This invention relates generally to centrifugal pumps, and, more particularly, to lubricating pump seals for centrifugal pumps, which seals act to reduce wear between the rotating and stationary surfaces of pumps that are used to pump a mixture of solids and carrier liquid, commonly known as slurry.
Centrifugal pumps employ centrifugal force to lift liquids from a lower to a higher level or to produce a pressure. Such pumps typically comprise an impeller consisting of a connecting hub with a number of vanes and shrouds, rotating in a volute collector or casing (See
The rotation of the impeller vanes results in a higher pressure in the volute collector than in the suction, which results in flow. This higher pressure has to be sealed against the lower pressure suction on one side and where the shaft (at a lower atmospheric pressure) on the other side enters the collector, to avoid leakage losses and loss of performance. In the case of the shaft, the most common sealing method is to utilize a stuffing box with rings of packing. On the front, or suction side, the most common method of sealing is to utilize a close radial clearance between the impeller and the casing and to employ radial seal rings. For pumps used to pump slurry, however, the sealing problem is more difficult. While radial seal rings are effective in clean water pumping applications, experience with slurry pumps has shown that the particles (solids) being pushed through the gap between the sealing surfaces are thrown off the rotating radial surface of the impeller seal ring, causing high wear to the wetted surfaces of the pump.
Wear occurs mostly as a result of particles impacting or sliding on the wetted surfaces. The amount of wear depends on the particle size, shape, specific gravity of the solids, and sharpness of the solids.
In order to reduce wear, some pumps employ a water flush to dilute and exclude solids, some utilize semi-axial gaps tapering inwardly at an angle, and some utilize clearing vanes protruding out of the front shroud of the impeller into the gap between the impeller and the suction liner, or combination of the above. Each of these, however, has either not satisfactorily solved the problem of wear, or has reduced wear at the expense of pump efficiency.
What is needed, then, is a pump seal that is simple, effective in reducing wear, and that does not impair the performance of the pump.
The present invention is directed to a radial seal for centrifugal pumps. Specifically, the sealing assembly is adaptable for use in a centrifugal pump of the type used for pumping an abrasive slurry where wear due to particulate matter is particularly problematic. The seal assembly may be installed in a pump having a sealing ring groove in the stationary pump casing and a means for supplying clean, pressurized flush water into the sealing ring groove. While the present invention may be installed on a variety of pump types, exemplary installation on a single-stage, single-suction centrifugal pump will be explained in detail herein.
One embodiment includes a radial seal that is positioned within the sealing ring groove of the stationary pump casing of a centrifugal pump. The radial seal is dimensioned to be smaller than the groove so that it may move freely within the groove. The radial (circular) seal has a generally rectangular cross section and is formed of a wear-resistant malleable iron, elastomer, or ceramic material.
The radial seal comprises: a flushing water inlet, or outer, end; a sealing, or inner, end; and opposed sides. The radial seal is dimensioned to fit within the sealing ring groove in the pump casing. Multiple openings extend from the water inlet end to the sealing end of the seal for the passage of pressurized water therethrough.
When pressurized water is applied to the water inlet end of the seal, the seal will move to a self-compensating, balanced position between the pump casing and the impeller of the pump. The inventors have found that this balanced condition is approximately defined by the following equation:
PI*AI=PMEAN*AS.
Hydrostatically, as the seal approaches the surface of the impeller, backpressure between the impeller and the radial seal increases. The sealing end of the radial seal also includes a lip portion that extends outwardly so that the area of the sealing end is larger than the area of the water inlet end. This relationship between seal areas and pressures helps to balances the seal so that the seal does not physically contact the impeller.
In another embodiment, the sealing end of the seal of the present invention has a centrally-formed recessed region. Desirably, it creates a “shower head”, or conical, distribution of flush water. Formed in this fashion, the flush water is caused to spread out from the perforations onto an even larger predetermined surface area. When the flush water enters the recessed portion, pressure in the recessed portion builds, again balancing the hydrostatic force between the seal and the impeller surface, so that the seal moves outward, but never actually contacts the impeller.
These and other aspects of the present invention will become apparent to those skilled in the art after a reading of the following description of the preferred embodiments when considered in conjunction with the drawings. It should be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention as claimed.
Certain exemplary embodiments of the present invention are described below and illustrated in the attached Figures. The embodiments described are only for purposes of illustrating the present invention and should not be interpreted as limiting the scope of the invention, which, of course, is limited only by the claims below. Other embodiments of the invention, and certain modifications and improvements of the described embodiments, will occur to those skilled in the art, and all such alternate embodiments, modifications and improvements are within the scope of the present invention.
Referring now to
Pump 10 comprises a stationary casing, or volute, 12 that houses the single impeller 22. As is conventional for centrifugal pumps, impeller 22 is rotated by a shaft (not shown) that is coupled to a motive power source (not shown) such as an electric motor. Aligned axially with impeller 22 is the pump suction inlet 13. Suction inlet 13 is the point of entry for slurry being drawn into the impeller 22. Suction inlet 13 is typically coupled to a suction source via piping (not shown) that mates with a suction flange surrounding suction inlet 13. Slurry enters the suction inlet and moves inwardly through the length of the suction branch to the eye 22a of the impeller 22. The counterclockwise rotation of the impeller 22 pushes the slurry on the back of the impeller vanes 22b, imparting radial motion and pressure to the slurry. The slurry is forced outward through a conventional casing discharge branch (not shown) that is typically connected to discharge piping. Depending upon the size of the pump and the rotational velocity of the impeller 22, hundreds or thousands of gallons per minute of slurry are drawn inwardly through the suction inlet 13 and discharged outwardly under pressure.
As shown in
Groove 12b is preferably dimensioned with a depth that is greater than its width. Thus, the groove stably maintains the radial seal 30 in position, without the possibility of any substantial distortion or rotation. At least one water inlet connection 12c is provided so that a supply of pressurized clean water may be injected into the groove 12b during pump operation or wet layup. As used herein, “clean water” refers to water that is substantially free of solid matter.
The complete radial seal 30 is best shown in
As noted, the clearance between seal 30 and the groove 12b is such as to allow easy movement and to minimize leakage in the gap. A version of this can have “0” rings in additional grooves (not shown) or other type of side seals to improve sealing. As shown in
Turning now to
As shown in
As shown in
The inventors have now found, however, that a self-compensating balanced position between the pump casing and the pump impeller is ensured when the sealing end area, AS is greater than the water inlet area, AI. The extended lip portion 31a may extend inwardly toward the suction inlet 13, as illustrated in
In further detail, the self compensating feature of the seal, including water being injected through the holes of the seal, is illustrated by the following equations. The variables of the equations are further defined in
The corresponding mean pressure within the impeller nose gap has been determined as:
Where:
The self-compensating, balanced position of the radial seal is the relative radial seal position that is defined by the following equation:
PC*AI=PMEAN*AS.
Where:
Typically, when pressurized flush water is applied, PI>PMEAN; therefore, the self-compensating balanced position is obtained by compensating with a sealing area, AS, that is greater than the water inlet area, AI. When PI*AS=PMEAN*AS, the force acting on the radial seal is zero.
If PI*AI>PMEAN*AS, the radial seal will be pushed forward and the gap between the pump casing and the impeller nose, as well as the leakage flow rate, will then decrease. The radial seal ring will stop moving forward, when again PI*AI>PMEAN*AS.
The following example, with assumed values, illustrates how the self-compensating, balanced radial seal operates:
As those skill in the art will appreciate, there are unlimited combinations of pressures, PG, PC and areas, AI, AS that may be employed in constructing a radial seal according to the present invention.
In operation, pressurized water is injected into groove 12b through inlet 12c. Desirably, the pressure of the water is between about 1 and 20 pounds per square inch greater than the discharge pressure of the pump. The water passes through openings 30c, 50c and outward through perforations 30f, 50f. With the sizes of the perforations 30f, 50f restricted, the pressure of the sealing water forces the seal 30, 50 laterally outward and into gap 14, defined by the inner surface 12h of casing 12a and impeller nose surface 22a of impeller 22. As seal 30, 50 protrudes outwardly toward surface 22a, the seal water forced through the perforations 30f, 50f creates a backpressure between seal surface 30b, 50b and impeller nose surface 22a. The backpressure between the opposed surfaces keeps the seal 30, 50 from actually contacting impeller nose surface 22a. Thus, the pressurized seal arrangement of the present invention creates a self-compensating clearance between the opposed surfaces 30b, 50b and 22a. As surfaces 30b, 50b are not in contact, there is no frictional seal wear on either the casing 12 or the impeller 22 caused by solid contact. Further, the pressurized water provides a lubricating and cleaning medium for the wetted surfaces of the centrifugal slurry pump 10.
Although the present invention has been described with preferred embodiments, it is to be understood that modifications and variations may be utilized without departing from the spirit and scope of the invention, as those skilled in the art will readily understand. Such modifications and variations are considered to be within the purview and scope of the appended claims and their equivalents.
This non-provisional application claims the benefit of Provisional application No. 60/526,270, filed Dec. 3, 2003, now pending, the content of which is incorporated herein in its entirety.
Number | Name | Date | Kind |
---|---|---|---|
2109679 | Neveling, Sr. | Mar 1938 | A |
2679412 | Whitfield | May 1954 | A |
2736265 | Higgins | Feb 1956 | A |
2925290 | Greenwald | Feb 1960 | A |
3272572 | Lloyd | Sep 1966 | A |
3516757 | Baumann | Jun 1970 | A |
4126360 | Miller et al. | Nov 1978 | A |
4913619 | Haentjens et al. | Apr 1990 | A |
5921748 | Frater | Jul 1999 | A |
5971704 | Blattmann | Oct 1999 | A |
6739829 | Addie | May 2004 | B2 |
Number | Date | Country |
---|---|---|
45-33481 | Oct 1970 | JP |
Number | Date | Country | |
---|---|---|---|
20050123395 A1 | Jun 2005 | US |
Number | Date | Country | |
---|---|---|---|
60526270 | Dec 2003 | US |