This invention relates to apparatus for regulating fluid flow utilising an improved way of combining different flow conditions to increase and economise the spraying (jet output) and mixing effects of a spray nozzle. More particularly, the invention is described, with reference to a water-saving shower head. However, the present invention is not restricted to shower head applications and is applicable to other fluidic applications involving liquid and/or gaseous fluid flows.
In order to conserve water it is common practice to install water saving shower heads. The devices currently used for this are quite rudimentary in operation. They typically reduce consumption by employing a small inlet to the shower head to reduce flow. The volume of water emanating from the head may also be decreased, simply by using reduced diameter spray holes. While each of these designs are to some extent successful, their effectiveness is limited because a reduction in flow rate also reduces the pressure of the spray. Consequently shower heads which operate at the current benchmark of 9 litres per minute for an AAA rating have problems with low spray pressure, restricted spray patterns and clogging of the outlet holes in the spray head. Also, for many people a shower spray of 9 litres per minute from existing devices feels inadequate.
One way of economising on flow rate whilst maintaining a desirable spraying effect is to have the primary flow of water entering the shower head chamber tangentially through an inlet in its peripheral side wall that is constrained to follow a circular flow path, and exits at an outlet in an end wall at or near the central axis of the chamber. This primary flow of water that follows a circular path forms a vortex commencing internally at or near the peripheral side wall and increases in velocity and pressure towards the outlet. If a further inlet is provided at substantially 90 degrees to the circular flow path and a secondary control flow of water is fed through this further inlet it regulates and atomizes the primary flow into a spray that emanates from the outlet.
This method of atomising and forming a spray is not limited to water applications and is employed in uses involving other fluids. One such application is in a fuel injection valve where atomisation of the fuel is desirable. U.S. Pat. No. 6,161,782 (Heinbuck et al.) depicts a fuel atomising disk in
A disadvantage of providing a secondary control flow at substantially 90 degrees to the primary circular flow (or vortex) path, is that it tends to interfere and break down the vortex.
According to a first aspect the invention consists of an apparatus for regulating fluid flow through a spray nozzle, said apparatus comprising a circular chamber defined by spaced apart end walls, a peripheral side wall, a central axis, at least a first inlet at or near said peripheral side wall to allow a flow of fluid to enter said chamber substantially tangential to said peripheral side wall, an outlet exiting through one of said end walls characterised in that in use a flow of fluid entering through said first inlet has a primary lower layer that substantially follows a first circular flow path which forms a vortex commencing at or near said peripheral side wall and increases in velocity and pressure towards said outlet and at least one secondary upper layer that substantially follows a second flow path radially inwardly towards said central axis, said primary lower layer and said secondary upper layer interact and support each other over at least a portion of flow between said inlet and said outlet.
Preferably said second flow path of said secondary upper layer is generated by means for generating an inwardly radial flow.
Preferably said apparatus comprises a disc engagable with a spray nozzle housing that in combination define said circular chamber, and one of said spaced apart end walls and said peripheral side wall of said circular chamber form part of said disc, and said means for generating an inwardly radial flow is a narrow annular gap between said disc and said housing, said annular gap being disposed radially outwardly relative to said peripheral side wall.
In one embodiment the volume of said annular gap is fixed.
In another embodiment the volume of said narrow gap is variable by movement of said disc relative to said spray nozzle housing along said centrally located housing.
In one embodiment said outlet is located at or near said centrally located axis.
Preferably said at least first inlet is a plurality of inlets.
Preferably in one embodiment the one of said spaced apart end walls that forms part of said disc has a substantially flat portion.
Preferably in another embodiment the one of said spaced apart end walls that forms part of said disc has at least one substantially curved portion.
In a further embodiment said apparatus is used to mix different fluids.
The currently preferred embodiments of the invention will now be described with reference to the attached drawings in which:
In order to best describe the invention it is appropriate to describe prior art apparatus for regulating fluid flow as shown in
Vr=VR(r/R)η A)
Upon substitution and integration:
Pr=PR+[S(VR)2/2η][(r/R)2η−1] D)
This shows the state of the vortex, ie. as the fluid moves from the circumference to the centre, there is an increase in speed along with pressure. This application is already used in devices such as garden sprinkles. However, they result in a fimbriated spray pattern and have poor atomisation effects.
The primary lower layer 16 and the secondary upper layer 17 interact (mix) and support each other in a non-destructive manner from start (perimeter) to finish (outlet). They do not break up the motion and effects created by the vortex, but rather enlarge and heighten the effects of the vortex. That is, as the layers 16 and 17 move from the outer perimeter (circumference) to the centre, there is an increase in pressure, drag and speed. It is preserved and built up in the form of potential energy, until it is released at the outlet in the form of kinetic energy, which we can see in the form of a centrifugal gush 18. The centrifugal gush 18 can be controlled and adjusted to produce various configurations to the outlet spray formation ie. straight line, wide angled, fimbriated, mist—full atomisation, single layered or stratified, point-blank pulse/hammering-etc., dependent on the nature of the desired end usage requirement.
Chamber 1a of the “fixed volume” shower head depicted in
Chamber 1b of the “adjustable volume” shower head depicted in
Both embodiments of
In the case of the “fixed volume” shower head as shown in
The disc 9 shown in the second and third embodiments of
From tests conducted by the inventor the following advantages are apparent with shower heads constructed according to the abovementioned embodiments of the present invention.
Whilst in the abovementioned embodiments the outlet centrally located, in other not shown embodiments the outlet does not have to be located at the centre of the chamber and may for instance be located near the centrally located axis. We positioning of the outlet can vary the output spray effect, and its location slightly offset from the central located can for instance be used to generate a pulse spray suitable for high pressure washing.
It should also be understood that plane of contact (or interface), between layers of flow 16 and 17 within chamber 1, can occur on various contours, such as parallel, concave, convex, parabolic, some on curved and some on a plane etc.
It should also be understood that whilst the abovementioned embodiments of the present invention refer to two layers of flow 16 and 17, it should be understood that in further not shown embodiments additional layers of flow may exist. Further layers may be of vortex and/or radial in the nature of their flows and may be separated by means of a physical barrier.
It will thus be appreciated that this invention at least in the form of the embodiments disclosed provides a novel and improved form of water saving shower head. Clearly however the examples described are only the currently preferred forms of the invention and a wide variety of modifications may be made which would be apparent to a person skilled in the art. For example the relative size of the circular chamber, the shape and configuration of the annular gap, the shape and configuration of the outlet nozzle, the placement number and design of the inlet ports, and the means of adjusting the control flow pressure may all be changed to suit applications other than shower heads following further development work by the inventor. It is also envisaged that the apparatus could be used as a mixer of different fluids. The invention is also not limited to any particular material for constructing the shower head although a high strength plastic or a corrosion resistant metal such as stainless steel or brass is currently preferred.
Whilst the present invention has been described with reference to shower head applications, it should be understood that the apparatus of the present invention is applicable to other not shown fluidic applications, such as, electronic fuel injection systems, exhaust systems, fire hydrant nozzles, sand-blasting nozzles, projectile firing devices, spray painting nozzles, bio-medical spray systems, brick-wash nozzles, aerosol bottle/can nozzles and gas torches.
In not shown embodiments where the apparatus of the present invention is used in sand-blasting nozzle or other projectile firing device, solids or projectiles are carried by the fluid flow. Where a fluid flow is established in a like manner to that show in
It should also be understood that whilst the above described shower head embodiments have been described with the water as the fluid, it may in other not shown embodiments be another type of fluid, either liquid or gas or mixtures thereof. Such fluids for example may be fuel, paint, agricultural chemical solutions, cleaning agents, medications, or commercial gases such as oxygen and nitrogen. Furthermore, the apparatus of the present invention may be used to mix different fluids prior to spraying.
Number | Date | Country | Kind |
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2002950802 | Aug 2002 | AU | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/AU03/01032 | 8/15/2003 | WO | 00 | 9/30/2005 |
Publishing Document | Publishing Date | Country | Kind |
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WO2004/016358 | 2/26/2004 | WO | A |
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9523029 | Aug 1995 | WO |
Number | Date | Country | |
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20060102748 A1 | May 2006 | US |