The technical field relates to pumps, and, more particularly to pumps used to pump mixtures of solids and liquids, solids-laden mixtures, and slurries.
Centrifugal pumps use centrifugal force to move liquids from a lower pressure to a higher pressure and employ an impeller, typically comprising of a connecting hub with a number of vanes and shrouds, rotating in a volute or casing. Liquid drawn into the center of the impeller is accelerated outwardly by the rotating impeller vanes toward the periphery of the casing, where it is then discharged at a higher pressure.
Centrifugal pumps, such as trash pumps, are conventionally used in applications involving mixtures of solids and liquids, solids-laden mixtures, slurries, sludge, raw unscreened sewage, miscellaneous liquids and contaminated trashy fluids, collectively referred to as mixed-media flow or mixed-media fluids. These mixed-media fluids are encountered in applications including, but not limited to, sewage plants, sewage handling applications, paper mills, reduction plants, steel mills, food processing plants, automotive factories, tanneries, and wineries.
As one example, such pumps are used in sewage lift stations to move wastewater to a wastewater treatment plant. In some aspects, submersible pumps are disposed in a wet well below ground (e.g., 20′ below ground) and are configured to lift the wastewater to an elevation just below ground level, where it is passed to downwardly sloping conduits that utilize gravity to move the flow along the conduit to the next lift station. This operation is repeated at subsequent lift stations to move the wastewater to a wastewater treatment plant. Another form of lift station utilizes “dry well” pumps, wherein one or more self-priming centrifugal pumps and associated controls and drivers (i.e., motor or engine) are either located in a (dry) building above ground or in a (dry) fiberglass (or concrete, metal, and/or polymer) room disposed below ground. Above-ground configurations utilize a self-priming centrifugal pump and an intake extending down into a wet well holding the influent wastewater. An exemplary solids-handling self-priming centrifugal pump for such application includes the Gorman Rupp T-Series™ or Super T-Series™ pumps, which feature a large volute design allowing automatic re-priming in a completely open system without the need for suction or discharge check valves and with a partially liquid-filled pump casing and a dry suction line. Depending on the size and configuration, these pumps generally handle a maximum solids diameter of between about 1.5″-3″ with a maximum head of between about 110 ft.-150 ft. Below-ground configurations typically use either a non-self-priming centrifugal pump disposed beneath the wet well, so as to provide a flooded pump suction, or use a self-priming pump. Flooded non-self-priming pumps correspondingly require an isolation means (e.g., a valve) to permit isolation of the pump suction to allow for pump cleaning and maintenance.
Controls in either the wet well or dry well monitor the wet well level and turn on one or more pumps as necessary to maintain a desired wet well state. The operation of the lift stations are often remotely monitored by means such as SCADA (Supervisory Control and Data Acquisition) systems or local node boxes at the lift station which transmit information to a base station or intermediary (e.g., Internet) at selected intervals via a hard-wired land line or transmission, such as microwave or RF signal.
The nature of the conveyed medium poses significant challenges to continuous operation of the pumps. One potential problem in such applications is the clogging of the impeller or pump by debris in the pumped medium. Therefore, pump serviceability is an important factor. Conventional multi-stage pumps comprise a plurality of sequentially stages arranged so that the discharge portion of one stage feeds liquid into the inlet portion of the next stage and each impeller is driven by a common impeller drive shaft. Rotation of the impeller drive shaft turns each impeller to force fluid outwardly into an internal passage which directs the fluid to the subsequent adjacent pump stage. However, these internal passages are difficult to clean and the pump must be substantially dismantled to permit cleaning. Predictably, these multi-stage pumps are used in applications where fouling or clogging not of concern, such as well or water pumps, and these pumps are not conducive to use in mixed-media flow.
Additional improvements in pump characteristics, such as discharge head, would be advantageous in many applications. For example, in the above-noted sewage handling application, lift stations are expensive to build, with a cost that typically ranges between about forty five thousand dollars and several hundred thousand dollars and may even exceed a million dollars in some instances. A higher head solids-handling self-priming centrifugal pump could be used to reduce the number of lift stations required to transmit wastewater to a wastewater treatment facility. Use of larger, higher-head trash pumps is possible, but such large pumps would have to operate at speeds higher than is generally advisable for a trash-type impeller, particularly in view of the fact that sewage pumps are expected to provide efficient operation for long periods of time without the need for frequent maintenance. Addition of pumps in series with existing pumps in a conventional manner is cumbersome or highly impractical given the space constraints imposed by the limited space available in conventional lift stations and would be a costly proposition when the additional space requirements are factored into the designs of new, more expansive facilities.
Accordingly, there is a need for an improved multi-pump configuration for pumping mixtures of solids and liquids, solids-laden mixtures, and slurries. There is also a need for an improved pump configuration providing increases in pump performance while simultaneously maintaining a compact configuration (e.g., without increasing the footprint of the pump).
In one aspect, a stacked pump arrangement for mixed-media flow includes a first, self-priming, centrifugal pump with a volute having an inlet and an outlet and a second straight centrifugal pump mounted to an upper portion of the first centrifugal pump, the second straight centrifugal pump also having a volute with an inlet and an outlet. A transition chamber is connected, at one end, to the first centrifugal pump volute outlet and is connected, at another end, to the second straight centrifugal pump volute inlet.
In another aspect, a pump arrangement is provided comprising a first self-priming centrifugal pump, comprising a volute having an inlet and an outlet, and a first rotating assembly comprising an impeller shaft and impeller and a second straight centrifugal pump mounted externally to an upper portion of the first centrifugal pump, the second straight centrifugal pump comprising a volute with an inlet and an outlet, a second rotating assembly comprising an impeller shaft and impeller. This arrangement also includes a transition chamber connected, at one end, to the first centrifugal pump volute outlet and connected, at another end, to the second straight centrifugal pump volute inlet. In various other aspects thereof, the first centrifugal pump impeller shaft is aligned with the second straight centrifugal pump impeller shaft along a longitudinal axis and/or a vertical axis and the rotating assemblies may be driven by separate power sources or by a common power source.
In yet another aspect, a pump arrangement is provided comprising a first self-priming centrifugal pump comprising a volute having an inlet and an outlet, and a first rotating assembly comprising an impeller shaft and impeller and a second straight centrifugal pump mounted externally to an upper portion of the first centrifugal pump, the second centrifugal pump comprising a volute with an inlet and an outlet, a second rotating assembly comprising an impeller shaft and impeller. A transition chamber serving as both a structural support for the second centrifugal pump and a flow path for mixed media flow between the first centrifugal pump and the second centrifugal pump is connected, at one end, to the first centrifugal pump volute outlet and is connected, at another end, to the second centrifugal pump volute inlet.
Other aspects and advantages of the present disclosure will become apparent to those skilled in this art from the following description of preferred aspects taken in conjunction with the accompanying drawings. As will be realized, the disclosed concepts are capable of other and different embodiments, and its details are capable of modifications in various obvious respects, all without departing from the spirit thereof. Accordingly, the drawings, disclosed aspects, and description are to be regarded as illustrative in nature, and not as restrictive.
a)-8(b) show examples of a stacked pump arrangement in accord with the present concepts showing a power source and power transmission elements.
In some aspects, impeller 401 may comprise gray iron, ductile iron, hard iron, CF8M stainless-steel, or CD4MCu. In one aspect, the impeller 401 may comprise an impeller such as described in the patent application titled “Improved Impeller and Wear Plate”, assigned to the Gorman-Rupp Company, and filed on Oct. 31, 2003 as patent application Ser. No. 10/697,162, and which is hereby incorporated by reference in its entirety. The rotating assembly 400 is attached to a corresponding surface of the centrifugal pump 100 casing or housing 101 using one or more mechanical fasteners, such as a plurality of bolts or screws. O-rings 417, 416 are provided to both seal the connection between the rotating assembly 400 and such corresponding surface of the centrifugal pump casing 101, as well as to facilitate external clearance adjustments.
The removable cover and wear plate assembly 300, which is also offered by the Gorman-Rupp Company, is shown to include a cover plate 328 having a handle 336, locking collar 329, adjustment screw 331, hand nut 333, and hex head capscrew 332. The removable cover and wear plate assembly 300 is described in the patent application titled “Centrifugal Pump Having Adjustable Cleanout Assembly”, assigned to the Gorman-Rupp Company, and filed on Sep. 16, 2002 as patent application Ser. No. 10/221,825, and which is hereby incorporated by reference in its entirety. In one aspect, shown in
Connecting members 316 are provided to dispose the wear plate 323 at a predetermined location within the volute. In the illustrated example, the connecting members 316 are solid ribs and the position of the wear plate 323 may be adjusted by adjusting a position of the cover plate 328 relative to the centrifugal pump 100 casing. In other aspects, however, connecting members 316 may be adjustable to permit positioning adjustment by variation of an adjustable length of the connecting members. A suction flange 338 and suction gasket 339 are connected to the volute 301 by mechanical fasteners, such as a plurality of bolts or screws 337, to provide a suction inlet. Alternately, other conventional universal sealing arrangements may be provided in place of the removable cover and wear plate assembly 300.
A flap valve or check valve 113 is optionally disposed on an inside of the suction inlet and affixed at an upper end to the centrifugal pump casing 101 by a flap valve cover 114. Flap valve cover 114 is preferably attached with mechanical fasteners that permit the flap valve 113 to be accessed without the need for special tools.
In one aspect, shown in
As shown in
In the example shown in the cross-sectional view of
Pumps 100, 200 may be driven by a single electric motor, such as a variable frequency drive (VFD), or other conventional power source (e.g., a fuel-based combustion engine, such as a gas or diesel engine) through an appropriate power transmission device, such as shown in
Power transmission may be had by conventional flat belt, V-belt, wedge belt, timing belt, spur gear, bevel gear, helical gear, worm gear, slip clutch, and chain and a correspondingly configured matching pulley, gear, and/or gear set, as applicable, or by any other conventional power transmission member(s). A sheave and V-belt drive system, for example, is employed with the number of sheaves and V-belts selected to accommodate, in a manner known to those of ordinary skill in the art, the range of torques intended to be transmitted from the power source to the associated drive shaft or impeller shaft.
a)-8(b) depict examples of various belt drive configurations.
As compared to a conventional Gorman-Rupp Company Super T-series™ self-priming centrifugal pump which provides, for a pump speed of about 1550 rpm, a TDH (Total Dynamic Head) of about 120 ft. at zero flow which slowly decreases to about 100 ft. TDH at 700 gpm and about 70 ft. TDH at 1400 gpm. The stacked pump arrangement in accord with the present concepts produces, at a pump speed of about 1950 rpm, a TDH of about 400 ft. at zero flow which decreases to about 335 ft. TDH at 700 gpm and about 270 ft. TDH at 1400 gpm. These figures represent preliminary test data and are intended to be illustrative in nature and are not intended to necessarily represent production operational characteristics.
In accord with the present disclosure, this stacked pump arrangement provides a higher discharge head while maintaining the footprint of a single pump and as well as the simplicity of serviceability offered by conventional Gorman-Rupp pumps. Inasmuch as the present invention is subject to many variations, modifications and changes in detail, it is intended that all subject matter described above or shown in the accompanying drawings be interpreted as merely illustrative in nature.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US05/07593 | 3/8/2005 | WO | 00 | 11/20/2007 |
Number | Date | Country | |
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Parent | 10794400 | Mar 2004 | US |
Child | 10592145 | US |