Abstract
NASA Langley and the U.S. Army have jointly sponsored programs to assess the effects of realistic flight environments and ground-based exposure on advanced composite materials and structures. Composite secondary structural components were initially installed on commercial transport aircraft in 1973; secondary and primary structural components were installed on commercial helicopters in 1979; and primary structural components were installed on commercial aircraft in the mid-to-late 1980's. Over 5.3 million total component flight hours have been accumulated on 350 composite components since 1973. Service performance, maintenance characteristics, and residual strength of numerous composite components are reported. In addition to data on flight components; 10-year ground-based exposure test results on material coupons are reported. Comparisons between flight and ground-based environmental effects for several composite material systems are also presented. Test results indicate excellent in-service performance with the composite components during the 15 year evaluation period. Good correlation between ground-based material performance and operational structural performance has been achieved.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Dexter, H.B. 1987. Long-Term Environmental Effects and Flight Service Evaluation of Composite Materials.NASA TM 89067.
Zinberg, H. 1982. Flight Service Evaluation of Composite Components on the Bell Model 206L: Design, Fabrication, and Testing.NASA CR 166002.
Rich, M.J. and Lowry, D.W. 1982. Flight Service Evaluation of Composite Helicopter Components—First Annual Report.NASA CR 165952.
Lowry, D.W. and Rich, M.J. 1983. Design, Fabrication, Installation, and Flight Service Evaluation of a Composite Cargo Ramp Skin on a Model CH-53 Helicopter.NASA CR 172126.
Wooley, J.H., Paschal, D.R., and Crilly, E.R. 1973. Flight Service Evaluation of PRD-49/Epoxy Composite Panels in Wide-Bodied Commercial Transport Aircraft.NASA CR 112250.
Stone, R.H. 1984. Flight Service Evaluation of Kevlar-49/Epoxy Composite Panels in Wide Bodied Commercial Transport Aircraft—Tenth and Final Annual Flight Service Report.NASA CR 172344.
Coggeshall, R.L. 1989. Boeing/NASA Composite Components Flight Service Evaluation.NASA CR 181898.
Fox, B.R. 1985. Flight Service Evaluation of an Advanced Metal Matrix Aircraft Structural Component—Flight Service Final Report.MDC Report J3827.
Lehman, G.M. 1982. Flight-Service Program for Advanced Composite Rudders on Transport Aircraft-Sixth Annual Summary Report.MDC Report J6574.
Fox, B.R. 1985. Flight-Service Program for Advanced Composite Rudders on Transport Aicraft—Ninth Annual Summary Report.MDC Report J-3871.
Chovil, D.V. et al. 1980. Advanced Composite Elevator for Boeing 727 Aircraft—Volume 2 Final Report.NASA CR 15958.
Stone, R.H. 1987. Flight Service Evaluation of Advanced Composite Ailerons on the L-1011 Transport Aircraft—Fifth Annual Flight Service Report.NASA CR17832.
McCarty, J.E. and Wilson, D.R. 1983. Advanced Composite Stabilizer for Boeing 737 Aircraft, inSixth Conference on Fibrous Composites in Structural Design. AMMRC MS 83-2.
Mardoian, G.H. and Ezzo, M.B. 1990. Flight Service Evaluation of Composite Helicopter Components.NASA CR182063.
Baker, D.J. 1990. Evaluation of Composite Components on the Bell 206 L and Sikorsky S-76 Helicopters.NASA TM 4195.
Hoffman, D.J. and Bielawski, W.J. 1991. Environmental Exposure Effects on Composite Materials for Commercial Aircraft.NASA CR 187478.
Author information
Authors and Affiliations
About this article
Cite this article
Dexter, H.B., Baker, D.J. Flight service environmental effects on composite materials and structures. Adv Perform Mater 1, 51–85 (1994). https://doi.org/10.1007/BF00705313
Issue Date:
DOI: https://doi.org/10.1007/BF00705313