This invention relates generally to sewage grinder pumps and more particularly to two-stage high head low flow sewage grinder pumps.
Many residential sewer systems use only the force of gravity to provide for discharging its wastewater into progressively larger sewer mains and ultimately to a dedicated treatment plant that is usually located in a low-lying area such that gravity can assist the flow of sewage. However, in a hilly land area, in a below-grade setting, along long horizontal pipe runs or perhaps due to smaller-diameter piping restrictions, gravity often will not suffice. In such situations, a lift-station or a stand-alone sewage ejector pump is required if gravity alone will not allow flow of sewage at a speed of at least 2 feet per second, which is considered to be a minimum required velocity to maintain suspended sewage solids in suspension. One type of ejector pump is a submersible grinder pump. In areas of flow pressure, one can employ such a fixture to move the sewage from a given location to a sewage collection system. The pump may be installed below the nearest available sewer line. The pump will either lift the waste to the level of the main drain or move the sewage through the piping.
Grinder pumps cut and grind solid materials into tiny pieces and are designed to reduce sewage particulate to a slurry. This overcomes sewage passageways restrictions and allows free movement of the fluid. A commonly used submersible grinder pump is a centrifugal pump with a recessed vortex impeller. In these systems, one can expect a power range of 2 to 7.5 horsepower (HP). Residences generally use the 2 HP models, principally due to its compatibility with typical residential electric-circuit configurations that provide comparatively low power. However, one may require a larger HP centrifugal pump, an intermediate lift station, or a progressing cavity style pump when sewer system pressures or flow resistance exceeds the capabilities of a 2 HP centrifugal pump. In residential applications, such systems are often unaffordable.
The progressing cavity pump's major advantage is its ability to work under relatively high pressures and allow service to areas with high-pressure requirements without the need for additional lift stations or relatively high HP pumps. Unfortunately, wear items that readily fail at high pressures, such as that pump's wobble stator arrangement, are a significant disadvantage.
Alternatively, centrifugal pumps offer higher flow rates than progressing cavity style pumps, have the ability to handle abrasives and slurries, and can operate at stall head or zero flow for extended periods without causing pump damage. For example, design pressures can be readily exceeded and can remain high until an upset condition, such as excessive simultaneous operations following a power outage, or high infiltration caused by poor installation, is resolved. However, a 2 HP residential centrifugal pump will have a significantly lower pressure limitation than a progressing cavity pump and is not suited for pressure sewer systems that achieve a total system head (distance pump is capable of lifting fluid) greater than 120 feet at the pump.
Thus, in a pressure sewer system where upset conditions produce high system pressures, both the progressing cavity and typical single-stage centrifugal grinder pumps lack relevant design efficiencies and possess limiting capabilities. However, since the centrifugal pump with recessed vortex impeller is more robust and reliable, a welcome pump design modification will combine this advantage with the high-pressure advantage of the progressing cavity pump to produce a pump that is affordable and still suitable to residential applications.
The foregoing illustrates limitations known to exist in present sewage grinder pumps. Thus, it is apparent that it would be advantageous to provide an alternative directed to overcoming one or more of the limitations set forth above. Accordingly, a suitable alternative is provided including features more fully disclosed hereinafter.
In one aspect of the present invention, this is accomplished by providing a sewage grinder pump comprising: a housing; a motor enclosed within the housing, the motor having a shaft extending therefrom; a plurality of impellers attached to the motor shaft; and a grinder attached to the motor shaft, the grinder and the plurality of impellers having a common axis of rotation.
In another aspect of the present invention, this is accomplished by providing a sewage grinder pump comprising: a housing; a motor enclosed within the housing, the motor having a shaft extending therefrom; a pump attached to the motor shaft; and a grinder attached to the motor shaft, the housing having a discharge conduit monolithic therewith, the discharge conduit being in fluid communication with the pump.
In another aspect of the present invention, this is accomplished by providing a method for grinding and pumping sewage comprising: providing a motor having a shaft extending therefrom with a first stage impeller, a second stage impeller and a grinder attached thereto; operating the motor to rotate the attached impellers and grinder; introducing sewage into the grinder; grinding any solids contained in the sewage in the grinder; passing sewage from the grinder into the first stage impeller; increasing the pressure of the sewage by rotation of the first stage impeller; passing sewage from the first stage impeller into the second stage impeller; increasing the pressure of the sewage further by rotation of the second stage impeller; and discharging the pressurized sewage into a sewer system.
In another aspect of the present invention, this is accomplished by providing a sewage grinder pump comprising: a housing; a motor enclosed within the housing, the motor having a shaft extending therefrom, the motor being about 2 horsepower; two impellers attached to the motor shaft, a first stage impeller and a second stage impeller, the sewage grinder pump having a stall head greater than about 200 feet and a maximum flow greater than about 30 gallons per minute; and a grinder attached to the motor shaft.
In another aspect of the present invention, this is accomplished by providing a sewage grinder pump comprising: a housing; a motor enclosed within the housing, the motor having a shaft extending therefrom; a pump attached to the motor shaft; a grinder attached to the motor shaft; and a discharge flange in fluid communication with the pump, the discharge flange having a check valve integral therewith.
In another aspect of the present invention, this is accomplished by providing a sewage grinder pump comprising: a housing; a motor enclosed within the housing, the motor having a shaft extending therefrom; a pump operably attached to the motor shaft; a grinder operably attached to the motor shaft; and a discharge conduit in fluid communication with the pump, the discharge conduit having an anti-siphon valve integral therewith, the antisiphon valve having a valve seat and a movable valve.
In another aspect of the present invention, this is accomplished by providing a method of installing a sewage grinder pump in a basin, the basin having a sewage outlet connection, the method comprising: providing a sewage grinder pump; selecting an appropriate discharge flange from a plurality of discharge flanges comprising at least one discharge flange having a first configuration and at least one discharge flange having a second configuration; attaching the discharge flange to the sewage grinder pump; positioning the sewage grinder pump with the attached discharge flange within the basin; attaching the discharge flange to a sewage outlet connection.
In another aspect of the present invention, this is accomplished by providing a sewage grinder pump comprising: a housing; a motor enclosed within the housing, the motor having a shaft extending therefrom; a pump operably attached to the motor shaft; a grinder operably attached to the motor shaft; and a discharge flange attached to the housing, the discharge flange being in fluid communication with the pump, the discharge flange having a connector assembly, the connector assembly adapted to connect the discharge flange to a sewage outlet, the connector assembly including an elastomeric seal for sealingly engaging the sewage outlet.
The foregoing and other aspects will become apparent from the following detailed description of the invention when considered in conjunction with the accompanying drawing figures.
Sewage grinder pump 10 is further supported within basin 100 by a suspension cable 12. A pair of electrical conduits 14 provide electrical power and control signals to sewage grinder pump 10.
In operation, as the sewage level in basin 100 rises to a predetermined level, the pump control system turns the pump on. Sewage and any entrained solids enter the pump inlet 41 where the solids are reduced in size in grinder 60. The pressure of the sewage and the contained comminuted solids is then raised by the two stages of vortex impellers 30, 32. Preferably, the pump motor 22 is a 2 HP motor and the sewage grinder pump 10 has a shut-off head greater than about 200 feet and a maximum flow greater than about 30 gallons per minute, as shown in
In one embodiment, sewage grinder pump 10 is provided with a plurality of pumping stages, see
Referring to
Starting with the pump housing 40, shown in an enlarged cross-section in
From the grinder 60, the sewage flows into the first stage volute 55. First stage impeller 30 increases the pressure and discharges into discharge passage 43, where the sewage passes into the inter-stage conduit 42 and enters the second stage volute 56 via second stage inlet 45. Second stage impeller 32 increases the pressure to the final discharge pressure and the sewage passes into the second stage outlet 47 and into pump housing outlet 44.
Preferably, impellers 30, 32 are both vortex impellers. As shown in
Referring again to
Impellers 30, 32 and grinder 60 are preferably attached to the same shaft and, more preferably, the impellers 30, 32 are positioned between the motor 22 and the grinder 66.
The discharge conduit 70 is monolithic with motor housing 20. Preferably, motor housing 20 and discharge conduit 70 are a monolithic casting. The discharge conduit 70 is positioned external to the portion of motor housing 20 that encloses motor 22. The discharge 70 connects the pump housing outlet 44 to the inlet 81 of the discharge flange 75. Discharge conduit 70 has an anti-siphon valve 71 integral therewith.
Details of anti-siphon 71 are shown in
Attached to the top of motor housing 20 is discharge flange 75. Discharge flange 75 has a lift handle 76 formed therein. Within discharge flange 75 is a fluid conduit 80 having an inlet 81 and an outlet 82. The inlet 81 of fluid conduit 80 is connected to the discharge of discharge conduit 70. Integral with discharge flange 75 is a check valve 78. Check valve 78 includes a removable valve seat 79 positioned within the inlet 81 of the fluid conduit 80. A movable valve 77 is attached to the valve seat 79. Check valve movable valve 77 is similar to anti-siphon movable valve 73, but does not include bleeder 69.
Because check valve 78 is integral with discharge flange 75, installation of sewage grinder pump 10 is simplified by eliminating the need to provide additional piping with a separate check valve. Other configurations of pumps can be accommodated by providing discharge flanges 75 in various configurations (see
The sewage grinder pump 10 of the present invention can be retro-fitted as a replacement for other style pumps. One such retro-fit pump 200 is shown in
In one embodiment, discharge flange 75 includes a connector assembly 84 for connecting the discharge of sewage grinder pump 10 to the sewage outlet 110 via a connecting conduit 116 and isolation valve 104. The connector assembly 84 includes a flange 89 that slidably engages a connecting flange 112 attached to support wall 114 (see
Sewage grinder pump 10 is installed by lowering the pump 10 into the basin 100 using suspension cable 12 and lift handle 76. Flange 89 is slid into the C-shaped basin connecting flange 112 with the elastomeric seal 86 engaging the connecting conduit mounting assembly 117 about the connecting conduit 116 to seal sewage grinder pump 10 to the sewage outlet. Flange 89 sits upon upper support 108 and a flange on the lower end of motor housing 20 sits upon lower support 109 to support sewage grinder pump 10 within basin 100.
This application is a national stage entry of PCT/lB2004/052100, filed Oct. 14, 2004, which designates the United States of America and which claims priority from provisional application 60/511,288, filed Oct. 14, 2003, the disclosure of which is hereby incorporated by reference.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2004/052100 | 10/14/2004 | WO | 00 | 4/6/2006 |
Publishing Document | Publishing Date | Country | Kind |
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WO2005/035447 | 4/21/2005 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3650481 | Conery et al. | Mar 1972 | A |
6010086 | Earle et al. | Jan 2000 | A |
6916152 | Keener | Jul 2005 | B2 |
Number | Date | Country | |
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20070069050 A1 | Mar 2007 | US |
Number | Date | Country | |
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60511288 | Oct 2003 | US |