The present invention relates to a pump system, and more particularly to a pump system which may be interchangeably utilized for either a clockwise or counterclockwise propeller shaft rotation.
Multi-engine propeller aircraft utilize pump systems which are driven by a propeller system gearbox. Typically, a pump system is mounted to a bulkhead within an engine nacelle of each engine to locate the main pump in proximity to the propeller system and associated gearbox. On multi-engine propeller aircraft, the propeller on adjacent engines typically rotates in opposite direction to counteract torque. That is, the propeller system of engine one rotates clockwise, the propeller system of engine two rotates counterclockwise, the propeller system of engine three rotates clockwise, and the propeller system of engine four rotates counterclockwise. Although an advantage from a propulsion perspective, such alternating rotations complicate pump installations as the engine gearboxes are also rotating in opposite directions. The associated pump drive systems must accommodate these specific rotations.
Conventional pump systems include a male drive shaft that extends from the pump system. Such conventional pump systems are designed to be driven from either end by switching the shaft. That is, a mounting structure is located on one end of the pump and a relatively significant blanking plate is bolted to the unused end to close the unused end of the pump against full pump pressure. This permits any single pump to accommodate either a clockwise or counterclockwise driven propeller system.
Disadvantageously, such conventional pump systems require that a clockwise mounting plate, a counterclockwise mounting plate and blanking plate be carried on the pump system at all times which increases system weight. The male drive shaft must also be removed and replaced to the opposite side to change the pump system to an opposite propeller rotation position. Such changeover requires disassembly of the pump at a significant depot level maintenance facilities which may increase aircraft downtime. The changeover to assure proper drive direction is a relatively complicated procedure which may further complicates maintenance time and expense.
Accordingly, it is desirable to provide a lightweight engine driven pump system which accommodates either a clockwise or counterclockwise propeller shaft rotation.
A pump system according to the present invention includes an inlet port, a discharge port, a drive aperture and a drain aperture. The drive aperture and the drain aperture are interchangeable such that the pump system may be utilized on either a clockwise or counterclockwise driven propeller. A gearbox driven male pump drive shaft is mounted into either aperture such that the aperture which receives the drive shaft becomes the drive aperture while the other aperture becomes the drain aperture.
A first pump gear is the driver gear in meshing engagement with a second pump gear which is the driven gear. The pump gears each include external gears in meshing engagement which communicate the fluid around the outside of the gears to provide the fluid pumping action from the inlet port to the discharge port. Fluid which is not communicated to the discharge port eventually collects within the second pump gear and is communicated to a gearbox drain through the drain aperture. As either pumping gear may become the driver gear by receiving the male drive shaft, the pump system may accommodate either a clockwise or counterclockwise propeller gearbox.
The present invention therefore provides a lightweight engine driven pump system which accommodates either a clockwise or counterclockwise propeller shaft rotation.
The various features and advantages of this invention will become apparent to those skilled in the art from the following detailed description of the currently preferred embodiment. The drawings that accompany the detailed description can be briefly described as follows:
A pump system 24 (
Such an alternating propeller rotation scheme requires that each associated pump system 24 be driven in a direction commensurate therewith. A mounting pad 27 is attached to each bulkhead 18 to mount the pump system 24 such that a pump drive shaft 28 rotates in a rotational direction (illustrated schematically by arrow r) relative to the propeller shaft 20 rotational direction R. The pump drive shaft 28 is preferably a male splined shaft. Typically, the pump shaft 28 rotates opposite the propeller shaft 20, however, other rotational schemes are also usable with the present invention. The male pump drive shaft 28 extends through the mounting pad 27 and is driven by the propeller gearbox 26 to drive the pump system 24.
The pump system 24 includes an inlet port 30, a discharge port 32, a drive aperture 34 and a drain aperture 36 (
Preferably, a locator pin 38 extends from the mounting pad 27 and is received into a locating aperture 40 formed into a seal plate 54 of pump housing 42 (
The inlet port 30 and the discharge port 32 are preferably located opposite each other and are spaced generally horizontally relative the vertically mounted apertures 34, 36. Such arrangement permits the drain aperture 36 to always be at the lowest point when the pump system 24 is mounted to the aircraft (
Referring to
Referring to
The first and second pump gear 50a, 50b each include an internal female spline 54a, 54b and an external gear 56a, 56b. The internal female spline 54a, 54b are equivalent and splined to receive the drive shaft 28 (
Either internal female spline 54a, 54b interchangeably receive the drive shaft 28 such that when the first internal female spline 54a receives the drive shaft 28, the first pump gear 50a is the driver gear, the first internal female spline 54a becomes the drive aperture 34, and the second internal female spline 54b becomes the drain aperture 36. Alternatively, when the second internal female spline 54b receives the drive shaft 28, the second pump gear 50b is the driver gear, the second internal female spline 54b becomes the drive aperture 34, and the first internal female spline 54a becomes the drain aperture 36.
Referring to
It should be understood that although a particular component arrangement is disclosed in the illustrated embodiment, other arrangements will benefit from the instant invention.
Although particular step sequences are shown, described, and claimed, it should be understood that steps may be performed in any order, separated or combined unless otherwise indicated and will still benefit from the present invention.
The foregoing description is exemplary rather than defined by the limitations within. Many modifications and variations of the present invention are possible in light of the above teachings. The preferred embodiments of this invention have been disclosed, however, one of ordinary skill in the art would recognize that certain modifications would come within the scope of this invention. It is, therefore, to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described. For that reason the following claims should be studied to determine the true scope and content of this invention.
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Number | Date | Country | |
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20060275117 A1 | Dec 2006 | US |