The present embodiments relate generally to gear pumps and, more particularly, to a pressure loaded journal bearing of a gear pump.
A gear pump operates to pump fluid from an inlet to an outlet. Generally, a gear pump utilizes multiple gears, including a drive gear and a driven gear, each with respective teeth. The drive gear is rotated, and in turn rotates the driven gear at a location where the respective teeth mesh. Fluid enters the inlet and travels between the teeth of the drive gear and a housing, and the teeth of the driven gear and the housing. As the gears turn, the fluid is pulled towards the outlet and squeezed out of the gear pump due to a pressure differential between the inlet and outlet.
Both the drive gear and the driven gear are supported within the gear pump by respective gear shafts. Each gear shaft is in turn supported by both a pressure loaded journal bearing and a stationary journal bearing, both of which react the load of the gear shaft. The gear shaft load is carried by both the stationary and pressure loaded journal bearings through a fluid film pressure in each journal bearing, between a surface of the gear shaft and a surface of the journal bearing. Bearings such as these, which support their loads on a layer of liquid, are known as hydrodynamic bearings. Pressure develops in the fluid film as a result of a velocity gradient between the rotating surface of the gear shaft and the surface of the journal bearing (i.e., a viscosity of the fluid resists a shearing action of the velocity gradient).
A conventional hydrodynamic bearing will operate at a fluid film thickness at which the film pressure in the journal bearing reacts the loads applied to the gear and gear shaft. However, for a given operating condition, as the loads continue to increase the fluid film thickness will continue to reduce until the surfaces of the gear shaft and the journal bearing physically contact one another. This is referred to as a “bearing touchdown,” and can cause damage, decreased performance, or catastrophic failure of the gear pump.
One solution for increasing the load carrying capacity of a given hydrodynamic journal bearing is to increase a size of the journal bearing. However, in certain gear pump applications operating and/or weight requirements do not permit the use of a larger and/or heavier journal bearing.
One embodiment includes a gear pump with a drive gear, a gear shaft passing through the drive gear, and a pressure loaded journal bearing. Also included is a fluid film, between a surface of the pressure loaded journal bearing and a surface of the gear shaft, and a hybrid pad on the pressure loaded journal bearing. The hybrid pad has a minimum leading edge angular location on the pressure loaded journal bearing of 29.5° and a maximum trailing edge angular location on the pressure loaded journal bearing of 42.5°. The gear pump also includes a porting path for supplying high pressure fluid from a discharge of the gear pump to the fluid film at the hybrid pad.
Another embodiment includes a method for use with a pressure loaded journal bearing. The method includes supporting a drive gear with a pressure loaded journal bearing, with a gear shaft passing through the drive gear. The method also includes providing a fluid film between a surface of the pressure loaded journal bearing and a surface of the gear shaft, and providing a hybrid pad on the pressure loaded bearing. The hybrid pad is located to have a minimum leading edge angular location on the pressure loaded journal bearing of 29.5° and a maximum trailing edge angular location on the pressure loaded journal bearing of 42.5°. High pressure fluid is supplied from a discharge of a gear pump to the hybrid pad through a capillary port at an angular location on the pressure loaded journal bearing of approximately 36°, and the fluid film is pressurized with the high pressure fluid supplied to the hybrid pad.
While the above-identified drawing figures set forth one or more embodiments of the invention, other embodiments are also contemplated. In all cases, this disclosure presents the invention by way of representation and not limitation. It should be understood that numerous other modifications and embodiments can be devised by those skilled in the art, which fall within the scope and spirit of the principles of the invention. The figures may not be drawn to scale, and applications and embodiments of the present invention may include features and components not specifically shown in the drawings.
Generally, a load carrying capacity of a pressure loaded journal bearing supporting a drive gear can be increased, without increasing a size of the pressure loaded journal bearing, by supplying high pressure fluid from a discharge of a gear pump to a fluid film at a hybrid pad on the pressure loaded journal bearing. The high pressure fluid supplied to the fluid film at the hybrid pad allows the fluid film, and thus the pressure loaded journal bearing, to support an increased load, yet at the same time meet gear pump operating and/or weight requirements. However, a location of the hybrid pad on the pressure loaded journal bearing is critical for successfully increasing the load carrying capacity of the pressure loaded journal bearing without compromising gear pump flow requirements.
Gear pump 10 can operate to pump fluid 11 at a constant rate from inlet 14 to outlet 16. Fluid 11 enters housing 12 at inlet 14. Using a relatively low supplied inlet pressure, fluid 11 fills into gaps between teeth of drive gear 18 and housing 12, and teeth of driven gear 20 and housing 12. Drive gear 18 is rotated, in a counterclockwise direction in the illustrated embodiment, which in turn rotates driven gear 20, in a clockwise direction in the illustrated embodiment. As gears 18 and 20 turn, fluid 11 is moved toward relatively high pressure outlet 16 and squeezed out from housing 12 as high pressure fluid 11h. Fluid 11 (and 11h) and fluid film 52 (shown in
For a given gear pump 10, drive gear 18 and driven gear 20 experience different loading. For example, drive gear 18 experiences radial pressure load 22 and power transfer reaction load 24 in the directions shown in
The load carrying capacity of pressure loaded journal bearing 36 is increased by delivering high pressure fluid 11h from outlet 16 to hybrid pad 50. Fluid 11h from outlet 16 is supplied to hybrid pad 50 through porting path 40. Specifically, fluid 11h discharges from outlet 16 at discharge face cut 42, and passes through axial hole 44 to radial spool cut 46 as shown in
Capillary port 48 extends through pressure loaded bearing 36 from radial spool cut 46 to hybrid pad 50, as shown in
Hybrid pad 50 is a location where high pressure fluid 11h is injected into fluid film 52, as shown in
Fluid film 52, as shown in
However, as noted previously, an increased load carrying capacity of bearing 36 can only result if hybrid pad 50 is properly configured. The proper configuration of hybrid pad 50 is a function of a plurality of factors, which can include, for example, a rotational speed of gear shaft 32, a magnitude and angle of gear shaft 32 radial load F, maximum diametral clearance C between a surface of bearing 36 and a surface of gear shaft 32, geometry of gear shaft 32 and bearing 34 or 36, and fluid film 52 properties (e.g., density, viscosity, specific heat). An improperly configured hybrid pad 50 can vent fluid film 52 pressure, instead of adding to fluid film 52 pressure, resulting in a decrease in load carrying capability of bearing 36. Also, an improperly configured hybrid pad 50 can result in excessive gear pump 10 leakage, preventing gear pump 10 from meeting flow requirements.
Plot 62 (no hybrid pad) shows a thickness of fluid film 52 is approximately 10.3 micron at all angular positions of load F. When hybrid pad 50 is configured on bearing 36 at angular location θP (36°), plot 64 (minimum load angle) shows a thickness of fluid film 52 at θP of approximately 31.5 micron, while plot 66 (maximum load angle) shows a thickness of fluid film 52 at θP of approximately 21.1 micron. Therefore, by pressurizing fluid film 52 with high pressure fluid 11h at hybrid pad 50 configured at angular location θP of 36°, bearing 36 not only has a thicker fluid film 52 and thus can carry a greater load as compared to bearing 36 without hybrid pad 50 (plot 62), but can also maintain fluid film 52 at a thickness great enough to support maximum load F over a range of angles of load F. Furthermore, designing gear pump 10 such that hybrid pad 50 is located at angular location θP of 36°, allows for manufacturing tolerances within region R which still permit bearing 36 to perform over a range of angles of maximum load F because θP is near a maximum thickness of fluid film 52, yet eliminates a risk of manufacturing tolerances leading to a location of hybrid pad 50 where the thickness of fluid film 52 significantly decreases. The present inventors have discovered that at all other hybrid pad 50 angular locations less than angular location θP of 36°, thickness of fluid film 52 decreases, and thus so does bearing 36 load carrying capacity (and the ability to accommodate manufacturing tolerances). Furthermore, altering hybrid pad 50 angular location θP by more than a couple degrees greater than 36° causes a decrease in thickness of fluid film 52 for plot 64 (minimum load angle). Thus, varying hybrid pad 50 configuration forward or backward by even a few angular degrees significantly alters the thickness of fluid film 52 over the range of angles of load F, and thus ultimately the ability of bearing 36 to prevent a bearing touchdown under all load ranges. Hybrid pad 50 angular location θP of 36° strikes a balance between allowing bearing 36 to support maximum load F over the various angular locations of maximum load F, while still taking into account manufacturing tolerances in region R when locating hybrid pad 50.
A right vertical axis of
Consequently, by properly configuring hybrid pad 50 and delivering high pressure fluid 11h to fluid film 52 at hybrid pad 50, the load carrying capacity of bearing 36 can be increased, without obstructing gear pump 10 from meeting flow requirements, such that a risk of a bearing touchdown is eliminated or substantially eliminated. Yet, bearing 36 size and/or weight is not increased, and as a result gear pump 10 can be utilized in applications with operating and/or weight requirements.
The following are non-exclusive descriptions of possible embodiments of the present invention.
A gear pump comprising a drive gear; a gear shaft passing through the drive gear; a pressure loaded journal bearing; a fluid film between a surface of the pressure loaded journal bearing and a surface of the gear shaft; a hybrid pad on the pressure loaded journal bearing with a minimum leading edge angular location on the pressure loaded journal bearing of 29.5° and a maximum trailing edge angular location on the pressure loaded journal bearing of 42.5°; and a porting path for supplying high pressure fluid from a discharge of the gear pump to the fluid film at the hybrid pad.
The gear pump of the preceding paragraph can optionally include, additionally and/or alternatively, any one or more of the following features, configurations and/or additional components:
The hybrid pad is axially spaced approximately 0.28 inch (0.71 cm) from a face of the drive gear, and wherein the hybrid pad has an axial length of approximately 0.80 inch (2.03 cm).
The fluid film supports a radial load of up to approximately 423 lbf/in2 (2916 kPa) at or near the hybrid pad.
The radial load is at an angular location of approximately 48.8°.
A maximum diametral clearance between the surface of the pressure loaded journal bearing and the surface of the gear shaft is approximately 0.0041 inch (0.0104 cm).
The high pressure fluid from the discharge of the gear pump is Jet A-1 fluid, and wherein the fluid is approximately 300° F. (149° C.) when entering the gear pump.
The porting path comprises a discharge face cut on the pressure loaded journal bearing for receiving the high pressure fluid from the discharge of the gear pump; a radial spool cut on the pressure loaded journal bearing; an axial hole through the pressure loaded journal bearing for communicating the high pressure fluid from the discharge face cut to the radial spool cut; and a capillary port extending through the pressure loaded bearing from the radial spool cut to the hybrid pad for delivering the high pressure fluid from the radial spool cut to the hybrid pad.
A centerline of the capillary port is axially spaced approximately 0.6225 inch (1.58 cm) from a face of the drive gear.
The capillary port has an angular location on the pressure loaded journal bearing of approximately 36°.
The capillary port has a diameter of approximately 0.023 inch (0.058 cm).
A method for use with a pressure loaded journal bearing, the method comprising supporting a drive gear with a pressure loaded journal bearing, wherein a gear shaft passes through the drive gear; providing a fluid film between a surface of the pressure loaded journal bearing and a surface of the gear shaft; providing a hybrid pad on the pressure loaded bearing and locating the hybrid pad to have a minimum leading edge angular location on the pressure loaded journal bearing of 29.5° and a maximum trailing edge angular location on the pressure loaded journal bearing of 42.5°; supplying high pressure fluid from a discharge of a gear pump to the hybrid pad through a capillary port at an angular location on the pressure loaded journal bearing of approximately 36°; and pressurizing the fluid film with the high pressure fluid supplied to the hybrid pad.
The method of the preceding paragraph can optionally include, additionally and/or alternatively, the following techniques, steps, features and/or configurations:
Subjecting the gear shaft to a radial load of up to approximately 423 lbf/in2 (2916 kPa) at an angular location of approximately 48.8°.
The hybrid pad is axially positioned approximately 0.28 inch (0.71 cm) from a face of the drive gear.
The gear shaft is rotated at a speed of approximately 9056 RPM.
Pressurizing the fluid film with the high pressure fluid increases a thickness of the fluid film by approximately 0.000425 inch (0.00108 cm).
Any relative terms or terms of degree used herein, such as “generally”, “substantially”, “approximately”, and the like, should be interpreted in accordance with and subject to any applicable definitions or limits expressly stated herein. In all instances, any relative terms or terms of degree used herein should be interpreted to broadly encompass any relevant disclosed embodiments as well as such ranges or variations as would be understood by a person of ordinary skill in the art in view of the entirety of the present disclosure, such as to encompass ordinary manufacturing tolerance variations, incidental alignment variations, temporary alignment or shape variations induced by operational conditions, and the like.
While the invention has been described with reference to an exemplary embodiment(s), it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment(s) disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.