The present invention relates generally to the field of fluid diffusers, and more particularly to tail sweep spray diffusers for pool cleaners.
Automatic swimming pool cleaners move along the floor and sidewalls of the pool to vacuum debris from the floor and side walls, as well as agitate and suspend fine particles so they move through the pool filter system. The cleaners generally include a tail sweep hose that trails behind the cleaner whipping from side to side to agitate and suspend the debris. In some devices, a replaceable scrubber cover can optionally be attached to the tail sweep. Contact with the pool floor and sidewall surfaces commonly causes abrasive wear of tail sweep parts and scrubber covers, often necessitating frequent replacement.
The whipping action of the tail sweep generally results from the stream of water exiting the end of the tail sweep hose under significant pressure. If the end of the hose is positioned above the water surface, the water stream exiting the end of the hose can project a significant distance which can soak the area surrounding the pool including the pool deck, pool furniture, adjacent structures, landscaping, artwork, and people enjoying the pool area. A diffuser having a deflector or diverter can be attached to the end of the hose to deflect the water stream if the end of the hose breaks the surface of the water. Previously known deflectors/diverters for tail sweep pool cleaners have, however, proven unsatisfactory in certain regards. For example, some known scrubbers include a foam cover configured to be fitted over a tail sweep to serve as a flow diffuser. The foam scrubber moves along the abrasive bottom and sides of the pool causing it to wear quickly and need to be replaced frequently. Further, while the foam scrubber is usually circular and surrounds the deflector, the scrubber tends to wear unevenly which contributes to a limited lifespan of the scrubber.
Wear from friction against pool surfaces can also cause detachment of flow deflecting nozzles or diffusers of a pool cleaner tail sweep, further contributing to undesirable spraying above the water surface. For example, flow deflectors having flexible clips or flanges for attachment to an existing pool cleaner tail sweep hose may be prone to disengagement from the nozzle, especially if the nozzle is worn due to abrasion. Also, misalignment of a flow deflector on the nozzle, for example due to abrasive wear on connecting parts, can cause the water stream exiting the hose to miss the flow obstruction of a tail sweep diffuser or diverter nozzle, allowing spray of pressurized water to shoot out of the pool. In some known tail sweep devices, the flow obstruction is positioned a significant distance from the end of the tail sweep hose, causing the water stream to miss the flow obstruction in the event of even a small misalignment of the tail sweep nozzle.
Some known tail sweep flow deflector nozzles also include openings that function as entrances for ambient fluid to create a pressure differential causing water or air to be drawn into the deflector housing. In some known devices, these openings are small and can plug with debris from the ambient fluid, restricting the water flow and reducing tail sweep whipping action. Such devices are particularly prone to clogging with debris when a flow deflector nozzle is used without a foam scrubber cover.
Accordingly, it can be seen that needs exist for improved tail sweep spray diffusers for pool cleaners. It is to the provision of improved tail sweep spray diffusers for pool cleaners meeting these and other needs that the present invention is primarily directed.
In example embodiments of the present invention, an improved pool cleaner tail sweep nozzle or diffuser is provided. Various embodiments may provide improved cleaning performance, greater durability for longer product life, and/or improved flow diversion/diffusion to prevent or substantially reduce spraying above the water surface. The diffuser is coupled to the end of the tail sweep hose which expels a stream of pressurized water. The diffuser generally includes a shaping nozzle configured to form an at least partially hollow cone of pressurized water stream. The shaping nozzle can be attached directly to the end of the hose. The diffuser can also include a dissipating portion configured to dissipate the at least partially hollow cone of the pressurized water stream when the spray diffuser is positioned above the surface of the water. The diffuser can optionally include a cover configured to fit over the dissipating portion of the diffuser.
In one aspect, the invention relates to a diffuser for a pool cleaner tail sweep. The diffuser preferably includes a flow shaping nozzle having a first end having an inlet opening for receiving an inlet stream of pressurized water from the pool cleaner tail sweep, a second end having an outlet opening for discharging an outlet stream of pressurized water, a fluid conduit extending from the inlet opening to the outlet opening, and an obstruction in the path of the outlet stream of pressurized water. The obstruction is preferably configured to shape the outlet stream of pressurized water into an at least partially diverging flow pattern. The diffuser preferably also includes a dissipating portion including a chamber into which the flow shaping nozzle discharges the at least partially diverging flow pattern. The dissipating portion preferably includes at least one dissipation element and a fluid discharge opening. The diffuser preferably operates in a first mode when submerged in a pool of water beneath a water surface, whereby the at least partially diverging flow pattern is directed through the fluid discharge opening of the dissipating portion in a concentrated stream in the first mode of operation when submerged in a pool of water beneath a water surface. The diffuser preferably also operates in a second mode when positioned above the water surface, whereby the at least partially diverging flow pattern is directed to the at least one dissipation element of the dissipating portion to form a diffuse stream in the second mode of operation when positioned above the water surface.
In another aspect, the invention relates to a diffuser for a pool cleaner having a tail sweep hose. The diffuser preferably includes a flow shaping nozzle configured for attachment to an end of the tail sweep hose. The flow shaping nozzle preferably has a first end including an inlet opening for receiving an inlet stream of pressurized water from the tail sweep hose, a second end including an outlet opening for discharging an outlet stream of pressurized water, a fluid conduit extending from the inlet opening to the outlet opening, and an obstruction in the path of the outlet stream of pressurized water. The obstruction is preferably configured to shape the outlet stream of pressurized water into an at least partially diverging flow pattern, and the obstruction is positioned immediately adjacent the end of the tail sweep hose when the flow shaping nozzle is attached to the end of the tail sweep hose. The diffuser preferably also includes a dissipating portion including a chamber into which the flow shaping nozzle discharges the at least partially diverging flow pattern. The dissipating portion preferably also includes at least one dissipation element, and a fluid discharge opening.
In still another aspect, the invention relates to a a diffuser for a pool cleaner having a tail sweep hose. The diffuser preferably includes a flow shaping nozzle configured for engagement with an end of the tail sweep hose. The flow shaping nozzle preferably has a first end including an inlet opening for receiving an inlet stream of pressurized water from the tail sweep hose, a second end including an outlet opening for discharging an outlet stream of pressurized water, a fluid conduit extending from the inlet opening to the outlet opening, and an obstruction in the path of the outlet stream of pressurized water. The obstruction is preferably configured to shape the outlet stream of pressurized water into an at least partially diverging flow pattern, and the obstruction is preferably positioned no more than about 1″ from the end of the tail sweep hose when the flow shaping nozzle is attached to the end of the tail sweep hose. The diffuser preferably also includes a dissipating portion including a chamber into which the flow shaping nozzle discharges the at least partially diverging flow pattern. The dissipating portion preferably also includes a generally hollow body having at least one sidewall and a plurality of openings in the at least one sidewall of the hollow body.
In another aspect, the invention relates to a diffuser for a pool cleaner tail sweep. The diffuser preferably includes a flow shaping nozzle having a first end including an inlet opening for receiving an inlet stream of pressurized water from the tail sweep hose, a second end including an outlet opening for discharging an outlet stream of pressurized water, a fluid conduit extending from the inlet opening to the outlet opening, and an obstruction in the path of the outlet stream of pressurized water. The obstruction is preferably configured to shape the outlet stream of pressurized water into an at least partially diverging flow pattern. The diffuser preferably also includes a dissipating portion including a chamber into which the flow shaping nozzle discharges the at least partially diverging flow pattern. The dissipating portion preferably operates with a spinning motion relative to the flow shaping nozzle, the spinning motion being rotational about an axis generally aligned with the outlet stream of pressurized water from the flow shaping nozzle.
In yet another aspect, the invention relates to a spray diffuser for a tail sweep pool cleaner comprising a hose that expels pressurized water out of an end of the hose, the spray diffuser comprising a shaping nozzle having a first end and a second end, wherein the first end is configured for attachment to the end of the hose and wherein the second end is configured to form an at least partially hollow cone of pressurized water stream, and a dissipating portion configured to dissipate the at least partially hollow cone of pressurized water stream when the spray diffuser is above a water surface.
In another aspect, the invention relates to a spray diffuser for a tail sweep pool cleaner comprising a hose that expels pressurized water from an opening at the end of the hose, the spray diffuser comprising a shaping nozzle configured for attachment to the end of the hose, the shaping nozzle comprising an opening and an obstruction positioned within or directly above the opening, wherein the opening in the shaping nozzle is positioned in front of the opening in the hose, and wherein the obstruction is a distance of no more than 1 inch from the opening in the hose.
In other example embodiments, a spinning diffuser for a tail sweep pool cleaner is provided. The diffuser is coupled to the end of the tail sweep hose which expels pressurized water out of the end of the hose. The spinning diffuser generally includes a shaping nozzle configured to form an at least partially hollow cone of pressurized water stream. The shaping nozzle can be attached directly to the end of the hose. The diffuser can also include a dissipating portion configured to dissipate the at least partially hollow cone of pressurized water stream when the diffuser is positioned above the surface of the water. The dissipating portion is generally free to rotate about the end of the hose. In example embodiments, the dissipating portion includes a spinning feature that causes the dissipating portion to spin when it is in use.
In another aspect, the present invention relates to a spinning diffuser for a tail sweep pool cleaner comprising a hose that expels a pressurized water stream out of an end of the hose, the spinning diffuser comprising a shaping nozzle having a first end and a second end, wherein the first end is configured for attachment to the end of the hose and wherein the second end is configured to form an at least partially hollow cone of pressurized water stream, and a dissipating portion configured to dissipate the at least partially hollow cone of the pressurized water stream when the spray diffuser is above a water surface, wherein the dissipating portion is coupled to the hose and is able to rotate about the hose, wherein the dissipating portion further comprises a spinning component configured to impart a rotational motion to the dissipating portion when it is in use.
In another aspect, the invention relates to a spinning diffuser for a tail sweep pool cleaner comprising a hose that expels pressurized water from an opening at the end of the hose, the spinning diffuser comprising a shaping nozzle configured for attachment to the end of the hose, the shaping nozzle comprising an opening and an impediment positioned within or directly above the opening, and a spinning portion that surrounds the shaping nozzle, wherein the spinning portion is configured to rotate about the end of the hose and wherein the rotational motion is driven by the action of the tail sweep pool cleaner.
These and other aspects, features and advantages of the invention will be understood with reference to the drawing figures and detailed description herein, and will be realized by means of the various elements and combinations particularly pointed out in the appended claims. It is to be understood that both the foregoing general description and the following brief description of the drawings and detailed description of example embodiments are explanatory of example embodiments of the invention, and are not restrictive of the invention, as claimed.
The present invention may be understood more readily by reference to the following detailed description of example embodiments taken in connection with the accompanying drawing figures, which form a part of this disclosure. It is to be understood that this invention is not limited to the specific devices, methods, conditions or parameters described and/or shown herein, and that the terminology used herein is for the purpose of describing particular embodiments by way of example only and is not intended to be limiting of the claimed invention. Any and all patents and other publications identified in this specification are incorporated by reference as though fully set forth herein.
Also, as used in the specification including the appended claims, the singular forms “a,” “an,” and “the” include the plural, and reference to a particular numerical value includes at least that particular value, unless the context clearly dictates otherwise. Ranges may be expressed herein as from “about” or “approximately” one particular value and/or to “about” or “approximately” another particular value. When such a range is expressed, another embodiment includes from the one particular value and/or to the other particular value. Similarly, when values are expressed as approximations, by use of the antecedent “about,” it will be understood that the particular value forms another embodiment.
With reference now to the drawing figures,
The shaping nozzle 130 has a first end and a second end, with an inner fluid flow channel or conduit extending therethrough. The first end includes an inlet opening and an attachment portion 132 configured for attachment to the end of the hose 122, as shown in
The second end of the flow shaping nozzle 130 includes an outlet opening and a diffuser portion 140. An inlet stream of pressurized water from the pool cleaner tail sweep hose 122 enters the inlet opening of the shaping nozzle 130, passes through the fluid conduit through the shaping nozzle, and is discharged from the outlet opening as an outlet stream of pressurized water. The shaping nozzle is generally positioned such that the diffuser portion 140 sits on or just beyond the end of the hose 122. The diffuser portion 140 is configured to manipulate the pressurized water stream to form a discharge stream or jet of water having an at least partially hollow or diverging flow profile, for example in the form of a cone or fan shaped stream or flow as shown in
The diffuser nozzle 124 preferably also includes a flow dissipator or dissipating portion 150 configured to extend beyond the second end of the shaping nozzle 130. The dissipating portion 150 is configured to dissipate the at least partially divergent or hollow cone of the pressurized water stream when the spray diffuser is above the water surface. Generally, the dissipating portion 150 is formed from a cylindrical or tubular body defining an inner conduit or channel extending therethrough, surrounded by a tubular body having at least one hole or cutout formed therein. In the depicted embodiment, the dissipating portion 150 is formed from a sleeve 152 with a plurality of circularly shaped cutouts 154. In other embodiments, other shaped sleeves and cutouts can be used. As shown in
The dissipating portion 150 can optionally be configured to receive and retain a foam cover 170, as shown in
In some embodiments, the diffuser nozzle 124 is configured to be smaller, more lightweight, and cheaper to manufacture than many previously known tail sweep diffuser nozzles. In some example embodiments, the outer diameter of the diffuser is about 20% smaller than prior art deflectors. In some example embodiments, the length of the diffuser is about 40% shorter than prior art deflectors. As a result, in some embodiments the diffuser and foam scrubbers last longer. In some example embodiments, the length of the diffuser is between about 2 inches and about 3 inches. In some example embodiments, the length of the diffuser is about 2.7 inches. In other embodiments, the length of the diffuser can be larger or smaller. In some example embodiments, the outside diameter of the diffuser is around 1 inch. In other embodiments, the outside diameter of the diffuser can be larger or smaller.
As shown in
In another example embodiment, as shown in
The shaping nozzle 630 includes a first end defining an inlet opening and a second end defining an outlet opening, with a fluid flow channel or conduit extending therethrough. The first end includes a barbed or ribbed attachment portion 632 configured for engagement within the end of the hose 622. The attachment portion is configured to be pushed or press-fitted into the end of the hose 622. An inlet stream of pressurized water from the tail sweep hose 622 is received in the inlet opening of the shaping nozzle 630, passes through the fluid conduit, and is discharged from the outlet opening as an outlet stream of pressurized water. The pressurized fluid exiting the hose is able to flow through the conduit into the diffuser portion of the shaping nozzle. In other embodiments, the attachment portion can be attached to the outside of the hose. The second end of the shaping nozzle 630 includes a diffuser portion 633. The shaping nozzle 630 is generally positioned such that the diffuser portion 633 sits on or just beyond the end of the hose, to prevent flow misalignments. The diffuser portion is configured to manipulate the pressurized water stream to form a discharge stream or jet of water having an at least partially hollow or diverging flow profile, for example in the form of a cone or fan shaped stream or flow pattern. In the depicted embodiment, the diffuser portion 633 has a generally circular cross-section. In other embodiments, the diffuser can be differently shaped. The diffuser portion 633 includes a top surface, a bottom surface, and a central opening. In use, the bottom surface of the diffuser portion is positioned against or adjacent to the end of the hose of the tail hose sweep cleaner. The diffuser portion 633 is positioned such that the stream of water exiting the end of the hose 622 passes through the central opening in the diffuser portion. The diffuser portion also includes a flow deflection obstruction or impediment 642 configured to diffuse, deflect, split or otherwise disrupt the flow of the pressurized water stream. The flow deflection impediment or slicer 642 is optionally configured to create a laminar flow where the drag force is proportional to the velocity. In the depicted embodiment, the flow deflection obstruction or impediment 642 includes a U-shaped cross-bar with first and second end portions and cross-bar portion therebetween. The first and second ends are attached to the top surface of the diffuser portion 633. The cross-bar portion is positioned just above the central outlet opening in the diffuser portion. In other embodiments, other types of flow deflection impediments can be utilized. In example embodiments, the flow obstruction 642 is positioned immediately adjacent, for example no more than about 1″ from, the end of the tail sweep hose when the flow shaping nozzle is attached to the end of the tail sweep hose, to minimize or prevent flow misalignment during use.
The spinning diffuser nozzle 624 preferably also includes a flow dissipator or dissipating portion 650 configured to extend beyond the second end of the shaping nozzle 630. The dissipating portion 650 preferably comprises at least one dissipation element, and is configured to dissipate the pressurized water stream when the spray diffuser 624 is above the water surface. Generally, the dissipating portion 650 is formed from a cylindrical channel having at least one hole or cutout. In the depicted embodiment, the dissipating portion 650 is formed from a sleeve 652 with a plurality of slot cutouts 654 that run perpendicular to the length of the dissipating portion. In other embodiments, other shaped sleeves and cutouts can be used. When the diffuser 624 is underwater, the ambient water pressure forces the diverging stream or cone of pressurized water to primarily exit a fluid discharge opening at the open distal end of the dissipating portion 650 causing a concentrated or tight solid stream or cone spray that contributes to the whipping motion of the hose and tail sweep, and helping dislodge dirt and debris from pool surfaces. Water surrounding the diffuser 624 is drawn into the dissipating portion 650 through openings 654 by the Venturi effect as the pressurized stream of water from the tail sweep hose 622 passes through the dissipating portion and is discharged out the open distal end. When the diffuser 624 is above the water surface, the ambient air pressure is insufficient to maintain the tight cone spray, and the water stream diverges outwardly as it passes over the flow deflection impediment 642, spraying against the interior surface and/or other dissipation elements of the dissipating portion 650 and exiting through the openings or cutouts 654 in the sleeve 652, thus dissipating the water spray into a mist or diffuse spray rather than a concentrated stream, thereby preventing or substantially reducing the incidence of water spraying out of the pool. In example embodiments, the shaping nozzle 630 prevents the dissipating portion 650 from disengaging from the end of the hose.
The dissipating portion 650 preferably comprises a spinning component or rotational aspect configured to impart a rotational motion to the dissipating portion 650 as it moves through the water. The spinning dissipating portion is attached to end of the tail sweep hose such that it can rotate about the end of the hose. In the depicted embodiment, the spinning component is formed from a plurality of pitched or helical blades 656 on an exterior surface of the sleeve, extending from a first end of the dissipating portion 650 to the second end of the dissipating portion. In other embodiments, the helical blades 656 can extend along only a portion of the length of the sleeve. In example embodiments, the blades 656 are integrally formed on the exterior surface of the sleeve 652 of the dissipating portion. As the dissipating portion 650 is pulled through the water, the water flow over the pitched blades 656 causes the dissipating portion to rotate relative to the end of the hose 622. The pitched blades 656 can be formed of a hard material such as a rigid plastic. In other embodiments, the pitched blades 656 can be formed from a flexible material such as silicon. The rotation of the dissipating portion 650 can contribute to the whipping motion of the tail sweep hose 622. The rotating blades 656 can also serve to scrape or brush the floor and sides of the pool P and help agitate dirt and debris.
The spinning diffuser 624 optionally also comprises a retaining cap 670, having a central opening configured to receive the hose, and a sidewall extending upward from the periphery of the end surface. In use, the sidewall of the retaining cap 670 is positioned around the first, attachment end of the shaping nozzle 630 of the diffuser. The sidewalls are configured to surround the attachment portion of the shaping nozzle to hold it in engagement with the hose 622. The retaining cap 670 is generally removably coupled to the shaping nozzle of the diffuser. In other embodiments, the retaining cap is permanently or semi-permanently attached to the shaping nozzle. The retaining cap 670 optionally also functions as a rotational bearing or bushing for low-friction contact with an inner surface of the spinning dissipating portion 650. In example embodiments, the diffuser nozzle 624 comprises at least one spinning component, such as the dissipating portion, which is passively driven to spin at the tail sweep moves through the water due to the helical blades 656 passing through the water. In other embodiments, the at least one spinning component may be actively driven to spin, for example by provision of a helical rotor or propeller in the path of the pressurized water flow from the tail sweep hose through the diffuser.
In the depicted embodiment, the attachment portion comprises a series of clips 840 positioned around the outer periphery of the bottom surface of the deflection disk. The clips 840 are configured to fit around the outside of the end of the hose to hold the diffuser 824 in engagement with the end of the tail sweep hose 822. In example embodiments, the attachment portion is configured to releasably attach the diffuser 824 to the end of the hose 822. In other embodiments, the diffuser 824 is permanently attached to the end of the hose 822. While the attachment portion of the depicted embodiment includes clips 840 that are push fitted over the end of the hose, other attachment means can be used including snaps, straps, and elastic elements. Preferably, the attachment means does not require any tools to attach or detach the diffuser to the hose, simplifying installation for the user. The attachment portion is configured to position the bottom of the deflection disk 832 against or in close proximity to the end of the hose. Therefore, the deflection element 836 is positioned at or near the end of the hose 822. In example embodiments, the diffuser 824 can also include a retaining cap 880, best seen in
The dissipating portion 850 includes a sleeve 852 with pitched or helical blades 854 as in the previous embodiment. The sleeve 852 of the depicted embodiment does not include openings. In other embodiments, the sleeve 852 can include openings as in the previous embodiment. The dissipating portion 850 of the depicted embodiment also includes an end cap 856 positioned at the second end of the dissipating portion. The end cap 856 generally includes a large central opening 858 and plurality of smaller diffusing openings 860 positioned around the central opening. When the diffuser 824 is positioned below the water surface S, the Venturi effect results in a reduction in pressure between the bottom of the cap 856 of the dissipating portion 850 and the top of the shaping nozzle 830. As a result, the dissipating portion 850 is retracted such that the bottom or interior face of the cap 856 is flush or adjacent to the top or exterior face of the shaping nozzle 830. In this position, the pressurized water stream from the tail sweep hose 822 passes substantially unobstructed through the large central opening 858 in the cap 856. When the diffuser 824 is positioned above the water surface S, the Venturi effect is not present and the pressurized water stream from the hose 822 pushes the cap 856 of the dissipating portion 850 away from the shaping nozzle 830, and the divergence of the pressurized water stream caused by flow impediment 836 causes the water stream to impinge upon the inner face of the end cap 856 of the dissipating portion 850 forming a mist or diffuse spray exiting the small openings 860 and the large opening 858, rather than a concentrated stream, eliminating or reducing the incidence of water spraying out of the pool P.
In operation, and in similar fashion to the above described embodiments, the diffuser 1024 generates a more concentrated pressurized stream of water for improved cleaning and movement of the tail sweep when the diffuser is submerged in water W below the surface S of a pool (
While the invention has been described with reference to example embodiments, it will be understood by those skilled in the art that a variety of modifications, additions, and deletions are within the scope of the invention, as defined by the following claims.
This application claims the benefit of U.S. Provisional Patent Application Ser. No. 62/715,642 filed Aug. 7, 2018 and U.S. Provisional Patent Application Ser. No. 62/717,540 filed Aug. 10, 2018, the entireties of which are hereby incorporated herein by reference for all purposes.
Number | Name | Date | Kind |
---|---|---|---|
2766026 | Boyd | Oct 1956 | A |
3776464 | Proffit | Dec 1973 | A |
3872533 | Proffit | Mar 1975 | A |
4356582 | Stephenson | Nov 1982 | A |
4651377 | Staples | Mar 1987 | A |
5901906 | Bouldin | May 1999 | A |
5996906 | Cooper | Dec 1999 | A |
6029290 | Butcher et al. | Feb 2000 | A |
7402242 | Duckett | Jul 2008 | B2 |
8037567 | Harris | Oct 2011 | B1 |
D654989 | Bloink et al. | Feb 2012 | S |
D657027 | Bloink et al. | Apr 2012 | S |
8241506 | Vernier et al. | Aug 2012 | B1 |
9249590 | Bloink et al. | Feb 2016 | B2 |
9938744 | Gopalan et al. | Apr 2018 | B2 |
20100011521 | Collins | Jan 2010 | A1 |
20170298645 | Checri | Oct 2017 | A1 |
Number | Date | Country |
---|---|---|
2830963 | Oct 2012 | CA |
2012138412 | Oct 2012 | WO |
2014071403 | May 2014 | WO |
Number | Date | Country | |
---|---|---|---|
20200047196 A1 | Feb 2020 | US |
Number | Date | Country | |
---|---|---|---|
62717540 | Aug 2018 | US | |
62715642 | Aug 2018 | US |