Title of Invention	"APPARATUS FOR LUBRICATING BEARING"
Abstract	A system for lubricating bearings on a vertical rotatable shaft within a bearing housing, is comprised of an annular lower lubricant sump at a lower portion of the bearing housing; an annular upper lubricant reservoir at an upper portion of the bearing housing; and a conduit providing fluid communication between the lower lubricant sump and the upper lubricant reservoir. Provision is made for metering a flow of lubricant from the upper lubricant reservoir into upper bearings. The lubricant is pumped from the lower lubricant sump, through the conduit, to the upper lubricant reservoir at a rate exceeding the rate of metered flow into the upper bearings. A constant head of lubricant above the metering orifice is provided in the upper lubricant reservoir, as well as an outlet for shunting excess lubricant back to the lower lubricant sump.

Title of Invention

"APPARATUS FOR LUBRICATING BEARING"

Abstract

A system for lubricating bearings on a vertical rotatable shaft within a bearing housing, is comprised of an annular lower lubricant sump at a lower portion of the bearing housing; an annular upper lubricant reservoir at an upper portion of the bearing housing; and a conduit providing fluid communication between the lower lubricant sump and the upper lubricant reservoir. Provision is made for metering a flow of lubricant from the upper lubricant reservoir into upper bearings. The lubricant is pumped from the lower lubricant sump, through the conduit, to the upper lubricant reservoir at a rate exceeding the rate of metered flow into the upper bearings. A constant head of lubricant above the metering orifice is provided in the upper lubricant reservoir, as well as an outlet for shunting excess lubricant back to the lower lubricant sump.

Full Text	The present invention relates to an apparates for lubricating bearing This invention relates generally to lubrication of: bearings on. a rotatable • shaft and more particularly to supplying a lubricating fluid to bearings, within a vertical wet-sump bearing housing, at a constant flow rate which, is independent of operating spsed. Present bearing lubrication systems for vertical wet. sump bearing housings are typically designed to supply lubricant at a flow rate specific to a design operating speed. They pump lubricant from a sump at the bottom of the housing to bearings at the top of the housing. The lubricant flows down through the bearings and returns to the sump. The amount and flow rate of lubricant supplied to the bearings is limited by the operating speed of the pump mechanism, the viscosity of. the lubricant, and the size of: the passages through which the lubricant is pumped to the bearings. While such systems, assuming constant viscosity, perform adequately at the design speed they may become ineffective at low operating speed, or they nay provide excess lubricant at high operating speed, aa would, be encountered with a variable apeed drive input. Thus, at low speed lubrication, may ba inadequate, while at high apeed excessive lubricant flow may cause over pressure which leads to seal failure and leakage of lubricant to the surroundings. In addition, lubricants are viscous liquids which, are subject to viscosity changes which are inversely related to temperature variations. Thus temperature increases cause viscosity decreases, and temperature decreases causa viscosity increases. Even when operating at design speed, the lubricant becomaa hot due to mechanical heat generation and loses viscosity. This causes decreased pumping action and results in inadequate lubrication of the /bearings. Such inadequacies result in costly damage to equipment and the environment. GB-A-444 496 discloses an apparatus for lubricating bearings in accordance with tlie preamble of claim 1. According to one aspect of the present invention., thers is provided an, apparatus for lubricating bearings on. a vertical rotatable shaft within a bearing housing, comprising a lower lubricant sump at. a lower portion, of. said bearing housing; an upper lubricant reservoir at an upper portion of said bearing housing; a conduit providing fluid communication between said lower lubricant sump and said upper lubricant reservoir; means for metering a flow of lubricant from said upper lubricant reservoir into upper bearings; means for pumping lubricant from said lower lubricant sump, through aaid conduit, to said \ipper lubricant reservoir at a rate exceeding a rate of said matered flow into said upper bea.rings; and means in said upper lubricant reservoir, for maintaining a constant head of lubricant above said metering means and for shunting excess lubricant, back to aaid lower lubricant sump ; characterised by means for feeding a portion, of said excess lubricant to said lower bearings before said excess lubricant is returned to said lower lubricant sump. According to another aspect of the present invention, there is provided a pumping device comprising a cup-like rotatable member, with an axis that is, in use, vertical, and having longitudinally directed oppositely handed, helical grooves on inner and outer surfaces; a smooth-walled bore in a stationary member closely surrounding without contacting the outer surface of eaid cup-like rotatabl© member) a smooth-walled stationary cylindrical member closely surrounded without contact by the inner surface of said cup-like member; and a sump which contains fluid at a level sufficient to cover a lower portion of. said rotatable cup-like member, said smooth-walled bore, and said smooth-walled cylindrical member, such that rotation of said cup-like member causes the fluid to be pumped upwardly on one said surface and downwardly on the other said surface of tha cup-like member. For a better understanding of the invention, and to show how the same may be carried into effect, reference will now be made, by way of example, to the accompanying drawings, in which:- Fig1, 1 is a vertical schematic partially sectional view of a pump equipped with a vertical wet sump lubrication, system; Fig. 2 is a fragmentary bottom perspective view of the pumping device; and Fig. .3 is a fragmentary sectional elevation view of the lubricant metering and shunt features of an upper lubricant reservoir. All the main features can be seen by referring to Pig, 1; however, it is also helpful to refer to Figs. 2 and 3, as appropriate, to further appreciate details of pumping, metering and shunting provisions. In'Fig. 1, the invention is shown aa applied to a vertical pump unit 60. A bearing housing assembly 50 has upper bearings 14 and lower bearings 18 supporting a rotatable shafts which is mounted within a bearing housing 10. A lower annular lubricant sump 40 in a lower end cover 11 of the housing 10 and an upper annular lubricant reservoir 20 in an upper end cover 12 are connected by a conduit 35, which is preferably bored in the wall of the housing 10. A cup-like pumping or lifting device 30, which is fixed to the rotatatole shaft 5, pumps lubricant by means of at least one helical groove 33 in the outer surface thereof, which groove co-operates with the inner wall 31 of a bore through which the cup-like pimping device 30 extends downward into the lower lubricant sump 40. Note that there ia no contact between the cup-like pumping device 30 and the inner wall 31 of the bore. The groove 33 is sized" such that it pumps an excess quantity of lubricant to the upper bearings 14 at all operating speeds. These features are seen in Figs. 1 and 2 . The upper lubricant reservoir 20, seen in Figs. 1 and 3, has a, spillway or overflow barrier 26 which maintains a constant pressure head above a metering orifice 25. The metering orifice 25 is sized to provide full lubrication, as required by the upper bearings 14, at all operating speeds and viscosity ranges. The metering orifice 25 has its mouth located slightly above the bottom of the upper reservoir 20 to retain a small amount of lubricant in the reservoir 20 upon shut-down. This assures a minimal response time for supplying .lubricant to the upper bearings 14 when re-starting the unit after such shut-down. Any excess lubricant reaching upper reservoir 20 passes over the overflow barrier 26 and is shunted back to the lower sump 40 through shunt passage 19, This overflow and shunt feature allows the , pumping device to operate with no throttling or other constriction without regard to operating speed; because the full lubricant requirements are always met, and any excess lubricant is merely returned to the lower sump 40. A portion of the excess lubricant ia directed, by the bowl shaped lower surface of the housing 10, through the lower bearings 18 before draining to the lower sump 40, Lubricant which passes through, the upper bearings .1.4 falls onto a slinger ring 45 attached to the shaft 5 below the bearings 14. The slingar ring 45 throws the lubricant against the wall of the bearing housing 10 where it gives up heat collected by contacting various parts of the bearings and shaft 5. By design, lubricant which ia not actually lubricating the bearings is exposed as much as possible to cooler surfaces within the bearing housing 10. This helps to dissipate heat and to maintain a steady state operating temperature. The cup-like pumping device 30 also acts aa a heat sink to extract heat from the shaft 5 adjacent to the lower bearing 18. The intimate mixing contact between, the lubricant and the pumping device 30 assures maximum heat transfer to the lubricant, which then serves to carry the heat to the housing walls 10, 11, 12 and to thus dissipate it to the surroundings of the housing assembly 50. This feature is important especially if the shaft 5 ia exposed to an external heat source such as hot pumpage or hot air. Thus, under any operating conditions, the bearing housing assembly 50 quickly achieves a steady-state operating temperature. A seal is provided to prevent escape of. lubricant from the lower sump 40. This is accomplished without contact between stationary and rotating parts. The lower sump 4,0 has an inner wall 39 which extends above the top of. the stationary lubricant level and, without contacting it, surrounds the shaft 5 and effectively provides a static seal. No further sealing would be needed except for induced turbulence in the lubricant within the lower sump 40. To counteract turbulence induced lubricant loss, a non-contacting dynamic axial counterflow sealing device ia provided using the cup-like pumping device 30, A helical groove 36 on. the inner surface o£ the pumping device 39, having an opposite handing £rom the pumping grove 33, pumps lubricant downward during operation. The groove 36 co-operates with the outer surface of ., the inner wall 30 without contact, in the same manner as groove 33 cooperates with wall 31 of the bore without contact. The bearing lubrication, system has been shown in Fig, 1 as applied to a pump, It is clear that any vertical bearing housing which is lubricated by a wet sump lubrication, aystem can benefit from the features disclosed here.

Full Text

The present invention relates to an apparates
for lubricating bearing

This invention relates generally to lubrication of: bearings on. a rotatable • shaft and more particularly to supplying a lubricating fluid to bearings, within a vertical wet-sump bearing housing, at a constant flow rate which, is independent of operating spsed.
Present bearing lubrication systems for vertical wet. sump bearing housings are typically designed to supply lubricant at a flow rate specific to a design operating speed. They pump lubricant from a sump at the bottom of the housing to bearings at the top of the housing. The lubricant flows down through the bearings and returns to the sump. The amount and flow rate of lubricant supplied to the bearings is limited by the operating speed of the pump mechanism, the viscosity of. the lubricant, and the size of: the passages through which the lubricant is pumped to the bearings. While such systems, assuming constant viscosity, perform adequately at the design speed they may become ineffective at low operating speed, or they nay provide excess lubricant at high operating speed, aa would, be encountered with a variable apeed drive input. Thus, at low speed lubrication, may ba inadequate, while at high apeed excessive lubricant flow may cause over pressure which leads to seal failure and leakage of lubricant to the surroundings.
In addition, lubricants are viscous liquids which, are subject to viscosity changes which are inversely related to temperature variations. Thus temperature increases cause viscosity decreases, and temperature decreases causa viscosity increases. Even when operating at design speed, the lubricant becomaa hot due to mechanical heat generation and loses viscosity. This causes decreased pumping action and results in inadequate lubrication of the /bearings.

Such inadequacies result in costly damage to equipment and the environment.
GB-A-444 496 discloses an apparatus for lubricating bearings in accordance with tlie preamble of claim 1.
According to one aspect of the present invention., thers is provided an, apparatus for lubricating bearings on. a vertical rotatable shaft within a bearing housing, comprising a lower lubricant sump at. a lower portion, of. said bearing housing; an upper lubricant reservoir at an upper portion of said bearing housing; a conduit providing fluid communication between said lower lubricant sump and said upper lubricant reservoir; means for metering a flow of lubricant from said upper lubricant reservoir into upper bearings; means for pumping lubricant from said lower lubricant sump, through aaid conduit, to said \ipper lubricant reservoir at a rate exceeding a rate of said matered flow into said upper bea.rings; and means in said upper lubricant reservoir, for maintaining a constant head of lubricant above said metering means and for shunting excess lubricant, back to aaid lower lubricant sump ; characterised by means for feeding a portion, of said excess lubricant to said lower bearings before said excess lubricant is returned to said lower lubricant sump.
According to another aspect of the present invention, there is provided a pumping device comprising a cup-like rotatable member, with an axis that is, in use, vertical, and having longitudinally directed oppositely handed, helical grooves on inner and outer surfaces; a smooth-walled bore in a stationary member closely surrounding without contacting the outer surface of eaid cup-like rotatabl© member) a smooth-walled stationary cylindrical member closely surrounded without contact by the inner surface of said cup-like member; and a sump which contains fluid at a level sufficient to cover a lower portion of.

said rotatable cup-like member, said smooth-walled bore, and said smooth-walled cylindrical member, such that rotation of said cup-like member causes the fluid to be pumped upwardly on one said surface and downwardly on the other said surface of tha cup-like member.
For a better understanding of the invention, and to show how the same may be carried into effect, reference will now be made, by way of example, to the accompanying drawings, in which:-
Fig1, 1 is a vertical schematic partially sectional view of a pump equipped with a vertical wet sump lubrication, system;
Fig. 2 is a fragmentary bottom perspective view of the pumping device; and
Fig. .3 is a fragmentary sectional elevation view of the lubricant metering and shunt features of an upper lubricant reservoir.
All the main features can be seen by referring to Pig, 1; however, it is also helpful to refer to Figs. 2 and 3, as appropriate, to further appreciate details of pumping, metering and shunting provisions. In'Fig. 1, the invention is shown aa applied to a vertical pump unit 60. A bearing housing assembly 50 has upper bearings 14 and lower bearings 18 supporting a rotatable shafts which is mounted within a bearing housing 10. A lower annular lubricant sump 40 in a lower end cover 11 of the housing 10 and an upper annular lubricant reservoir 20 in an upper end cover 12 are connected by a conduit 35, which is preferably bored in the wall of the housing 10. A cup-like pumping or lifting device 30, which is fixed to the rotatatole shaft 5, pumps lubricant by means of at least one helical groove 33 in the outer surface thereof, which groove co-operates with

the inner wall 31 of a bore through which the cup-like pimping device 30 extends downward into the lower lubricant sump 40. Note that there ia no contact between the cup-like pumping device 30 and the inner wall 31 of the bore. The groove 33 is sized" such that it pumps an excess quantity of lubricant to the upper bearings 14 at all operating speeds. These features are seen in Figs. 1 and 2 .
The upper lubricant reservoir 20, seen in Figs. 1 and 3, has a, spillway or overflow barrier 26 which maintains a constant pressure head above a metering orifice 25. The metering orifice 25 is sized to provide full lubrication, as required by the upper bearings 14, at all operating speeds and viscosity ranges. The metering orifice 25 has its mouth located slightly above the bottom of the upper reservoir 20 to retain a small amount of lubricant in the reservoir 20 upon shut-down. This assures a minimal response time for supplying .lubricant to the upper bearings 14 when re-starting the unit after such shut-down. Any excess lubricant reaching upper reservoir 20 passes over the overflow barrier 26 and is shunted back to the lower sump 40 through shunt passage 19, This overflow and shunt feature allows the , pumping device to operate with no throttling or other constriction without regard to operating speed; because the full lubricant requirements are always met, and any excess lubricant is merely returned to the lower sump 40. A portion of the excess lubricant ia directed, by the bowl shaped lower surface of the housing 10, through the lower bearings 18 before draining to the lower sump 40,
Lubricant which passes through, the upper bearings .1.4 falls onto a slinger ring 45 attached to the shaft 5 below the bearings 14. The slingar ring 45 throws the lubricant against the wall of the bearing housing 10 where it gives up heat collected by contacting various parts of the

bearings and shaft 5. By design, lubricant which ia not actually lubricating the bearings is exposed as much as possible to cooler surfaces within the bearing housing 10. This helps to dissipate heat and to maintain a steady state operating temperature.
The cup-like pumping device 30 also acts aa a heat sink to extract heat from the shaft 5 adjacent to the lower bearing 18. The intimate mixing contact between, the lubricant and the pumping device 30 assures maximum heat transfer to the lubricant, which then serves to carry the heat to the housing walls 10, 11, 12 and to thus dissipate it to the surroundings of the housing assembly 50. This feature is important especially if the shaft 5 ia exposed to an external heat source such as hot pumpage or hot air. Thus, under any operating conditions, the bearing housing assembly 50 quickly achieves a steady-state operating temperature.
A seal is provided to prevent escape of. lubricant from the lower sump 40. This is accomplished without contact between stationary and rotating parts. The lower sump 4,0 has an inner wall 39 which extends above the top of. the stationary lubricant level and, without contacting it, surrounds the shaft 5 and effectively provides a static seal. No further sealing would be needed except for induced turbulence in the lubricant within the lower sump 40. To counteract turbulence induced lubricant loss, a non-contacting dynamic axial counterflow sealing device ia provided using the cup-like pumping device 30, A helical groove 36 on. the inner surface o£ the pumping device 39, having an opposite handing £rom the pumping grove 33, pumps lubricant downward during operation. The groove 36 co-operates with the outer surface of ., the inner wall 30 without contact, in the same manner as groove 33 cooperates with wall 31 of the bore without contact.

The bearing lubrication, system has been shown in Fig, 1 as applied to a pump, It is clear that any vertical bearing housing which is lubricated by a wet sump lubrication, aystem can benefit from the features disclosed here.

Documents:

520-del-1998-abstract.pdf

520-del-1998-assignment.pdf

520-DEL-1998-Correspondence Others-(29-04-2011).pdf

520-DEL-1998-Correspondence-Others-(31-03-2010).pdf

520-del-1998-correspondence-others.pdf

520-del-1998-correspondence-po.pdf

520-del-1998-description (complete).pdf

520-del-1998-drawings.pdf

520-del-1998-form-1.pdf

520-del-1998-form-13.pdf

520-del-1998-form-19.pdf

520-del-1998-form-2.pdf

520-DEL-1998-Form-27-(29-04-2011).pdf

520-del-1998-form-3.pdf

520-del-1998-form-4.pdf

520-del-1998-form-6.pdf

520-del-1998-gpa.pdf

520-DEL-1998-Petition 138-(31-03-2010)-1.pdf

520-DEL-1998-Petition 138-(31-03-2010).pdf

520-del-1998-petition-137.pdf

520-DEL-1998-Petition-138-(29-04-2011).pdf

520-del-1998-petition-138.pdf

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Patent Number

221983

Indian Patent Application Number

520/DEL/1998

PG Journal Number

32/2008

Publication Date

08-Aug-2008

Grant Date

14-Jul-2008

Date of Filing

26-Feb-1998

Name of Patentee

FLOWSERVE MANAGEMENT COMPANY

Applicant Address

222 W.LAS COLINAS BOULEVARD, SUITE 1500, IRVING, TEXAS 70539, U.S.A.

Inventors:

#	Inventor's Name	Inventor's Address
1	WILLIAM B.JONES	JR., 14963 LASHBURN STREET, WHITTIER, CA 90604
2	MARK L. HALL	13096 BLACKBURN STREET #175, GARDEN GROVE, CA 92843,
3	HAYRAPETIAN	1535 THOMSPSON AVENUE GLENDALE, CA 91201
4	KHAJAK JACK MINASSIAN	1256 RUBERTA AVENUE, GLENDALE, CA 91201

PCT International Classification Number

F16N 13/20

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	08/807,311	1997-02-27	U.S.A.