavelength of liquid droplets at a defined distance in front of the device) includes: (a) a plurality of fluidic oscillators, each having a channel that is part of a fluidic circuit for inducing oscillations in the pressurized liquid that flows through the oscillator, (b) a housing having an exterior surface that includes a front face with a center-point and a rear face, (c) a plurality of passages, each of which extends through the housing and intersects with its front face to define an outlet, with each passages configured to allow for the insertion of one of the plurality of fluidic oscillators into each of the plurality of passages, and (d) a geometrical arrangement of these outlets in the housing front face that is chosen so as to achieve the desired properties of the oscillating spray when the device is operating at its specified flow rate. | 03-25-2010 |
20100090036 | Fluidic circuit with bump features for improving uniform distribution of fluidic sprays - A fluidic circuit or oscillator is provided with one or more small raised bumps or protrusions near the outlet or exhaust of a fluidic circuit to alter the spray pattern by re-distributing heavy areas of flow, resulting in a more uniform spray. The fluidic oscillator enclosure operates on a pressurized liquid flowing through the oscillator to generate a liquid jet that flows from said oscillator and into a surrounding environment to form an oscillating spray of liquid droplets, where the oscillator generates a stream of liquid droplets. The outlet or throat structure includes at least one bump or protuberance configured to project into the oscillating spray. | 04-15-2010 |
20100123031 | Fluid oscillator assembly for fuel injectors and fuel injection system using same - A fuel injection system includes a fuel injector that includes a nozzle assembly and at least one passageway that includes at least one fluid oscillator. The at least one passageway extends from a nozzle orifice, positioned on the outside of the fuel injector, to inside the fuel injector. Fuel from inside the fuel injector moves through the at least one fluid oscillator and oscillates between a high injection rate and a low injection rate as it moves through the at least one nozzle orifice and into the combustion chamber. | 05-20-2010 |
20100276521 | Nozzle and Fluidic Circuit adapted for use with cold fluids, viscous fluids or fluids under light pressure - A fluid spraying or nozzle system adapted for use with cold fluids, viscous fluids or fluids under light pressure includes a fluidic oscillator having a power nozzle and an oscillation chamber coupled to the power nozzle for issuing a jet of fluid into the oscillation chamber and an outlet aperture spraying a jet of fluid into ambient space. The oscillator's walls define an oscillation inducing interaction region causing the jet of fluid to rhythmically sweep back and forth between the sidewalls in the oscillation chamber. The oscillation inducing interaction region defines an outlet throat width which is adapted to work with the power nozzle's width and an a bell-shaped feed that spreads the fluid jet as it leaves the power nozzle, so that the interaction region and feedback channels are quickly filled with fluid at a low pressure and the fluidic oscillator is activated to generate a desired fan pattern of fluid spray. | 11-04-2010 |
20110139907 | Tank-cleaning nozzle - A tank-cleaning nozzle having an inlet tube, a cleaning head mounted for rotation on the inlet tube and at least one spray nozzle disposed on the cleaning head. The spray nozzle is in the form of a fluidic oscillator nozzle producing an oscillation solid jet at an outlet from the nozzle. | 06-16-2011 |
20120037731 | Fluidic oscillator - A fluidic oscillator contains at least one channel including an interacting cavity disposed therein, a first inlet communicating with the interacting cavity to flow fluid inward, and a first outlet communicating with the interacting cavity to spray the fluid flowing through the interacting cavity outward, characterized in that: at least one turbulent flow passage is used to guide the fluid to flow into the interacting cavities from one of two opposite first longitudinal walls of the interacting cavities so that a turbulent flow effect is generated in the interacting cavities, and then the fluid flows out of the first outlets to generate oscillatory spray. | 02-16-2012 |
20130240644 | OUTLET MECHANISM WITH PULSATILE SPLASH - An outlet mechanism with pulsatile splash has a main waterway comprising an inlet waterway, two branch waterways and two back-flow waterways; the two branch waterways communicate with the outlet end of the inlet waterway and are arranged symmetrically with respect to the inlet waterway. The outlet directions of the outlet ends of the two branch waterways intersect; the two back-flow waterways are arranged symmetrically with respect to the inlet waterway, and one end of the back-flow waterway communicates with the branch waterway. Another end of that communicates with the inlet end of the inlet waterway. Part of water in the branch waterway is returned to the inlet end of the inlet waterway by the back-flow waterway. The remain water in the two branch waterways intersect when water comes out of the outlet, so that the left-and-right-swing outlet effect, and then the pulsatile splash outlet effect are generated. | 09-19-2013 |
20140291423 | Cup-shaped Nozzle Assembly with Integral Filter Structure - A filtering nozzle assembly or spray head has a conformal nozzle component engineered to generate a filtered spray and configured as a small cylindrical member having a substantially open proximal end and a substantially closed distal end wall with a centrally located discharge orifice defined therein. Optionally, cup-shaped filtered orifice defining member also includes a fluidic circuit's oscillation inducing geometry molded into the cup or directly into the distal surface of a sealing post and the one-piece filter cup provides the fluidic circuit's discharge orifice. | 10-02-2014 |