US1975274A - Centrifugal pump impeller - Google Patents

Centrifugal pump impeller Download PDF

Info

Publication number
US1975274A
US1975274A US629142A US62914232A US1975274A US 1975274 A US1975274 A US 1975274A US 629142 A US629142 A US 629142A US 62914232 A US62914232 A US 62914232A US 1975274 A US1975274 A US 1975274A
Authority
US
United States
Prior art keywords
impeller
periphery
ports
suction
pump
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US629142A
Inventor
Hollander Aladar
Walter L Forward
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Byron Jackson Co
Original Assignee
Byron Jackson Co
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Byron Jackson Co filed Critical Byron Jackson Co
Priority to US629142A priority Critical patent/US1975274A/en
Application granted granted Critical
Publication of US1975274A publication Critical patent/US1975274A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F04POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
    • F04DNON-POSITIVE-DISPLACEMENT PUMPS
    • F04D29/00Details, component parts, or accessories
    • F04D29/18Rotors
    • F04D29/22Rotors specially for centrifugal pumps
    • F04D29/2205Conventional flow pattern
    • F04D29/2211More than one set of flow passages

Definitions

  • Figure 1 illustrates a cross-sectional view er the pump impeller taken in a plane at right angles to the impeller shaft;
  • Figure 2 illustrates a cross-sectional view of Figure 1, taken substantiallyin the plane of line II--II, and also illustrates a fragmental sectional view of the pump casing.
  • the pump structure mayinclude a conventional double-inlet pump casing or volute 1 provided with wearing rings 2 and 3.
  • the pump impeller 7 is of the double-suction type and may be provided with the usual wearing rings 4 and 5 which cooperate with the rings 2 and 3 to act as running seals to reduce leakage from the pressure side or volute of the pump into the inlet eyes-thereof.
  • the impeller may' be suitably mounted upon the usual pump shaft 6, and may be "of the doublesuction type having opposed suction eyes 8 and 9. Double-suction impellers are inherently balanced against axial thrust, as is well known.
  • each of the suction eyes 8 and 9 commiinicates with a pair of discharge ports 10, 11 and 12, 13, these ports being defined by the vanes 15, 16 and 17, 18,
  • each vane is in advance of the outer edge '23 (in the direction of rotation), so that there is a smooth and rounded shoulder 24 which slopes outwardly away from the axis of the impeller. This gives the suction eyea somewhat funnel-shaped entrance, with the small end thereof toward the inner part of the impeller.
  • Each pair of discharge ports discharges on substantially one-half of the periphery of the impeller, so that with the two pairs'of ports disposed at right angles to each other the fluid is discharged from substantially the entire periphery of the impeller. This is important since impellers which do not discharge from substantially the entire periphery are subject to a pulsating discharge.
  • Non-clogging pumps have been built heretofore having single-suction (unbalanced) impellers and having only two discharge ports.
  • Double-suction impellers of the clear-water type heretofore constructed are provided with fluid'passages, which passages at their discharge ends may be only one-half the width of the periphery of the impeller, and are not intertwined.
  • the fluid passages are intertwined, thus permitting the discharge ends of the fluid passages to be nearly equal to the full width of the periphery of the impeller. Consequently the solids which can pass through the passages in our impeller may be twice as large as those which can pass through an ordinary double-suction impeller of the clear-water type. This is most important in the handling of sewage.
  • the vanes form the separating walls between the ports developed from the opposed inlet eyes of the impeller. Furthermore, it will be seen that in the four-port impeller,( Figure 2), the vanes 15 and 16 are of substantially constant thickness for practically their entire length, serving on their convex sides as the higher-pressure faces or surfaces of the ports entering from one inlet eye, and serving on their concave sides as the lower-pressure faces or surfaces of the ports entering from the opposite inlet eye.
  • impellers While we have shown the impellers as being provided with shrouds 25 and 26 ( Figure 2), it is to be understood that the impeller may be of the open type, in which event the shrouds would be stationary parts in the pump casing.
  • a centrifugal pump impeller, a pair of opposed suction inlet eyes, and four intertwining hollow arcuate vanes arranged to define four fluid channels forcommunicating the periphery of the impeller alternately with one and then the other of said inlet eyes, and each of said vanes having a well rounded terminal section adjacent its respective inlet eye from which section the convex surface of the vane develops radially traversing substantially a quarter turn of the impeller before arriving at the periphery thereof, while the concave surface of the vane develops radially from said terminal section traversing substantially a half turn of the impeller before arriving at the periphery thereof.
  • a centrifugal pump impeller In a centrifugal pump impeller, a pair of opposed suction inlet eyes, and four intertwining hollow arcuate vanes arranged to define four fluid channels of substantially uniform cross sectional area throughout their entire length for communicating the periphery of the impeller alternately with one and then the other of said inlet eyes, and each of said vanes having a well rounded terminal section adjacent its respective inlet eye from which section the convex surface of the vane develops radially to the impeller periphery while the concave surface of said vane develops radially from said terminal section to arrive at the impeller periphery substantially a quarter turn in advance of the peripheral engaging point of the convex surface.
  • a centrifugal pump impeller In a centrifugal pump impeller, a pair of opposed suction inlet eyes, and four intertwining hollow arcuate vanes arranged to define four fluid channels for communicating the periphery of the impeller alternately with one and then the other of said inlet eyes, and each of said vanes having Mill 5 the impeller before arriving at the periphery thereof while the concave surface of the vane twists from an outwardly directed taper to an axially parallel surface as it develops radially from the outwardly tapered terminal section traversing substantially a half turn of the impeller before arriving at the periphery thereof.
  • a centrifugal pump impeller In a centrifugal pump impeller, a pair of opposed suction inlet eyes, and four intertwining hollow arcuate vanes arranged to define four fluid channels for communicating the periphery of the impeller alternately with one and then the other of said inlet eyes, and each of saidvanes having a well rounded terminal section adjacent its respective inlet eye from which section the convex surface of the, vane develops radially to the impeller periphery while the concave surface of the vane develops radially from said terminal section to arrive at the impeller periphery substantially a quarter turn in advance of the peripheral engaging point of the convex surface.
  • a centrifugal pump impeller a pair of opposed suction inlet eyes, and four intertwining hollow arcuate vanes. arranged to define four fluid channels for communicating the impeller periphery alternately with one and then the other of said inlet eyes, and each of said vanes having a well rounded terminal section adjacent its respective inlet eye from which section the convex surface of the vane develops radially to the impeller periphery while the concave surface of the vane develops radially from said terminal section to substantially overlap the terminal section of the diametrically opposite vane periphery altetely with ene and then the I other of said inlet eyes, and each of said ves iii) having a well rounded terminal section adjacent its respective inlet eye from which section the convex surface of the vane develops radially traversing substantially a quarter turn of the impeller before arriving at the periphery thereof while the concave surface of the vane develops radially from said terminal section traversing substantially a half
  • a centrifugal pump impeller a pair of opposed suction inlet eyes, and four intertwining hollow arcuate vanes arranged to define four fluid channels of substantially uniform depth throughout their entire length, for communicating the impeller periphery alternately with one and then the other of the said inlet eyes, andradially from said terminal section to arrive at the impeller periphery substantially a quarter turn in advance of the peripheral engaging point of the convex surface.
  • a centrifugal pump impeller a pair of opposed suction inlet eyes, and four intertwining hollow arcuate vanes arranged to define four fluid channels for communicating the impeller periphery alternately with one and then the other of said inlet eyes and each of said fluid channels communicating through substantially a quarter turn of the impeller periphery, and each of said vanes having a well rounded terminal section adjacent its respective inlet eye from which section the convex surface of the vane develops radially to-the impelier periphery while the concave surface of the vane develops radially from said terminal to arrive at the impeller periphery substantiaily a quarter turn in advance of the periphery engaging point of the convex surface.

Description

2, 1934- A. HOLLANDER E-i- AL 1,975,274
CENTRIFUGA L PUMP IMPELLER Filed Aug. 17, 1952 Patented o r. 2, 1934:
1,975,274 CENTRIFUGAL PUMP. IMPELLER A'l'adar Hollander and Walter L. Forward, Berkeley, Calif., assignors to Byron Jackson (30.,
Los Angeles, Calif., a corporation of Delaware Application August 17, 1932, Serial No. 629,142 8- Claims. (01. its-115) This invention relates to improvements in can trifugal pump impellers, and? particularly for useon those pumps which are employed for pump-- ing fluids 'of'the nature of sewage, containingpulpyor stringy material and relatively large solids. t I i It has been thecommon practice in pumps for handling sewageand the like to employ singlesuction impellers'provided with vanes having 10 well rounded forward ends and only one or two discharge ports which' form substantiallyan L or a T, so that-there are no sharp shoulders in the suction eye on which dbris might collect.-
These pumps do not easily clog, but their use has been limited to pumps of relatively small size or large size and slow'speed. v j
The disadvantages of the single-suction irnpeller having one and even two discharge ports results from the poor control of the water flowgo ing through the impeller and to the unbalanced hydraulic forces which limit the maximum head to which these pumps can be satisfactorily applied. Furthermore the necessity of full-width channels in a single-suction impeller makes itimpossible to; construct the fluid passages in proper proportions for best efficiency. 1
It is, therefore, an object of this invention to fully eliminate the above disadvantages by pro-'- viding an impeller of the doubleasuction type 3o. withfour ports.
As pumps of ordinary,-single-suction type increase in size, the -.p rob1em of the unbalanced hydraulic forces becomes one of great importance, especially when the pumps are to operate at relatively high speeds. It is, therefore, a further object of this invention to provide doublesuction impellers having four ports or fluid channels which impellers will be' substantial hydraulic balance whether the impellers are large 40 or small or whether they are to run at .relatively high orlowspeeds.
The advantages of our design are emphasized to a greater degree as the sizeof the pump is increased where the restriction of the passages due tionable'and where the elimination of any unbalanced hydraulic forces are' of greater importance for successful operation'. 2 i i 5 It is a further object of the present invention to provide a pump'having the non-clogging characteristics 'of the previous pumps but of 1 greater capacity-for a given size of'impeller and or greater efiiciency. i v it is a further object of the presentinvention' to provide a non-clogging pump which is substantially balanced against axial thrust.
It is-a further object of this invention to provide a non-clogging pump having a discharge passage substantially around the entire periphery of'the impeller so as to substantially eliminate the pulsating of the discharge.
It is a further object to'provide a pump impeller with a pair of diametrically opposed ports having an inlet entrance communicating with one side of the impeller and a 'pair of diametrically opposed ports spaced 90 from the other pair of ports having an inlet entrance communicating with the other'sideof the impeller.
It is a further object to provide an impeller having two pairs of discharge ports and each pair of discharge ports arranged to discharge from substantially one-half of theperiphery of the impeller, so that with the two pairs of ports disposed at right angles to each other they will discharge from substantially the entire periphery of the impeller.
Pump impellers which do not discharge from substantially the entire periphery thereof are subject to a pulsating discharge. It is, therefore, a further object of this invention to provide double-suction pump impellers with ports which do discharge from substantially the entire periphery thereof to eliminate the pulsating of the impeller discharge.
It is a further object to provide a pump construction which will be 'hydrostatically balanced, hon-clogging, nonpu1sating, and which may be built forrelatively high speeds in large sizes and which will have a large capacity and high efliciency.
It is a further object to provide a double-suction impeller having intertwining ports whereby the discharge passage of the ports, from the pe- 'riphery of the impeller, may be more than onehalf of the width of the entrance end of the ports,
whereby the solids which may pass through the ports in'our impeller may be twice as large as thdse which may pass through an ordinary dou- I ller of the lear-water t e. to the presence of the pump shaft is not ob;|ec- Me Suctmn lmpe C W Other, objects and advantages of the invention will become apparent as the nature of the same is more fully understood from the following description and accompanying drawing,
of the inventionis chosen principally for the purpose 'of exempliflcation and that variations therefrom in details of construction or arrangement of parts may accordingly be efiected and yet remain within the spirit and scope of the invention as the same is set forth in the appended claims.
In the drawing:
Figure 1 illustrates a cross-sectional view er the pump impeller taken in a plane at right angles to the impeller shaft;
Figure 2 illustrates a cross-sectional view of Figure 1, taken substantiallyin the plane of line II--II, and also illustrates a fragmental sectional view of the pump casing.
In the preferred form of'the invention, the pump structure mayinclude a conventional double-inlet pump casing or volute 1 provided with wearing rings 2 and 3. The pump impeller 7 is of the double-suction type and may be provided with the usual wearing rings 4 and 5 which cooperate with the rings 2 and 3 to act as running seals to reduce leakage from the pressure side or volute of the pump into the inlet eyes-thereof. The impeller may' be suitably mounted upon the usual pump shaft 6, and may be "of the doublesuction type having opposed suction eyes 8 and 9. Double-suction impellers are inherently balanced against axial thrust, as is well known.
Referring to Figure 2, it will be noted that each of the suction eyes 8 and 9 commiinicates with a pair of discharge ports 10, 11 and 12, 13, these ports being defined by the vanes 15, 16 and 17, 18,
respectively. The inner ends of the vanes are well rounded to prevent solids from sticking. The inner edge 22 of each vane is in advance of the outer edge '23 (in the direction of rotation), so that there is a smooth and rounded shoulder 24 which slopes outwardly away from the axis of the impeller. This gives the suction eyea somewhat funnel-shaped entrance, with the small end thereof toward the inner part of the impeller. Each pair of discharge ports discharges on substantially one-half of the periphery of the impeller, so that with the two pairs'of ports disposed at right angles to each other the fluid is discharged from substantially the entire periphery of the impeller. This is important since impellers which do not discharge from substantially the entire periphery are subject to a pulsating discharge. By our construction we have provided a balanced non-clogging, non-pulsating impeller discharging from substantially the entire periphery and which can be built for high speed or in large sizes having both large capacity and high efficiency.
Non-clogging pumps have been built heretofore having single-suction (unbalanced) impellers and having only two discharge ports. In
some cases these discharge ports have covered substantially the entire-periphery of the impeller, to limit pulsation of the discharge, but this could only be poorly accomplished with a two-port impeller because the forces acting on the water in the way of ports are materially different than the ones acting in the way 'of the vane, which is relatively close to the periphery. The double-suction four-port impellers discharging symmetrically from substantially the entire periphery eliminates this pulsation and also eliminates the axial thrust.
Double-suction impellers of the clear-water type heretofore constructed are provided with fluid'passages, which passages at their discharge ends may be only one-half the width of the periphery of the impeller, and are not intertwined. In the impeller of our invention, the fluid passages are intertwined, thus permitting the discharge ends of the fluid passages to be nearly equal to the full width of the periphery of the impeller. Consequently the solids which can pass through the passages in our impeller may be twice as large as those which can pass through an ordinary double-suction impeller of the clear-water type. This is most important in the handling of sewage.
It will be seen that in our double suction impeller the vanes form the separating walls between the ports developed from the opposed inlet eyes of the impeller. Furthermore, it will be seen that in the four-port impeller,(Figure 2), the vanes 15 and 16 are of substantially constant thickness for practically their entire length, serving on their convex sides as the higher-pressure faces or surfaces of the ports entering from one inlet eye, and serving on their concave sides as the lower-pressure faces or surfaces of the ports entering from the opposite inlet eye. Another way of expressing the same idea is to say that in the double-suction two-port impeller having four discharge portsat the periphery, there are four vanes, each having a highand a low-pressure side-the two vanes which serve as higher pressure surfaces for water entering from one inlet eye of the impeller also serve as lower:-:pressure surfaces for water entering from'the opposite inlet eye thereof.
While we have shown the impellers as being provided with shrouds 25 and 26 (Figure 2), it is to be understood that the impeller may be of the open type, in which event the shrouds would be stationary parts in the pump casing.
Having fully described the invention, it is to'be understood that it is not to be limited to the details shown herein, but the invention is of the full scope of the appended claims.
We claim:-
1. In a centrifugal pump, impeller, a pair of opposed suction inlet eyes, and four intertwining hollow arcuate vanes arranged to define four fluid channels forcommunicating the periphery of the impeller alternately with one and then the other of said inlet eyes, and each of said vanes having a well rounded terminal section adjacent its respective inlet eye from which section the convex surface of the vane develops radially traversing substantially a quarter turn of the impeller before arriving at the periphery thereof, while the concave surface of the vane develops radially from said terminal section traversing substantially a half turn of the impeller before arriving at the periphery thereof.
i 2. In a centrifugal pump impeller, a pair of opposed suction inlet eyes, and four intertwining hollow arcuate vanes arranged to define four fluid channels of substantially uniform cross sectional area throughout their entire length for communicating the periphery of the impeller alternately with one and then the other of said inlet eyes, and each of said vanes having a well rounded terminal section adjacent its respective inlet eye from which section the convex surface of the vane develops radially to the impeller periphery while the concave surface of said vane develops radially from said terminal section to arrive at the impeller periphery substantially a quarter turn in advance of the peripheral engaging point of the convex surface.
3. In a centrifugal pump impeller, a pair of opposed suction inlet eyes, and four intertwining hollow arcuate vanes arranged to define four fluid channels for communicating the periphery of the impeller alternately with one and then the other of said inlet eyes, and each of said vanes having Mill 5 the impeller before arriving at the periphery thereof while the concave surface of the vane twists from an outwardly directed taper to an axially parallel surface as it develops radially from the outwardly tapered terminal section traversing substantially a half turn of the impeller before arriving at the periphery thereof.
4. In a centrifugal pump impeller, a pair of opposed suction inlet eyes, and four intertwining hollow arcuate vanes arranged to define four fluid channels for communicating the periphery of the impeller alternately with one and then the other of said inlet eyes, and each of saidvanes having a well rounded terminal section adjacent its respective inlet eye from which section the convex surface of the, vane develops radially to the impeller periphery while the concave surface of the vane develops radially from said terminal section to arrive at the impeller periphery substantially a quarter turn in advance of the peripheral engaging point of the convex surface.
5. In a centrifugal pump impeller, a pair of opposed suction inlet eyes, and four intertwining hollow arcuate vanes. arranged to define four fluid channels for communicating the impeller periphery alternately with one and then the other of said inlet eyes, and each of said vanes having a well rounded terminal section adjacent its respective inlet eye from which section the convex surface of the vane develops radially to the impeller periphery while the concave surface of the vane develops radially from said terminal section to substantially overlap the terminal section of the diametrically opposite vane periphery altetely with ene and then the I other of said inlet eyes, and each of said ves iii) having a well rounded terminal section adjacent its respective inlet eye from which section the convex surface of the vane develops radially traversing substantially a quarter turn of the impeller before arriving at the periphery thereof while the concave surface of the vane develops radially from said terminal section traversing substantially a half turn of the impeller before arriving at the periphery thereof.
7. In a centrifugal pump impeller, a pair of opposed suction inlet eyes, and four intertwining hollow arcuate vanes arranged to define four fluid channels of substantially uniform depth throughout their entire length, for communicating the impeller periphery alternately with one and then the other of the said inlet eyes, andradially from said terminal section to arrive at the impeller periphery substantially a quarter turn in advance of the peripheral engaging point of the convex surface.
23. In a centrifugal pump impeller, a pair of opposed suction inlet eyes, and four intertwining hollow arcuate vanes arranged to define four fluid channels for communicating the impeller periphery alternately with one and then the other of said inlet eyes and each of said fluid channels communicating through substantially a quarter turn of the impeller periphery, and each of said vanes having a well rounded terminal section adjacent its respective inlet eye from which section the convex surface of the vane develops radially to-the impelier periphery while the concave surface of the vane develops radially from said terminal to arrive at the impeller periphery substantiaily a quarter turn in advance of the periphery engaging point of the convex surface.
ALADAR none. WALTER L. FORWARD.
US629142A 1932-08-17 1932-08-17 Centrifugal pump impeller Expired - Lifetime US1975274A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US629142A US1975274A (en) 1932-08-17 1932-08-17 Centrifugal pump impeller

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US629142A US1975274A (en) 1932-08-17 1932-08-17 Centrifugal pump impeller

Publications (1)

Publication Number Publication Date
US1975274A true US1975274A (en) 1934-10-02

Family

ID=24521761

Family Applications (1)

Application Number Title Priority Date Filing Date
US629142A Expired - Lifetime US1975274A (en) 1932-08-17 1932-08-17 Centrifugal pump impeller

Country Status (1)

Country Link
US (1) US1975274A (en)

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2646002A (en) * 1950-07-29 1953-07-21 Borg Warner Centrifugal pump
US2791183A (en) * 1952-02-09 1957-05-07 Skoglund & Olsson Ab Impeller for centrifugal pumps
US4239013A (en) * 1977-10-21 1980-12-16 Haynes Hendrick W Propelling means
CN103899573A (en) * 2014-03-17 2014-07-02 安徽华瑞塑业有限公司 Centrifugal pump impeller
US9377027B2 (en) 2011-08-11 2016-06-28 Itt Manufacturing Enterprises Llc. Vertical double-suction pump having beneficial axial thrust
EP2930367B1 (en) * 2013-07-05 2020-05-27 Ebara Corporation Pump blade for submerged pump and submerged pump having same

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2646002A (en) * 1950-07-29 1953-07-21 Borg Warner Centrifugal pump
US2791183A (en) * 1952-02-09 1957-05-07 Skoglund & Olsson Ab Impeller for centrifugal pumps
US4239013A (en) * 1977-10-21 1980-12-16 Haynes Hendrick W Propelling means
US9377027B2 (en) 2011-08-11 2016-06-28 Itt Manufacturing Enterprises Llc. Vertical double-suction pump having beneficial axial thrust
EP2930367B1 (en) * 2013-07-05 2020-05-27 Ebara Corporation Pump blade for submerged pump and submerged pump having same
CN103899573A (en) * 2014-03-17 2014-07-02 安徽华瑞塑业有限公司 Centrifugal pump impeller
CN103899573B (en) * 2014-03-17 2016-06-15 安徽华瑞塑业有限公司 A kind of centrifugal pump impeller

Similar Documents

Publication Publication Date Title
US2165808A (en) Pump rotor
GB1085418A (en) Centrifugal pumps
US1912452A (en) Balanced multistage centrifugal pump
US2195174A (en) Pump
US1975274A (en) Centrifugal pump impeller
US3324799A (en) Radial staging for reentry compressor
US3788764A (en) Multi-stage centrifugal pump with means for pulse cancellation
AU2018202578A1 (en) Volute casing for a centrifugal pump and centrifugal pump
US3013501A (en) Centrifugal impeller
US1871747A (en) Impeller for centrifugal pumps
US1979621A (en) Balanced turbulence pump
US1654907A (en) Centrifugal pump
GB574079A (en) A new or improved centrifugal pump
US4575312A (en) Impeller
US3588280A (en) Inducers for centrifugal pumps
US2028783A (en) Centrifugal pump
US1978277A (en) Multistage pump balancing means
RU2623634C1 (en) Axial force discharge method for multistage segmental pump
US1875419A (en) claypool
US1182439A (en) Centrifugal pump.
GB272713A (en) Improvements in centrifugal pumps
US2654322A (en) Pump
US2671404A (en) Turbine pump
US2300689A (en) Automatic priming pump and the like
US3438330A (en) Noise suppression means