Stress wave analysis of turbine engine faults

Author

Board, David B.

Author_Institution

SWANTECH LLC, Lauderdale, FL, USA

Volume

6

fYear

2000

fDate

2000

Firstpage

79

Abstract

Stress Wave Analysis (SWAN) provides real-time measurement of friction and mechanical shock in operating machinery. This high frequency acoustic sensing technology filters out background levels of vibration and audible noise, and provides a graphic representation of machine health. By measuring shock and friction events, the SWAN technique is able to detect wear and damage at the earliest stages and is able to track the progression of a defect throughout the failure process. This is possible because as the damage progresses, the energy content of friction and shock events increases. This `stress wave energy´ is then measured and tracked against normal machine operating conditions. This paper describes testing that was conducted on several types of aircraft and industrial gas turbine engines to demonstrate SWAN´s ability to accurately detect a broad range of discrepant conditions and characterize the severity of damage

Keywords

acoustic transducers; aerospace engines; aircraft testing; friction; gas turbines; shock measurement; stress analysis; wear; SWAN technique; energy content; failure process; friction; gas turbine engines; high frequency acoustic sensing technology; machine health; mechanical shock; operating machinery; real-time measurement; shock; stress wave analysis; turbine engine faults; wear; Acoustic measurements; Electric shock; Engines; Filters; Frequency; Friction; Machinery; Mechanical variables measurement; Stress measurement; Turbines;

fLanguage

English

Publisher

ieee

Conference_Titel

Aerospace Conference Proceedings, 2000 IEEE

Conference_Location

Big Sky, MT

ISSN

1095-323X

Print_ISBN

0-7803-5846-5

Type

conf

DOI

10.1109/AERO.2000.877885

Filename

877885