The present invention relates generally to a chopper pump for pumping fluids containing solid matter and, more specifically, to a cutting assembly for breaking up solid matter in the fluid being supplied to the chopper pump into smaller pieces.
Chopper pumps are implemented when a fluid supply contains solid matter that needs to be pumped, or displaced. The fluid supply is provided to an inlet of the chopper pump where an impeller rotates adjacent to a cutting plate that may be hardened. Rotation of the impeller adjacent to the cutting plate engages the solid matter and displaces the fluid supply from the inlet to an outlet. Typically, chopper pumps include a hardened impeller to aid in cutting the solid matter and increase the durability of the impeller. However, hardening an impeller inhibits the ability of a user to trim (i.e., remove material from) the impeller to customize pump performance and/or contour the ultimate form factor of the impeller. Additionally, solid matter can become stuck or lodged between the impeller and the cutting plate during operation of the chopper pump, which leads to clogging and/or reduced pump efficiency.
In light of at least the above shortcomings, a need exits for an improved cutting assembly for a chopper pump that aids in removing solid matter that can inhibit performance and enables the form factor of the chopper pump impeller to be contoured or modified, if desired, while maintaining, or improving, cutting performance.
The aforementioned shortcomings can be overcome by providing a cutting assembly for a chopper pump having a cutting insert removably received within a recess in an impeller and arranged adjacent to a cutting plate. The cutting insert is a separate component from the impeller, which negates the desire for the entire impeller to be fabricated from a hardened material. The cutting assembly disclosed allows the discrete cutting insert to be fabricated from a hardened material enabling the impeller, which may not be hardened in certain situations, to be trimmed or modified, if desired. Additionally, the cutting plate includes one or more cutting plate grooves to aid in removing solid matter that could get stuck between the cutting blade insert and the cutting plate.
Some embodiments of the invention provide a cutting assembly for a chopper pump. The cutting assembly includes a cutting insert having a cutting blade extending radially therefrom, and an impeller having a central hub, a plurality of vanes, and an insert surface. The cutting insert includes at least one cutting groove axially recessed into the cutting insert. The insert surface defines an axial recess that is dimensioned to receive the cutting insert therein. The cutting assembly further includes a cutting plate having a plate hub with a cutting extension protruding radially inward therefrom. Rotation of the impeller rotates the cutting blade past the cutting extension.
Some embodiments of the invention provide a chopper pump including a drive section having a drive shaft, and a housing coupled to the drive section and having an inlet, an outlet, and an internal cavity arranged between the inlet and the outlet. The chopper pump further includes an impeller received within the internal cavity and coupled to the drive shaft for rotation therewith. The impeller includes a recess formed therein. The chopper pump further includes a cutting insert received within the recess of the impeller. The cutting insert includes a cutting groove axially recessed into the cutting insert. The cutting insert can include a cutting blade. The chopper pump further includes a cutting plate coupled to the housing within the internal cavity. The cutting plate includes a cutting extension that extends radially inward. Rotation of the impeller rotates the cutting blade past the cutting extension.
Some embodiments of the invention provide a cutting assembly for a chopper pump. The cutting assembly includes a cutting insert having at least one cutting blade extending radially therefrom. The cutting assembly further includes an impeller having a central hub, a plurality of vanes, and an insert surface. The insert surface includes a plurality of insert apertures arranged to align with a corresponding plurality of mounting apertures on the cutting insert.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” or “having” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Unless specified or limited otherwise, the terms “mounted,” “connected,” “supported,” and “coupled” and variations thereof are used broadly and encompass both direct and indirect mountings, connections, supports, and couplings. Further, “connected” and “coupled” are not restricted to physical or mechanical connections or couplings.
The following discussion is presented to enable a person skilled in the art to make and use embodiments of the invention. Various modifications to the illustrated embodiments will be readily apparent to those skilled in the art, and the generic principles herein can be applied to other embodiments and applications without departing from embodiments of the invention. Thus, embodiments of the invention are not intended to be limited to embodiments shown, but are to be accorded the widest scope consistent with the principles and features disclosed herein. The following detailed description is to be read with reference to the figures, in which like elements in different figures have like reference numerals. The figures, which are not necessarily to scale, depict selected embodiments and are not intended to limit the scope of embodiments of the invention. Skilled artisans will recognize the examples provided herein have many useful alternatives and fall within the scope of embodiments of the invention.
As shown in
The housing 16 defines an internal cavity 24 in fluid communication with the inlet 18 and the outlet 20. A cutting assembly 26 is configured to be arranged within the internal cavity 24 of the housing 16. The cutting assembly 26 includes a cutting insert 28, an impeller 30, and a cutting plate 32. The cutting insert 28 is releasably coupled to the impeller 30 and is arranged adjacent to the cutting plate 32. The cutting insert 28 and the impeller 30 are fastened to the drive shaft 22 via an impeller fastening element 34 in the form of a threaded bolt. This enables the impeller 30 and the cutting insert 28 to rotate with the drive shaft 22 in a desired direction.
As shown in
The illustrated impeller 30 is in the form of a semi-open impeller. In other embodiments, the impeller 30 may be in the form of an open impeller or any other form capable of receiving a cutting insert. The impeller 30 includes a shroud 46 having a first shroud surface 48 and an opposing second shroud surface 50. A plurality of vanes 52 extend from and are arranged circumferentially around the first shroud surface 48 of the impeller 30. The plurality of vanes 52 define a substantially curved shape that curves from a shroud outer surface 54 of the shroud 46 toward a central hub 56 of the impeller 30. The curvature defined by the plurality of vanes 52 is similar to the curvature defined by the plurality of cutting blades 36 (as shown in
The central hub 56 of the impeller 30 includes a recess 58 defined by an insert surface 60 that is axially recessed and dimensioned to receive the cutting insert 28. The recess 58 is dimensioned to accommodate the cutting insert 28 therein. The insert surface 60 extends from the central hub 56 partially along each of the plurality of vanes 52. That is, each of the plurality of vanes 52 defines a step change in an axial dimension at a location between the shroud outer surface 54 and the central hub 56. The location at which the step change in axial dimension occurs in each of the plurality of vanes 52 is congruent with a distance that the plurality of cutting blades 36 radially extend from the insert central hub 38 of the cutting insert 28. Additionally, an axial depth of the recess 58 (i.e., the magnitude of the step change in axial dimension of the plurality of vanes 52) is congruent with a thickness of the plurality of cutting blades 36. In this way, when the cutting insert 28 is inserted into the recess 58 of the impeller 30 (as shown in
With continued reference to
The cutting plate 32 includes a cutting extension 66 protruding radially inward from an inner surface 68 of a plate hub 70. The illustrated cutting plate 32 includes one cutting extension 66 arranged on the inner surface 68 of the plate hub 70. In other embodiments, the cutting plate 32 may include more than one cutting extension 66 arranged circumferentially around the inner surface 68. For example, in one embodiment, the cutting plate 32 may include two cutting extensions 66 arranged circumferentially in approximately 180 degree increments on the inner surface 68. In another embodiment, the cutting plate 32 may include three cutting extensions 66 arranged circumferentially in approximately 120 degree increments on the inner surface 68.
The inner surface 68 of the plate hub 70 defines an opening with a diameter that is substantially equal to a diameter of the inlet 18 of the housing 16. The plate hub 70 extends substantially perpendicularly from a base 72 of the cutting plate 32. The base 72 of the cutting plate 32 includes a mounting surface 74 having a plurality of threaded mounting apertures 76 arranged circumferentially around and extending through the mounting surface 74.
The housing 16 includes an inlet face 77 having a plurality of plate apertures 78 and a plurality of threaded ring apertures 80 arranged thereon. The plurality of plate apertures 78 and the plurality of threaded ring apertures 80 are alternatingly arranged circumferentially around the inlet face 77 of the housing 16. The plurality of plate apertures 78 extend axially through an inlet wall 81 of the housing 16, which circumscribes the inlet 18. The plurality of plate apertures 78 are dimensioned to receive a fastening element 84 in the form of a threaded bolt. The plurality of ring apertures 80 extend partially through the inlet wall 81 and are arranged radially inward compared to the plurality of plate apertures 78. The plurality of ring apertures 80 are dimensioned to receive a fastening element 82 in the form of a threaded bolt.
When assembled (as shown in
The relative threaded interaction between the fastening elements 84 secured to the cutting plate 32 and the fastening elements 82 securing the retainer ring 85 enables the axial relation between the cutting plate 32 and the cutting insert 28 to be selectively controlled. That is, the cutting plate 32 is axially adjustable by adjusting an axial depth that the fastening elements 84 are threaded into the plurality of threaded mounting apertures 76 and/or by adjusting an axial distance between the inlet face 77 and the retainer ring 85, which is set by the fastening elements 82. In one implementation, the axial relation between the cutting plate 32 and the cutting insert 28 may be set by the axial depth the fastening elements 84 are threaded into the threaded mounting apertures 76, and the retainer ring 85 may be utilized to secure the cutting plate 32 in place via the fastening elements 82. In another implementation, the axial relation between the cutting plate and the cutting insert 28 may be set by the axial distance between the retainer ring 85 and the inlet face 77, which is controlled via the fastening elements 82, and the fastening elements 84 may be utilized to secure the cutting plate 32 in place.
As shown in
As shown in
When the cutting assembly 26 is assembled as shown in
During operation of the chopper pump 10, the drive section 12 is configured to rotate the impeller 30, and thereby the cutting insert 28, in a desired direction. The rotation of the impeller 30 creates a low pressure at the inlet 18 that draws a process fluid into the inlet 18. From the inlet 18, the process fluid is drawn into the internal cavity 24 of the housing 16 where rotation of the impeller 30 centrifugally furnishes the process fluid to the outlet 20 at an increased pressure.
While the process fluid is passing from the inlet 18 to the outlet 20 during operation of the chopper pump 10, the process fluid flows through the cutting assembly 26. In particular, rotation of the impeller 30 rotates the cutting blades 36 of the cutting insert 28 past the cutting extension 66 of the cutting plate 32. The leading edges 86 of the cutting insert 28, which include the plurality of serrated teeth 90, rotate past the cutting extension 66 and over the extension groove 106 in a scissor-type cutting action to break up and engage solids in the incoming process fluid flow. Additionally, the serrated teeth 90 may engage and break up string-like materials prior to entering the internal cavity 16. Further, the axial portions 96 of the cutting grooves 92 rotate past the distal ends 100 of the cutting extension 66, and the radial portions 94 of the cutting grooves 92 rotate past the extension groove 106 formed in the back surface 108 of the cutting extension 66. Thus, the illustrated cutting assembly 26 provides additional cutting, chopping, or engagement locations by rotation of the axial portions 96 of the cutting grooves 92 past the distal end 100 of the cutting extension 66, and by rotation of the radial portions 94 of the cutting grooves 92 past the extension groove 106 formed in the back surface 108 of the cutting extension 66. These additional cutting, chopping, and/or engagement locations interact with and may alleviate the influence of solids that can get stuck or trapped within the cutting assembly 26.
Once the chopper pump 10 is powered down, the cutting plate 32 may be axially adjusted with respect to the impeller 30, and the cutting insert 28 fastened therein, by adjusting an axial depth the fastening elements 82 and/or the fastening elements 84, as described above. Since the cutting insert 28 is a separate, or discrete, component relative to the impeller 30, the impeller 30 may not need to be fabricated from a hardened material. Additionally, since the cutting insert 28 may negate the need for the impeller 30 to be fabricated from a hardened material, the impeller 30 may be trimmed or modified, as desired. Furthermore, if the cutting, chopping, or pumping performance of the chopper pump 10 deteriorates over time, the cutting insert 28 or the impeller 30 may be replaced independently as required, and as opposed to an entire impeller structure.
A coupling member 212 is configured to be received through the shredder hub 210 and couple the shredder 202 to the drive shaft 22 and the impeller 30 for rotation therewith. When assembled, the cutting insert 28 is positioned between the shredder 202 and the impeller 30. The cutter ring 204 is dimensioned to be received within the inlet 18 of the housing 16. An inner surface 214 of the cutter ring 204 includes a plurality of cutting recesses 216 arranged circumferentially around the inner surface 214. The plurality of cutting recesses 216 each define a generally U-shaped cutout on the inner surface 214 of the cutter ring 204.
When assembled, as shown in
With reference to
The shredder extensions 208 include a first shredding surface 228, a second shredding surface 230, and a tip protrusion 232. The first shredding surface 228 defines a generally S-shaped profile and includes a convex portion 234 and a concave portion 236. The second shredding surface 230 defines a generally convex profile. The tip protrusions 232 form a generally triangular shaped extension protruding from a lower surface 238 of each shredder extension 208 adjacent to a distal tip end 240 thereof. The combination of the first shredding surfaces 228 and the second shredding surfaces 230 provide each shredder extension 208 with a generally frustoconical shape that tapers towards the lower surface 238. That is, a thickness of the shredder extensions 208 may decrease as it extends toward the lower surface 238.
In operation, the cutting action between the cutting insert 28 and the cutting plate 32 for the cutting assembly 200 is similar to the operation of the cutting assembly 26, described above. In addition, the shredder 202 rotates with the drive shaft 22, which rotates the shredder extensions 208 within the cutter ring 204 past the plurality of cutting recesses 216. The rotation of the shredder extensions 208 within the cutter ring 204 can push debris away from the suction within the inlet 18 to attempt to prevent the inlet 18 from becoming completely blocked by debris. Also, the frustoconical shape defined by the shredder extensions 208 helps improve performance of the pump 10 by increasing flow. That is, the frustoconical shape improves flow by enabling the shredder 202 to act as a stage where rotation of the shredder 202 results in pumping of the fluid prior to the fluid entering and/or passing through the inlet 18.
The housing 16 includes a plurality of adjusting apertures 306 and a plurality of set apertures 308. The plurality of adjusting apertures 306 and the plurality of set apertures 308 are alternatingly arranged circumferentially around the inlet 18 of the housing 16. The plurality of adjusting apertures 306 are dimensioned to receive one of the adjusting fastening elements 302, which may be in the form of a threaded bolt. The plurality of set apertures 308 are dimensioned to threading receive one of the set fastening elements 304, which may be in the form of a threaded bolt.
When assembled, the plurality of adjusting fastening elements 302 extend through a corresponding one of the adjusting apertures 306 and into a corresponding one of the plurality of threaded mounting apertures 76. This fastens the cutting plate 32 within the internal cavity 24 of the housing 16 adjacent to the inlet 18. The set fastening elements 304 are threaded through a corresponding one of the plurality of adjusting apertures 308 to engage the mounting surface 74 of the cutting plate 32. In this way, the set fastening elements 304 act as a standoff or spacer to control an axial distance between the cutting plate 32 and the cutting insert 28. That is, the cutting plate 32 is axially adjustable by adjusting an axial depth of the plurality of set fastening elements 304 and subsequently adjusting the adjusting fastening elements 302 until the mounting surface 74 of the cutting plate 32 engages the plurality of set fastening elements 304.
It will be appreciated by those skilled in the art that while the invention has been described above in connection with particular embodiments and examples, the invention is not necessarily so limited, and that numerous other embodiments, examples, uses, modifications and departures from the embodiments, examples and uses are intended to be encompassed by the claims attached hereto. The entire disclosure of each patent and publication cited herein is incorporated by reference, as if each such patent or publication were individually incorporated by reference herein.
Various features and advantages of the invention are set forth in the following claims.
This application is a continuation of U.S. patent application Ser. No. 15/498,085 filed on Apr. 26, 2017, which claims priority under 35 U.S.C. § 119 to U.S. Provisional Patent Application No. 62/327,810 filed on Apr. 26, 2016, the entire disclosures of which are incorporated herein by reference.
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Number | Date | Country | |
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Parent | 15498085 | Apr 2017 | US |
Child | 16741231 | US |