This invention relates to pumps for moving fluid and particularly, but not necessarily exclusively, to centrifugal pumps used in swimming pools and spas.
Most centrifugal pumps require priming before use, or the pump will not function properly or at all. Such pumps have difficulty priming to certain heights—such as above around 5 feet—in short amounts of time. Larger pumps designed for commercial applications have even greater difficulty priming, with average priming times ranging anywhere from 25 minutes to more than an hour. Down time spent priming the pump can be costly to commercial and other facilities, as swimming pools and spas are rendered inoperable while the pump is priming.
The present invention provides alternative pump designs that make priming more efficient and therefore dramatically reduce priming time. The disclosed pumps include one or more deflection structures that deflect the fluid from the diffuser directly toward the outlet of the pump. In particular, the one or more deflection structures force the fluid flow from a circular path and direct it to the pump outlet. In some instances, the one or more deflection structures change the circular flow path around the diffuser to an axial path toward the pump outlet. In some examples, when the pump outlet is within a plane that is offset from a plane of the diffuser, the one or more deflection structures deflect the fluid approximately 90 degrees (or other suitable angle) so the fluid flows in an axial (e.g., lateral) direction perpendicular to its otherwise circular flow.
This deflection forces the fluid flow from its circular path directly toward the pump outlet, reducing air bubble accumulation inside the pump while priming and making it easier for air to escape through the pump outlet. Making it easier for air to escape the pump outlet ultimately allows air to escape the pump faster during priming, reducing back pressure caused by trapped air pockets inside the pump and drastically improving priming performance. The deflection structures can take many forms, including separation petitions, ramps, projections, fins, spiraled/twisted/curved surfaces, etc.
It thus is an optional, non-exclusive object of the invention to provide designs for pumps.
It is another optional, non-exclusive object of the present invention to provide pumps with improved priming performance.
It is another optional, non-exclusive object of the present invention to provide pumps with improved hydraulic efficiencies.
It is also an optional, non-exclusive object of the present invention to provide pumps configured to separate fluid flowing through the diffuser and deflect at least a portion of the fluid from its circular flow toward an outlet of the pump.
It is a further optional, non-exclusive object of the present invention to provide pumps especially useful in connection with water-circulation systems of swimming pools and spas.
Other objects, features, and advantages of the present invention will be apparent to those skilled in the relevant art with reference to the remaining text and the drawings of this application.
Illustrated in
As shown in
The pump 10 also includes one or more deflection structures 40. These deflection structures 40 can take many forms and are configured to interrupt the circular flow of the fluid and change the direction of the fluid so the fluid quickly exits the diffuser 20 and moves toward the pump outlet 16 (instead of re-circulating within the gap G of the diffuser 20 until enough fluid eventually accumulates in the vanes 28 to force a portion out of the diffuser 20). More specifically, the deflection structures 40 are designed to redirect the fluid flow from the gap G toward the pump outlet 16. In some non-limiting examples, the deflection structures 40 are designed to alter the fluid flow of the diffuser 20 to an axial direction generally perpendicular to the circular flow.
As shown in
Directing the fluid to the pump outlet 16 before it can recirculate within the diffuser 20 reduces air bubble accumulation inside the pump 10 while priming, making it easier for air to escape from the pump outlet 16. This in turn allows air to escape the pump outlet 16 faster during priming, reducing back pressure caused by trapped air pockets during priming and dramatically improving the priming performance of the pump 10. The arrangement of the deflection structures 40 can also lead to improved hydraulic efficiencies.
This disclosure will provide a number of examples of suitable deflection structures 40, but this disclosure should not be considered limiting, as the deflection structures can take any suitable form. Any number and/or combination of deflection structures may be used, including one or more such structures. The structures may be present on any surface of the pump 10, including, but not limited to, an internal wall (e.g., the inner diameter) of the pump housing 12, the diffuser 20, an internal wall of the seal plate 22, a separate structure such as a ring, and/or other surfaces or components of the pump 10.
As mentioned above and shown in
Once fluid flowing within the gap G encounters a face 42 of the deflection structure 40a, the fluid is deflected from its circular path 44 to a deflected path (represented by arrow 46 in
More specifically, as shown in
In some examples, a majority of the fluid flowing through the diffuser 20 is diverted from the circular path 44 to the axial path 46 (for example more than 50%, more than 60%, more than 70%, more than 80%, more than 90%, or more than 95%) before recirculating within the gap G.
Like the deflection structures 40b, the deflection structures 40c are configured to block the circular path (represented by arrows 44) of the fluid and divert it into a diverted path (represented by arrows 46 in
In some examples, a majority of the fluid flowing through the diffuser 220 is diverted from the circular path 44 to the axial path 46 (for example more than 50%, more than 60%, more than 70%, more than 80%, more than 90%, or more than 95%) before recirculating within the gap G.
More specifically, as shown in
More specifically, as shown in
In the non-limiting embodiment of
As previously mentioned, a pump according to the invention can include any number and combination of deflection structures.
As used below, any reference to a non-enumerated group of aspects (e.g., “any previous or subsequent aspect”) is to be understood as a reference to each of those aspects disjunctively (e.g., “Aspects A, B, C, or D” and so forth).
Aspect A is a pump for improved priming performance, the pump comprising at least one deflection structure configured to divert fluid moving through a diffuser from a circular path directly to an outlet of the pump.
Aspect B is a pump for improved priming performance, the pump comprising at least one deflection structure extending at least partially into a gap formed between an outer diameter of a diffuser and an inner diameter of a housing of the pump.
Aspect C is a pump for improved priming performance, the pump comprising at least one deflection structure configured to prevent fluid from recirculating within a diffuser through a gap formed between an outer diameter of the diffuser and an inner diameter of a housing of the pump.
Aspect D is a pump for improved priming performance, the pump comprising at least one deflection structure configured to divert fluid flowing through a diffuser in a circular path into an axial path leading directly to an outlet of the pump, where the at least one deflection structure is a rib, a wall, a ramp, a projection, a curved surface, a twisted surface, or an extension.
Aspect E is a pump for improved priming performance, the pump comprising at least one deflection structure extending at least partially into a gap formed between an outer diameter of a diffuser and an inner diameter of a housing of the pump, the at least one deflection structure configured to modify a path of fluid flowing through the gap and wherein the at least one deflection surface is on at least one of: an interior wall of a housing of the pump; a surface of a seal plate of the pump; a ring configured to couple with the diffuser; an impeller of the pump; or the diffuser.
Aspect F is a pump including any of the aspects identified in any of the previous statements A-E.
Aspect G is methods for using the pump in any of the previous statements A-E.
Aspect H is a pump for improved priming performance of a swimming pool or spa, the pump comprising means for diverting fluid moving through a diffuser from a circular path directly to an outlet of the pump.
Aspect I is a pump of any previous or subsequent aspect, wherein the means for diverting diverts a majority of the fluid moving through the diffuser from the circular path to an axial path generally perpendicular to the circular path.
Aspect J is a pump of any previous or subsequent aspect, wherein the means for diverting is at least one deflection structure extending at least partially into a gap formed between an outer diameter of the diffuser and an inner diameter of a housing of the pump.
Aspect K is a pump of any previous or subsequent aspect, wherein the at least one deflection structure extends completely or nearly completely through the gap, thereby preventing the fluid from recirculating within the gap along the circular path.
Aspect L is a pump of any previous or subsequent aspect, where the means for diverting is a rib, a wall, a ramp, a projection, a curved surface, a twisted surface, or an extension.
Aspect M is a pump of any previous or subsequent aspect, wherein the means for diverting is configured to divert the fluid moving through the diffuser by changing a direction of the fluid by approximately 90 degrees.
Aspect N is a pump of any previous or subsequent aspect, wherein the means for diverting forces the fluid into a helical shape toward the outlet of the pump.
Aspect O is a pump of any previous or subsequent aspect, wherein the means for diverting is a plurality of deflection structures integrated with the diffuser.
Aspect P is a pump for improved priming performance of a swimming pool or spa, the pump comprising at least one deflection structure configured to divert fluid flowing through a diffuser in a circular path into an axial path leading directly to an outlet of the pump, where the at least one deflection structure is a rib, a wall, a ramp, a projection, a curved surface, a twisted surface, or an extension.
Aspect Q is a pump of any previous or subsequent aspect, wherein the at least one deflection structure extends at least partially into a gap formed between an outer diameter of the diffuser and an inner diameter of a housing of the pump.
Aspect R is a pump of any previous or subsequent aspect, wherein the at least one deflection structure extends completely or nearly completely through the gap, thereby preventing the fluid from recirculating within the gap along the circular path.
Aspect S is a pump of any previous or subsequent aspect, wherein the at least one deflection structure is configured to divert the fluid moving through the diffuser by changing a direction of the fluid by approximately 90 degrees.
Aspect T is a pump of any previous or subsequent aspect, wherein the at least one deflection structure forces the fluid into a helical shape toward the outlet of the pump.
Aspect U is a pump of any previous or subsequent aspect, wherein the at least one deflection structure is integrated with the diffuser.
Aspect V is pump for improved priming performance of a swimming pool or spa, the pump comprising at least one deflection structure extending at least partially into a gap formed between an outer diameter of a diffuser and an inner diameter of a housing of the pump, the at least one deflection structure configured to modify a path of fluid flowing through the gap, and wherein the at least one deflection structure is on at least one of: an interior wall of the housing of the pump; a surface of a seal plate of the pump; a ring configured to couple with the diffuser; an impeller of the pump; or the diffuser.
Aspect W is a pump of any previous or subsequent aspect, wherein at least one deflection structure is configured to divert a majority of the fluid flowing through the gap from a circular path directly to an outlet of the pump.
Aspect X is a pump of any previous or subsequent aspect, wherein the at least one deflection structure extends completely or nearly completely through the gap, thereby preventing the fluid from recirculating within the gap along the circular path.
Aspect Y is a pump of any previous or subsequent aspect, wherein the at least one deflection structure is configured to modify the path of the fluid from a circular path to an axial path generally perpendicular to the circular path.
Aspect Z is a pump of any previous or subsequent aspect, where the at least one deflection structure is a rib, a wall, a ramp, a projection, a curved surface, a twisted surface, or an extension.
Aspect AA is a pump of any previous or subsequent aspect, wherein the at least one deflection structure is configured to modify the path of the fluid by changing a direction of the fluid by approximately 90 degrees.
Aspect BB is a pump of any previous or subsequent aspect, wherein the at least one deflection structure forces the fluid flowing through the gap out of a circular path and into a helical shape toward an outlet of the pump.
Aspect CC is a pump of any previous or subsequent aspect, wherein the at least deflection structure is integrated with the diffuser.
Aspect DD is a method of improving pump priming performance of a swimming pool or spa, the method comprising diverting fluid moving in a circular path through a diffuser of a pump by changing a direction of the fluid so the fluid flows in an axial path directly to an outlet of the pump instead of the circular path through the diffuser.
These examples are not intended to be mutually exclusive, exhaustive, or restrictive in any way, and the invention is not limited to these example embodiments but rather encompasses all possible modifications and variations and combinations within the scope of any claims ultimately drafted and issued in connection with the invention (and their equivalents). For avoidance of doubt, any combination of features not physically impossible or expressly identified as non-combinable herein may be within the scope of the invention.
Further, although Applicant has described devices and techniques for use with swimming pools and spas, persons skilled in the relevant field will recognize the present invention may be employed with any pump and is not limited to pumps used with swimming pools and spas. More specifically, the pumps disclosed herein can be used to route and distribute any source of water or other fluid. Finally, references to “pools” and “swimming pools” herein may also refer to spas and other water-containing vessels, ponds and other bodies of water, water features such as waterfalls and fountains, water removal or routing apparatuses (e.g., sump pumps), or any other usage involving a pump.
This application claims the benefit of and priority to U.S. Provisional Patent application Ser. No. 63/004,869, filed Apr. 3, 2020, the entire contents of which are hereby incorporated herein by this reference.
Number | Name | Date | Kind |
---|---|---|---|
2934021 | Conery | Apr 1960 | A |
3103177 | Gatto | Sep 1963 | A |
5100289 | Caoduro | Mar 1992 | A |
5226790 | Serafin | Jul 1993 | A |
Number | Date | Country |
---|---|---|
0460597 | Dec 1991 | EP |
9823864 | Jun 1998 | WO |
0068575 | Nov 2000 | WO |
WO-03056185 | Jul 2003 | WO |
Entry |
---|
International Application No. PCT/US2021/022323, International Search Report and Written Opinion dated Jun. 30, 2021, 11 pages. |
International Application No. PCT/US2021/022323, International Preliminary Report on Patentability dated Oct. 13, 2022, 7 pages. |
Number | Date | Country | |
---|---|---|---|
20210310490 A1 | Oct 2021 | US |
Number | Date | Country | |
---|---|---|---|
63004869 | Apr 2020 | US |