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Publication numberUS3836001 A
Publication typeGrant
Publication dateSep 17, 1974
Filing dateJul 19, 1972
Priority dateJul 19, 1972
Also published asCA995916A, CA995916A1, US3949578
Publication numberUS 3836001 A, US 3836001A, US-A-3836001, US3836001 A, US3836001A
InventorsR Heldreth
Original AssigneeWestinghouse Electric Corp
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Pump with self-cleaning lint filter
US 3836001 A
Abstract
The invention provides a bi-directional single-impeller centrifugal pump having a filter screen enclosed within the pump housing and interposed, in the pump chamber, between the single pump inlet and one of two outlets defined in the housing for filtering the fluid pumped through the one outlet in response to the impeller rotating in one direction. When the impeller is reversed to pump the fluid through the other outlet, the particles of lint etc., retained within the pump chamber by the filter screen are then free to exit the pump as flushed therefrom by the fluid being pumped through the other outlet.
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United States Patent [191 Heldreth [451 Sept. 17, 1974 1 PUMP WITH SELF-CLEANING LINT FILTER [75] Inventor: Robert L. Heldreth, Mansfield, Ohio [73] Assignee: Westinghouse Electric Corporation,

Pittsburgh, Pa.

[22] Filed: July 19, 1972 [21] Appl. No.: 273,257

[52] US. Cl 210/167, 210/409, 210/416 [56] References Cited UNITED STATES PATENTS Smith 210/416 Douglas 415/152 A Primary ExaminerFrank A. Spear, Jr. Attorney, Agent, or Firm-F. A. Winans [5 7 ABSTRACT The invention provides a bi-directional single-impeller centrifugal pump having a filter screen enclosed within the pump housing and interposed, in the pump chamber, between the single pump inlet and one of two outlets defined in the housing for filtering the fluid pumped through the one outlet inresponse to the impeller rotating in one direction. When the impeller is reversed to pump the fluid through the other outlet, the particles of lint etc., retained within the pump chamber by the filter screen are then free to exit the pump as flushed therefrom by the fluid being pumped through the other outlet.

7 Claims, 3 Drawing Figures PATENTED 5 "97 SHEET 2 [IF 2 FIGS 1 PUMP WITH SELF-CLEANING LINT FILTER RELATED APPLICATION The pump of the present invention is related to the pump disclosed in the copending application, Ser. No. l66,096, now US. Pat. No. 3,751,179, of W. A. Wasemann having a common assignee.

BACKGROUND OF THE INVENTION 1. Field of the Invention:

This invention relates to a centrifugal pump having a pumping chamber defined by a casing providing one inlet and two outlets with the pumped fluid being directed through either one or the other of the outlets depending upon the direction of rotation of the pump impeller. More particularly, the present invention is directed to a pump of the above nature including a filter interposed within the pumping chamber between the inlet and one of the outlets for filtering water discharged through that one outlet, with the filter being cleaned by a flushing action when the impeller is reversed to pump the water through the other outlet.

2. Description of the Prior Art:

In that the pump of the present invention is primarily utilized in the environment of laundry apparatus, such as an automatic washing machine, the prior art associated with this environment will be discussed.

It is well known to continuously circulate the wash water during the agitation or wash portion of the timed cycle of an automatic washing machine to provide an opportunity to pass the wash fluid through a filtering mechanism to trap the suspended lint particles and the like which, if not filtered, tend to be caught in the clothes being laundered as the wash water flows through them. One such apparatus for filtering the circulating water is shown in US. Pat. No. 2,555,725 which shows a pump attached to the water-containing tub of the washing machine. The pump includes two outlets with valve means and associated valve control means to determine the flow path the pumped fluid has between a recirculating line (the line through which the water is continuously circulated) or a drain line. Interposed between the pump and the valve in the circulating line is a self-cleaning filtering mechanism which is placed in a filtering position in this line by automatic control means. Through the use of this pump and associated filter structure, as the wash fluid is being pumped through the recirculating line, the control means maintains the filter in the path of the fluid; however, when the timer control has advanced through the wash portion of the cycle to a drain and pump-out portion, the filtering means will automatically move to another position whereupon it is subjected to a flushing action by the draining fluid and thereby cleaned.

As the laundry appliance field is highly competitive the above-described pump and filtering mechanism requiring valves and automatic actuating mechanisms including solenoids, was prohibitively expensive and therefore the most prevalent type of pumping and filtering means comprises a reversible centrifugal pump which pumps to either a recirculating line or a drain line depending upon the direction of rotation of the impeller, with the recirculating line discharging above the normal water level in the clothes containing tub so that a manually accessible filter could be interposed between the recirculating line and the water. This structure eliminated the expensive valve and valve control means and also permitted the structure defining the filtering mechanism to serve as a receptacle for washing additives which were than added to the wash water by the action of the recirculating water as it passed through the filtering structure.

The above arrangement was generally accepted even though it had obvious shortcomings, not the least of which was that the water falling from the recirculating discharge tended to splash on the filtering pan and carry with it lint particles previously trapped by the filter. Further, the filter required attention in that it had to be regularly manually cleaned. And, lastly, the impact of the recirculating fluid on the filtering pan tended to aerate the water often causing an oversudsing problem.

SUMMARY OF THE INVENTION The invention discloses a bi-directional single impeller centrifugal pump having a filter screen permanently disposed within the pump housing in position to filter the water flowing through the outlet connected with the recirculation line and flushed by the water flowing to the outlet associated with the drain line so that the lint particles trapped by the filter within the pump housing are subsequently carried to drain whenever the pump is placed in that mode of operation. Such pump and filter mechanism, in addition to providing a selfcleaning filter, eliminates the necessity for valves and valve control mechanisms to determine the direction of the pumped fluid and further permits the option of directing the recirculating line to discharge into a washing machine below the normal water level within the machine thereby eliminating splashing and sudsing.

DRAWING DESCRIPTION FIG. 1 is a cross-sectional elevation view of the pump of the present invention;

FIG. 2 is a plan view of the lower housing member including the impeller and filtering screen; and,

FIG. 3 is an elevation view of the pump in a washing machine.

DESCRIPTION OF THE PREFERRED EMBODIMENT The preferred structure of the centrifugal pump of the present invention will be described with reference to both FIGS. 1 and 2. As therein shown, the pump 10 has a housing 12 generally formed by fastening together two separate components, namely a bottom member 14 and a top member 16. Each member is preferably molded from a plastic such as polypropylene.

The bottom member 14 includes a generally planar bottom wall 18 and an upstanding peripheral side wall 20 with the juncture between the side wall and the bottom wall radiused so as to provide a generally smooth contour. The side wall 20 terminates in a radially outwardly projecting flange 22 having apertures 24 therein through which connecting bolts 26 are received. The bottom wall 18 also centrally defines an aperture 28 having a stepped wall configuration so as to properly receive a seal 30 through which the rotating shaft 32 of a reversible motor 34 projects into the pump housing 12. Similarly, flange 22 has a stepped configuration such as at 36 for receiving an annular O-ring 38 generally around the inner periphery of flange 22.

The top member 16 includes a generally planar top wall 40 in opposed facing relation with bottom wall 18, with the outermost periphery of top wall 40 radiused as at 42 to provide a generally smooth contoured transition between the horizontal top wall and the vertical side wall 20 of the bottom member 14. The radially outermost portion of the top member 16 defines a flange 44 in opposed facing relation to flange 22 of the bottom member and has apertures 46 for alignment with apertures 28 of the bottom member through which the mounting bolts 26 are received. It is seen that in the assembled position shown in FIG. 1, the face-to-face engagement of the cooperating flange members compresses the O-ring 38 to provide a generaly water-tight seal around the periphery of the housing 12.

The central portion of top wall 40 defines a generally cylindrical chamber defined by an upstanding generally vertical wall 48 covered by a contoured dome member 50 and provides a configuration for the housing to internally accommodate structure attaching the impeller to the drive shaft 32 of the motor 34 as will be subsequently described.

The vertical wall 48 defines an opening 52 therein which is bounded by an outwardly projecting nipple member 54 providing an inlet to the pumping chamber 56 which can generally be defined as the internal space formed by the opposing top wall 14 and bottom wall 18 and peripheral side wall 20.

An impeller 58 is disposed within the housing 12 in driving engagement with shaft 32 of a reversible motor 34. The impeller 58 includes a central hub portion 60 having a sleeve member 62 which telescopically receives the shaft 32 therein. The upper end of the sleeve contains an aperture in alignment with a threaded aperture in the shaft for receiving a bolt member 66. Sealing means such as a top disk 69 and an O-ring 70 are interposed between the headed bolt 66 and the sleeve to provide a sealing engagement when the bolt is tightened to secure the impeller on shaft 32. The lower portion of the hub 60 has a generally truncated conical form to conform to the contour of the lower bottom wall 18 and seal 30 and itself encloses a mating sealing means 72 in facing engagement with the seal 30 of the bottom member 14.

The impeller 58 extends radially outwardly from the hub member forming a generally planar bottom wall 74, the bottom face of which is in close facing relationship with the bottom wall 18 of the bottom member 14. The upper face of the impellers bottom wall 74 supports a plurality of impeller blades 76 which have an arcuate configuration (see FIG. 2) to provide a pumping capability in either direction of rotation of the impeller; however, with the pumping capacity of the blade in one direction being substantially more efficient than the pumping capacity of the impeller blade in the opposite direction.

Referring now to FIG. 2, it is seen that the side wall 20 of the bottom member 14 defines outlet apertures 78 and 80 which are bounded by integrally molded outwardly extending nipple portions 82 and 84 respectively. Aperture 78 is generally the larger of the two outlets and its associated nipple portion 82 extends generally tangentially from the side wall 20. Additionally, a short projection or dam means 86 extend inwardly from the side wall 20 generally adjacent the aperture 78 on the side opposite the tangential wall of the nipple portion 82 .and in parallel facing relation thereto.

Outlet aperture 80 and its associated nipple portion 84 extend generally parallel to outlet aperture 78 and nipple 82 however in a non-tangential position with respect to the side wall 20. Aperture 80 is also associated with a dam member 88 extending inwardly from the side wall 20 on the side of the aperture closest to the dam 86 associated with outlet aperture 78 so that the two described dam members are interposed within the pumping chamber between the two outlets 78 and 80. It is to be noted that the dam members extend from the bottom wall upwardly to a height so as to abutt the top wall 40, and thus are notched as at 86a and 88a so as to permit them to receive the top wall radius 42.

The pump as described up to this point is generally the same as the pump in the previously identified copending related application; however, the pump 10 of the present invention further includes filter means 90 disposed within the pump chamber 56 to generally partition the pump chamber into two annular chambers 92 and 94 as separated by the filter means 90.

Referring to FIG. 1, the filter means 90 comprises a generally fine mesh screen member 96, preferably molded of plastic, having the general configuration of an arcuate strip of constant height sufficient to extend from the bottom wall 18 to the top wall 40 and properly positioned within the pumping chamber by being received within an arcuate notch 98 formed in the bottom wall and a similar opposing arcuate notch 100 formed in the top wall. Further, the screen is positioned immediately in front of outlet aperture 80 with one end abutting darn member 88 which contains a notch 102 for properly seating the filter in this position. The opposite end of the screen member is outwardly formed as at 104 so as to extend toward the side wall 20 and it likewise is properly seated in position by being received within a notch 106 formed therein.

It is thus seen that with the top member 16 and bottom member 14 secured together the fluid, entering the inlet 52, must first pass through some portion of the filter 90 before it can be discharged through outlet aperture 80 and nipple 84, whereas, the fluid is free to exit through the other outlet 78 without passing through the filter 90.

In the pump 10, as described, when the impeller is rotated by the motor in a counterclockwise direction, as

viewed in FIG. 2, fluid entering the inlet 52 is discharged throughoutlet aperture 78 at a relatively large volume whereas, when the impeller is reversed so as to be rotated in the clockwise direction the pumped fluid is discharged from the pumping chamber 56 through outlet aperture 80 at a substantially reduced volume. Thus, as shown in FIG. 3, in the normal application, the inlet opening is connected to the outer tub 108 of an automatic washing machine 110 through an appropriate hose 112 with the outlet aperture 78 and nipple 82 connected to a drain hose 114 and outlet aperture 80 and nipple 84 connected to a recirculating line 116. Therefore, with the washing machine performing a washing or agitating function, the impeller 58 is rotated in a clockwise direction so as to continuously recirculate the water. In this mode of operation the lint containing wash water enters the pumping chamber through the inlet opening 52 and in flowing through the filter 90 so as to be discharged through the recirculating aperture 80 the lint is retained on the screen member 96 or in the chamber 92 formed between the impeller and the screen member 96. When the impeller is reversed at the end of the agitation cycle to pump the wash water to drain, the lint collected within chamber 92 is flushed by the incoming water so as to exit chamber 92 through the drain outlet aperture 78 thereby cleaning all the collected lint from the screen 96 and the chamber 92.

It is noted in FIG. 2 that the screen member 96 extends annularly approximately two-thirds of the way around the pump chamber, thereby providing more than sufficient cross-sectional area to accommodate the relatively low volumetric flow rate discharging from the recirculating outlet 80 without causing any substantial velocity gradient across the filtering member that might accompany a filtering area of reduced size. As a matter of fact, in a transparent working model of the above-described pump, it was noted that the lint collected in chamber 92 did not exhibit any definite tendency to plaster itself against the screen 96 and in fact the lint particles remained in a generally suspended fluidized condition being continuously stirred by the turbulence of the fluid in the chamber 92 such that when the impeller was reversed to pump to drain, the lint collected in chamber 92 was immediately flushed through the drain outlet clearing the pumping chamber for subsequent operation. However, it has been found that a filter screen of a cross-sectional area only equal to the cross-sectional area of the recirculating outlet under the same circumstances became immediately clogged with lint and prevented the flow through the recirculating outlet. As the amount of lint developed under actual washing conditions depends upon the type of fabrics being laundered and, as an oversized screen or filtering member such as disclosed does not effect the pumping characteristics of this pump, it is better to provide a large filtering area, such as one having the length described so that even when exposed to extreme lint producing washing conditions it will permit flow. The choice of an oversized screen area is not meant to imply that a filter of lesser area will not operate satisfactorily under most conditions; however, for the purpose of the present pump, in that the filter is generally inaccessible once the pump has been mounted on the machine, it was felt safer to oversize than undersize the area of the filter.

Referring again to FIG. 3, it is seen that a pump of the above construction having a filter within the body of the pump permits the option of directing the recirculating filtered water to re-enter the tub either above the water level to be used to flush wash additives from a dispenser as is presently well known in the art or below the water level (shown in phantom) to eliminate the aeration of the water and its attendant sudsing.

What is claimed is:

1. A reversible centrifugal pump comprising a housing providing a pump chamber bounded by the intrnal wall structure of the housing and including a top wall defining inlet means for receiving fluid to be pumped, a peripheral side wall defining first and second outlet means for directing the discharge of the pumped fluid and a bottom wall; a rotatable impeller enclosed within said chamber and coupled to drive means for rotation in either direction with said fluid being received for discharge at said first outlet means when said impeller is rotated in one direction and at said second outlet means when said impeller is rotated in the opposite direction; and means for filtering the fluid received at said first outlet means comprising a strip of foraminous material stationarily mounted within said pump chamber and defining a peripheral edge contiguous with said internal wall structure, and disposed between said inlet means and said first outlet means and between said first outlet means and said second outlet means so that said inlet means and said second outlet means are in flow communication through said chamber free of said filtering means and said inlet means and said first outlet means are in flow communication only through said filtering means whereby,

rotation of said impeller in said one direction to primarily discharge fluid through said first outlet means, causes said fluid to pass through said filtering means leaving particles removed by said means within the pump chamber and subsequent rotation of said impeller in the opposite direction to primarily discharge fluid through said second outlet means causes said particles previously retained within the pump chamber by said filtering means to be carried with said fluid for discharge therefrom.

2. Pump structure according to claim 1 wherein said foraminous strip has an arcuate configuration as viewed in a plane perpendicular to the axis of said impeller, for effectively partitioning said pump chamber into two annular chambers, with said first outlet means opening into one of said annular chambers and said second outlet means opening into the remaining annular chamber.

3. Pump structure according to claim 2 wherein said wall structure defines indexing means cooperating with said peripheral edge of said foraminous strip to properly position said strip within said housing.

4. Pump structure according to claim 3 wherein said indexing means includes notches in said wall structure for receiving said peripheral edge of said foraminous strip.

5. Pump structure according to claim 4 wherein said foraminous strip extends on the order of 2/3 of the distance around said pump chamber.

6. Pump structure according to claim 1 wherein the rate of fluid discharged through said first outlet means is substantially less than through said second outlet means.

7. Pump structure according to claim 6 wherein said foraminous strip extends generally concentric with said side wall to partition said chamber into two annular chambers with said first outlet means opening into one chamber and said second outlet means opening into the other chamber, said filtered particles being retained in said second chamber when said impeller is rotated in said one direction and flushed from said second chamber by fluid entering said second chamber from both said inlet means and said first chamber when said impeller is rotated in said opposite direction.

Patent Citations
Cited PatentFiling datePublication dateApplicantTitle
US1675200 *Apr 2, 1927Jun 26, 1928Smith Walter TPump
US3136254 *Jun 5, 1961Jun 9, 1964Blackstone CorpBi-directional pump
Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US4652368 *Jun 5, 1986Mar 24, 1987N/S CorporationWater filtration system
US4923366 *Feb 1, 1989May 8, 1990General Electric CompanyReversible turbine pump
US6418943Jun 4, 1999Jul 16, 2002Whirlpool CorporationWash liquid circulation system for a dishwasher
US7882715 *Feb 8, 2011Lg Electronics Inc.Method for cleaning foreign materials filtering apparatus
US7914263 *May 14, 2007Mar 29, 2011Vladimir BergerEjector-type rotary device
US7926310Apr 19, 2011Lg Electronics Inc.Foreign materials filtering apparatus and washing machine having the same
US8020413Sep 20, 2011Lg Electronics Inc.Foreign materials filtering apparatus and washing machine having the same
US8033144Oct 11, 2011Lg Electronics Inc.Foreign materials filtering apparatus and washing machine having the same
US8037721Oct 18, 2011Lg Electronics Inc.Foreign materials filtering apparatus and washing machine having the same
US8097155Jan 17, 2012Ennis G ThomasAbove ground water clarifier
US20080216518 *Mar 4, 2008Sep 11, 2008Yoo Sang-HeeForeign materials filtering apparatus and washing machine having the same
US20080216519 *Mar 4, 2008Sep 11, 2008Yoo Sang-HeeForeign materials filtering apparatus and washing machine having the same
US20080217243 *Mar 4, 2008Sep 11, 2008Yoo Sang-HeeMethod for cleaning foreign materials filtering apparatus
US20080286121 *May 14, 2007Nov 20, 2008Vladimir BergerEjector-type rotary device
US20100326899 *Sep 3, 2009Dec 30, 2010Ennis G ThomasAbove ground water clarifier
US20120152866 *Jun 21, 2012Stiles Jr Robert WModular Pump and Filter System and Method
Classifications
U.S. Classification210/167.1, 415/911, 415/121.2, 210/409, 415/169.1
International ClassificationD06F39/08, F04D29/42, F04D29/70, A47L15/42, B01D35/26
Cooperative ClassificationD06F39/085, F04D29/708, F04D29/426, B01D35/26, Y10S415/911
European ClassificationB01D35/26, D06F39/08D2, F04D29/70P, F04D29/42P