초록

A bearing scavenge system comprises a scavenging passage extending axially through a rotating shaft supported by the bearing assembly. Oil and air are drawn from an oil cavity of the bearing assembly and evacuated through the rotating shaft as the shaft rotates.

대표청구항 ▼

The invention claimed is: 1. A scavenge system for a bearing assembly, the system comprising a scavenging passage extending axially through a rotating shaft supported by the bearing assembly, at least one inlet passage extending substantially radially inwardly from a peripheral surface of the shaft

The invention claimed is: 1. A scavenge system for a bearing assembly, the system comprising a scavenging passage extending axially through a rotating shaft supported by the bearing assembly, at least one inlet passage extending substantially radially inwardly from a peripheral surface of the shaft to said scavenging passage, and at least one scoop provided on the rotating shaft, said at least one scoop impelling oil internally of said rotating shaft radially inwardly through said at least one inlet passage into said scavenging passage as said at least one scoop rotates with said rotating shaft. 2. A scavenge system as defined in claim 1, wherein at least two scoops are defined in said rotating shaft, and wherein each pair of adjacent scoops defines one of said at least one inlet passage therebetween. 3. A scavenge system as defined in claim 1, wherein said at least one scoop curves radially outwardly in a direction of rotation of said rotating shaft. 4. A scavenge system as defined in claim 1, wherein said at least one scoop has a curved cross-section which is thinner toward the outer surface of the rotating shaft. 5. A scavenge system as defined in claim 2, further comprising a number of conduits in fluid communication with an oil cavity communicating with the bearing assembly, the conduits defining a plurality of circumferentially aligned openings in an annular inner surface closely surrounding an outer surface of the rotating shaft. 6. A scavenge system as defined in claim 1, wherein said scavenging passage is concentric with the rotating shaft and in fluid flow communication with a stationary chamber. 7. A scavenge system as defined in claim 5, wherein there is provided at least two angularly spaced-apart inlet passages in the rotating shaft between the scoops, each of the inlet passages being defined such as to alternately be aligned with each of the plurality of openings during a rotation of the shaft, the rotation of the shaft creating an interaction between aligned inlet passages and openings such that used oil flowing from the conduits is drawn from the openings to the inlet passages, so as to flow through the scavenge passage axially of the rotating shaft. 8. A scavenge system as defined in claim 7, wherein the scavenge passage is annular. 9. A scavenge system as defined in claim 5, wherein each of the conduits is composed of a first tube connected to a second tube, the first tube extending along an axial direction of the rotating shaft and the second tube extending along a radial direction of the rotating shaft. 10. A scavenge system as defined in claim 1, wherein each inlet passage is perpendicular to the scavenge passage and is inclined with respect to a radius of the rotating shaft. 11. A scavenge system as defined in claim 5, wherein the plurality of openings are grouped in series of closely adjacent openings, the series being regularly angularly spaced apart. 12. A scavenge system as defined in claim 6, wherein the stationary chamber is located at a downstream end of the rotating shaft. 13. A scavenge system for a bearing assembly, the system comprising a scavenging passage extending axially through a rotating shaft supported by the bearing assembly, and means provided on the rotating shaft for drawing oil radially inwardly towards a central axis of said rotating shaft and into said scavenging passage as said shaft rotates. 14. A scavenge system as defined in claim 13, wherein said means comprise at least one hole defined in said rotating shaft, said at least one hole being perpendicular to an axis of the rotating shaft and at an angle to a radius thereof. 15. A scavenge system as defined in claim 13, wherein said means comprise at least one scoop provided at the outer surface of the rotating shaft, said at least one scoop picking up oil at the outer surface of the shaft and directs the oil into said scavenge passage as the shaft rotates. 16. A scavenge system as defined in claim 15, wherein said means comprise at least two scoops defined in said rotating shaft, and wherein each pair of adjacent scoops defines an inlet passage therebetween, said inlet passage being in fluid flow communication with said scavenging passage. 17. A scavenge system as defined in claim 15, wherein said at least one scoop curves radially outwardly in a direction of rotation of said rotating shaft. 18. A scavenge system as defined in claim 15, wherein said at least one scoop has a curved cross-section which is thinner toward the outer surface of the rotating shaft. 19. A scavenge system as defined in claim 13, further comprising: first fluid communication means between a lubricant cavity containing the bearing assembly and an annular inner surface closely surrounding an outer surface of the rotating shaft. 20. A scavenge system as defined in claim 19, wherein said first fluid communication means comprise a number of conduits in fluid communication with the lubricant cavity, the conduits defining a plurality of circumferentially aligned openings in said annular inner surface. 21. A scavenge system for a bearing assembly, the system comprising a scavenging passage extending axially through a rotating shaft supported by the bearing assembly, and at least one scoop provided on the rotating shaft, said at least one scoop impelling oil internally of said rotating shaft into said scavenging passage as said at least one scoop rotates with said rotating shaft, further comprising a number of conduits in fluid communication with an oil cavity communicating with the bearing assembly, the conduits defining a plurality of circumferentially aligned openings in an annular inner surface closely surrounding an outer surface of the rotating shaft, wherein there is provided at least two angularly spaced-apart inlet passages in the rotating shaft between the scoops, each of the inlet passages being defined such as to alternately be aligned with each of the plurality of openings during a rotation of the shaft, the rotation of the shaft creating an interaction between aligned inlet passages and openings such that used oil flowing from the conduits is drawn from the openings to the inlet passages, so as to flow through the scavenge passage axially of the rotating shaft.