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Advancements in polymer matrix composites have made them attractive to developers of power and propulsion equipment for spaceflight and aeronautic applications. However, many of these applications have very unique operational environments that are not easily found in the available design databases. Rapid insertion of these materials through prototype development and concept demonstration programs are hampered by the absence of relevant design data. In such cases, development programs conducted by the NASA Glenn Research Center have found it beneficial to employ pathfinder experimental methods designed to focus on the specific application and operational environment at hand. This chapter describes specialized experimental investigations of composite durability for applications that include flywheel energy storage, combustion chamber, and fan case structures. The experiments were designed to investigate complex thermomechanical and hygrothermal environments posed by these technologies. Beyond cycles-to-failure and residual strength, dimensional stability and stiffness degradation are key, if not primary, concerns in preserving functional capability for the cited applications.
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J. C. Thesken, C. L. Bowman, S. M. Arnold, and R. C. Thompson, (2003) "Time-Temperature Dependent Response of Filament Wound Composites for Flywheel Rotors," Composite Materials: Testing and Design Fourteenth Volume, ASTM STP 1436, C.E. Bakis, Ed., ASTM International, West Conshohocken, PA.
J. C. Thesken, E. E. Shin, J. K. Sutter, C. Burke, (2003) "Durability of Polyimide Composites subjected to thermo-mechanical fatigue in reusable propulsion systems", ICCM-14, July 14–18, San Diego, CA.
J. C. Thesken, M. G. Castelli and J.R. Ellis (2002) "Hygrothermal and Mechanical Fatigue of Polymer Matrix Composites for Propulsion Applications" Eighth International Fatigue Congress, Stockholm, Sweden.
Saleeb, A.F., Arnold, S.M., and Al-Zoubi, N.R., A Study of Time Dependent and Anisotropic Effects on the Deformation Response of Two Flywheel Rotor Designs. Composite Materials: Testing and Design Fourteenth Volume, ASTM STP 1436, C.E. Bakis, Ed., ASTM International, West Conshohocken, PA, 2003.
Genta, G., Kinetic Energy Storage: Theory and Practice of Advanced Flywheel Systems, Butterworths, 1985.
Keckler, C.R., Bechtel, R.T., and Groom, N.J., An Assessment of Integrated Flywheel System Technology. NASA CP 2346, 1984.
DeTeresa, S.J., Materials for Advanced Flywheel Energy Storage Devices., MRS Bulletin, 1999.
Bitterly, J.G., Flywheel Technology. IEEE AES Systems Magazine, 1998.
Arnold, S.M., A.F. Saleeb, and Al-Zoubi, N.R., Deformation and Life of Composite Flywheel Disk and Multi-Disk Systems. NASA/TM.2001-210578.
Tzeng, J.T., Viscoelastic Analysis of Composite Flywheels for Energy Storage. ARL-TR-2610, U.S. Army Research Laboratory, Aberdeen Proving Ground, MD 21005.
Tzeng, J.T., Viscoelastic Behavior of Composite Rotors at Elevated Temperatures. IEEE Transactions on Magnetics, Vol. 33, No. 1, 1997, pp. 413–418. CrossRef
Emerson, R.P. and Bakis C.E., Relaxation of Press-Fit Interference Pressure in Composite Flywheel Assemblies. Proc. 43th SAMPE Symposium and Exhibition, 31 May.June 4 1998, Long Beach, CA, SAMPE, Covina,CA 1998.
Emerson, R.P. and Bakis C.E., Viscoelastic Behavior of Composite Flywheels. Proc. 45th SAMPE Symposium and Exhibition, 21.25 May 2000, Long Beach, CA, SAMPE, Covina,CA 2000.
Thompson, R.C., Pak, T.T., and Rech, B.M., Hydroburst Test Methodology for Evaluation of Composite Structures. Composite Materials: Testing and Design Fourteenth Volume, ASTM STP 1436, C.E. Bakis, Ed., ASTM International, West Conshohocken, PA, 2003.
Irion, M.N., and Adams, D.F., "Compression Creep Testing of Unidirectional Composite Materials," Composites, Vol. 12, No. 2, April 1981, pp. 117–123. CrossRef
Mohan, R., and Adams, D.F., "Nonlinear Creep-Recovery Response of a Polymer Matrix and Its Composites," Experimental Mechanics, Vol. 25, No. 3, September 1985, pp. 262–271. CrossRef
Tuttle, M.E. and Brinson, H.F., Prediction of the Long-Term Creep Compliance of General Composite Laminates. Experimental Mechanics March 1986, pp. 89–102. CrossRef
Sullivan, J.L., Measurement of Composite Creep. Experimental Techniques Sept./Oct. 1991, pp. 32–37002E. CrossRef
Gates, T.S., Experimental Characterization of Nonlinear, Rate-dependent Behavior in Advanced Polymer Composites. Experimental Mechanics March 1992, vol. 31, pp. 68–73. CrossRef
Gates, T.S. and Sun, C.T., Elastic/Viscoplastic Constitutive Model for Fiber Reinforced Thermoplastic Composites. AIAA Journal, vol. 29, No. 3, 1991 pp. 457–463. CrossRef
Gates, T.S., Veazie, D.R. and Brinson, L.C.A. Comparisson of Tension and Compression Creep in Polymeric Composite and the Effects of Physical Ageing on Creep. NASA TM 110273 August 1996, NASA Langley Research Center.
Brinson, L.C. and Gates, T.S., Chapter 10.Viscoelasticity and Aging of Polymer Matrix Composites. Comprehensive Composite Materials. Editors in Chief, Kelly, A. and Zweben, C.H., Vol 2. 2000, pp. 333–368, Elsevier Science LTD, Oxford, UK.
Raghavan, J. and Meshii, M., Creep of Polymer Composites. Composites Science and Technology 57, 1997, pp. 1673–1688. CrossRef
Al-Haik, M., Vaghar, M.R. Garmestani, H., and Shahawy, M., Viscoplastic analysis of structural polymer composites using stress relaxation and creep data. Composites Part B: engineering, 32, 2001, pp. 165–170. CrossRef
Arnold, S.M., Saleeb, A.F., and Castelli, M.G., A General Time Dependent Constitutive Model: Part II. Application to a Titanium Alloy., Journal of Engineering Materials and Technology, 122, pp. 1–9.
Hexcel Advanced Composite Materials Technical Literature, "Hexcel 8552 Epoxy Matrix - Product Data," Hexcel, 5794 West Las Positas Blvd., P.O. Box 8181, Pleasanton, CA 94588-8781, August, 1998.
Baaklini, G.Y., Kono, K.K., Martin, R.E., and Thompson, R., NDE Methodologies for Composite Flywheels Certification. SAE Conference, 2000 Power Systems, San Diego October-November 2000. (also NASA/TM.2000-210473, October 2000).
Perry, C.C., Strain-Gage Reinforcement Effects on Low Modulus Materials-Section IIID. Manual on Experimental Methods for Mechanical Testing of Composites, Ed. M.E. Tuttle and R.L. Pendleton, SEM (1989).
Perry, C.C., Strain-Gage Reinforcement Effects on Orthotropic Materials-Section IIID. Manual on Experimental Methods for Mechanical Testing of Composites, Ed. M.E. Tuttle and R.L. Pendleton, SEM (1989).
Turner, S. Chapter 4 Creep in Glassy Polymers. in The Physics of Glassy Polymers ed. R.N. Haward, Applied Science Publishers LTD, London, 1973
Suh, N.S. and Turner, A.P.L., Elements of the Mechanical Behavior of Solids, 1974, Scripta Book Co., Washington D.C. p. 314.
Struik, L.C.E. Physical Aging in Amorphous Polymers and Other Materials, 1978, Elsevier Scientific Publishing Co. Amsterdam, Netherlands.
J. C. Thesken, M. Melis, E. Shin, J. Sutter and J. Fink (2003) “Design analysis of a Combustion Chamber Stiffened by Polymer Composite Sandwich” Presented at ICCM-14, San Diego, CA. July 14–18.
C.L. Bowman, J.K. Sutter, J.C. Thesken, and B.P. Rice, "Characterization of Graphite Fiber/Polyimide Composites for RLV Applications" in Proceedings of the 46th International SAMPE Symposium and Exhibition, Vol 46, Book 2, (SAMPE, Covina CA, 2001) 1515–1529.
E. Shin et al (2003): “Effects of Fiber Reinforcement Architecture on the Hygrothermal-Mechanical Performance of Polyimide Matrix Composites for Aeropropulsion applications” presented at ICCM-14, San Diego, CA. July 14–18.
E. E. Shin et al.(2002) “Design and Fabrication Issues of High Temperature PMCs for Aerospace Propulsion Applications” SAMPE 2002 Long Beach.
J. E. Fink, B. Shapey, E. Eugene Shin, James K. Sutter, John Thesken, and Demetrios Papadopoulos, Gary Wonacott and Chris Benzie (2002) “Initial Assessment of High Temperature Polymer Matrix Carbon Fiber Composites for 3 rd Generation Liquid Propellant Rocket Engine Applications” High Temple Workshop 22, Sante Fe, NM.
M. G. Castelli, J. K. Sutter, and D. Benson, “Durability and Damage Tolerance of Polyimide Chopped Fiber Composite Subjected to Thermomechanical Fatigue Missions and Creep Loadings, ”Time Dependent and Nonlinear Effects in Polymers and Composites, ASTM ASTP 1357, R. A Schapery and C. T. Sun, Eds., American Society for Testing and Materials, West Conshohocken, PA, 2000, pp. 285–309.
B. P. Rice and C.W. Lee, “Study of Blister Initiation and Growth in a High-Temperature Polyimide,” SAMPE International Technical Conference, 29, (1997) pp.675–685.
C.L. Bowman, J.C. Thesken, K.C. Chuang, and C.P. Arendt, "Graphite Fiber/Polyimide Composites Subjected To Moisture And Rapid Heating" in Proceedings of the 47th International SAMPE Symposium and Exhibition, Vol 47, (SAMPE, Covina CA, 2002).
M.B. Dow and D.L. Smith, SAMPE International Technical Conference, 21, (1989) pp. 595–605.
K.C. Chuang and J.E. Waters, “Effects of Endcaps on the Properties of Polyimide/Carbon Fiber Composites”, SAMPE International Symposium, 40, (1995) pp. 1113–1123.
A.L. Gyekenyesi, et al., “A Study of Elevated Temperature Testing Techniques for the Fatigue Behavior of PMCs: Application to T650-35/AMB21”, NASA TM 106927, July 1995
Cornelia., D.(1994). In: 39 th International SAMPE Symposium, pp. 917–929.
Bakis, C.E. et al. (1989). In: Composites (2nd Vol), ASTM STP 1003, pp.180–193.
Gyekenyesi, A.L. (1998). ASME-98-GT-106.
Talreja, R. (1981). In: Proceedings of the Royal Society of London, A378, pp. 461–475.
Nilsson, K. F., Thesken, J. C., Sindelar, P., Giannakopoulus, A. E. and Storåkers, B. (1993) J. Mech. Phys. Solids 41, 749–782. CrossRef
Reifsnider, K. and Stinchcomb, W.W. (1986). In: Composite Materials: Fatigue and Fracture, ASTM STP 907, pp. 298–313.
Lacy, T.E., McDowell, D.L. Willice, P. A. & Talreja, R. (1997) International Journal of Damage Mechanics, vol. 6, pp.62–95. CrossRef
- Durability of Polymer Composites in Power and Propulsion Applications
John C. Thesken
Cheryl L. Bowman
James K. Sutter
- Springer US
- Chapter 14
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