Aerospace bearing

Aerospace bearings are the bearings installed in aircraft and aerospace systems including commercial, private, military, or space applications.

US Airman cleans thrust bearings, an example of aerospace bearings.

Materials include M50 tool steel (AMS6491), carbon chrome steel (AMS6444), the corrosion resistant AMS5930, 440C stainless steel, silicon nitride (ceramic) and titanium carbide-coated 440C.[1]

Typically, special attention is given to the material specification, non-destructive testing, and to the traceability of the bearing (a system of documents that enables an engineer to trace a bearing, typically back to its manufacturing batch and material supply).

Design

When designing aerospace bearings, it is important to take a few things into account, including:

  • material standard
  • design
  • lubrication type
  • surface coatings and treatments
  • non-destructive testing
  • traceability

In order to assure bearing performance, it is necessary for the bearing steel to be of high quality. Jet engine bearings are typically manufactured from metals manufactured using a vacuum arc remelt to enable material requirements to be met.

Jet engine shaft bearings and accessory drive shaft bearings typically use single piece or two piece machined retainers. The pressed steel or moulded retainers found on mass-produced bearings are not used.

Temperature and moisture resistant oils, greases and lubricants are normally specified. If the lubricant is not correct the performance of the bearing will be compromised.

Application

In jet engines bearings can operate at over 200 degrees Celsius (400 °F) and at speeds over 10,000 rpm for the turbine shafts to over 30,000 rpm in the accessory drives. In wing control surface applications temperatures as low as −55 °C (−67 °F) may be encountered.

Monitoring

Bearings are a vital factor in many products and assemblies and their performance is often monitored continuously. In jet engines the oil supply is monitored to detect the presence of metallic debris that could identify a failure either of the bearings or of other components whose failure may contaminate the bearings.

References

  1. J. J. C. Hoo; Willard B. Green (1998). Bearing steels: into the 21st century. ASTM International. pp. 355–358. ISBN 0-8031-2421-X.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.