Sage Journals: Discover world-class research

Abstract

The perceived benefits of permanent usage monitoring equipment in helicopters include savings in the cost of helicopter maintenance and a favourable impact on safety and fleet management. Unlike indirect fatigue monitoring, direct load monitoring relies on a large number of sensors which requires high operational and maintenance costs. In this paper, a learning network has been developed, and during training sessions allowed to learn how to predict fatigue damage indirectly from flight parameters. Each training example consists of instantaneous fatigue damage induced during a small time step, and flight parameters measured during the time step. The instantaneous damage values are evaluated through a new approach called the progressive damage model. By considering the laws of aerodynamics and dynamics, the network combines the flight parameters in such a way that the resulting features can be mapped into fatigue. About 10.5 flying hours of data were used to train the network. After training, the network was blind tested using flight parameters from 5.8 flying hours. The network was found to predict the fatigue damage of two rotating components indirectly from the flight parameters with accuracy better than the accuracy of a strain gauge system with 5 per cent measurement error.

Keywords

health and usage monitoring systems (HUMS)fatigue artificial intelligence neural networks flight data recorder

Get full access to this article

View all access options for this article.

References

James

D O N

The use of reliability techniques in civil aircraft structure airworthiness—a CAA view

The Aeronautical J., January 1988, 92 (911).

Stone

D E W

The reliability of inspection techniques in relation to damage tolerant design

The Aeronautical J., January 1988, 92 (911).

Amer

K B

A ‘new’ philosophy of structural reliability, fail safe versus safe life. Fourty-fourth Annual National Forum of the American Helicopter Society, 1988.

CAA.

Report of the working group on helicopter health monitoring, CAA paper 85012, Civil Aviation Authority, London, August 1985.

James

S L

The regulatory viewpoint. One day Conference on Helicopter Airworthiness in the 1990s, November 1990, The Royal Aeronautical Society.

Spigel

B S

Consideration of reliability design for rotorcraft. Proceedings of the American Helicopter Society, National Technical Specialists’ Meeting, Fatigue Methodology III, 1–11, October 1989.

Miner

M A

Cumulative damage in fatigue

J. Applied Mechanics, September 1945, A-159-A-164.

Edwards

P R

A description of Helix and Felix, standard fatigue loading sequences for helicopters, and of related fatigue tests used to assess them

Vertica, 1985, 9 (1).

Fraser

K F

General requirements and techniques for component fatigue Life substantiation in Australian service helicopters. Department of Defence, Defence Science and Technology Organisation, Aeronautical Research Laboratory, AR-006–619, Propulsion Report 187, June 1991.

10.

Venn

G J

Data processing of the Sea King operational recordings (trial installation phase). WHL FR3/7471/1, July 1982.

11.

Schaefer

C G

The effect of aerial combat on helicopter structural integrity. Fourty-fifth Annual National Forum of the American Helicopter Society, Washington, 1989, 197–210.

12.

Good

D E

Deibler

D T

Helicopter structural integrity monitoring. Eighteenth European Rotorcraft Forum, Paper No. H7, H7.1-H7.13, September 1992.

13.

Haas

D J

Milano

Flitter

Prediction of helicopter component loads using neural networks. AIAA Thirty-fourth Structures, Structural Dynamics, and Materials Conference, 19–22 April, 1993, AIAA paper 93–1301 (American Institute of Aeronautics and Astronautics).

14.

Haas

D J

Flitter

Milano

Helicopter flight data feature extraction for component load monitoring. Thirty-fifth Structures, Structural Dynamics, and Materials Conference, 18–20 April, 1994, AIAA paper 94–1308 (American Institute of Aeronautics and Astronautics).

15.

Tang

S S

O'Brian

L J

A novel method for fatigue life monitoring of non-airframe components. 1991, AIAA paper 91–1088, 1357–1370 (American Institute of Aeronautics and Astronautics).

16.

Azzam

The use of helicopter flight parameters for fatigue damage prediction. MJAD/R/125/93, MJA Dynamics, April 1993.

17.

Azzam

Indirect prediction of helicopter structural fatigue using measured aircraft parameters—training and test. MJAD/R/142/93, MJA Dynamics, December 1993.

18.

Gunsallus

C T

Pellum

W G

Flannelly

W G

Holometrics: an information transformation methodology. Fourty-fourth Annual National Forum of the American Helicopter Society, Washington, June 1988, 879–885.

19.

Gustavson

Pellum

W L

Systematic application of holometric synthesis for cost-effective flight load monitoring. The American Helicopter Society fourty-ninth Annual Forum, St. Louis, Missouri, May 19–21, 1993.

20.

Azzam

Model based fatigue damage prediction networks for helicopter components. Blind test validation, MJAD/R/156/94, MJA Dynamics, June 1994.

21.

Azzam

The use of a fatigue state decider to improve the performance of a helicopter fatigue damage prediction network. MJAD/R/166/95, MJA Dynamics, March 1995.

22.

Ellis

S D

A combined range-mean-pairs rainflow count of load time histories for use in formulation of structurally relevant cost functions and fatigue analysis. RAE TR 81122, October 1981.

23.

Holford

D M

The role of a fatigue damage accumulation plot in structural loads data analysis. RAE TR 82125, December 1982.

A practical approach for the indirect prediction of structural fatigue from measured flight parameters

Abstract

Keywords

Get full access to this article

References