Role of the Material Constitutive Model in Simulating the Reusable Launch Vehicle Thrust Cell Liner Response
Publication: Journal of Aerospace Engineering
Volume 18, Issue 1
Abstract
The reusable launch vehicle thrust cell liner, or thrust chamber, is a critical component of the space shuttle main engine. It is designed to operate in some of the most severe conditions seen in engineering practice. These conditions give rise to characteristic deformations of the cooling channel wall exposed to high thermal gradients and a coolant-induced pressure differential, characterized by the wall’s bulging and thinning, which ultimately lead to experimentally observed “dog-house” failure modes. In this paper, these deformations are modeled using the cylindrical version of the higher-order theory for functionally graded materials in conjunction with two inelastic constitutive models for the liner’s constituents, namely Robinson’s unified viscoplasticity theory and the power-law creep model. Comparison of the results based on these two constitutive models under cyclic thermomechanical loading demonstrates that, for the employed constitutive model parameters, the power-law creep model predicts more precisely the experimentally observed deformation leading to the “dog-house” failure mode for multiple short cycles, while also providing much improved computational efficiency. The differences in the two models’ predictions are rooted in the differences in the short-term creep and relaxation responses.
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Acknowledgments
The support of the NASA–Glenn Research Center through Grant No. NAG3-2411 is gratefully acknowledged, as is the assistance of Dr. S. M. Arnold, the Technical Monitor for this grant.
References
Aboudi, J., Pindera, M.-J., and Arnold, S. M. (1999). “Higher-order theory for functionally graded materials.” Composites, Part B, 30(8), 777–832.
Armstrong, W. H. (1979). “Structural analysis of cylindrical thrust chambers.” NASA Contractor Rep. No. 159522, Washington, D.C.
Armstrong, W. H., and Brogren, E. W. (1975). “Thrust chamber life prediction. Volume II—Plug nozzle centerbody and cylinder life analysis.” NASA Contractor Rep. No. 134822, Washington, D.C.
Armstrong, W. H., and Brogren, E. W. (1976). ”3-dimesional thrust chamber life prediction.” NASA Contractor Rep. No. 134979, Washington, D.C.
Arnold, S. M. (1987). “Effects of state recovery on creep buckling induced by thermomechanical loading.” PhD dissertation, Univ. of Akron, Akron, Ohio.
Arya, V. K., and Arnold, S. M. (1991). “Viscoplastic analysis of an experimental cylindrical thrust chamber liner.” NASA Technical Memorandum 103287, Washington, D.C.
Butler, D. T. (2003). “Analysis of factors affecting the performance of RLV thrust cell liners.” MS thesis, Univ. of Virginia, Charlottesville, Va.
Ellis, D. L., and Yun, H. M. (1999). “Cu-8 Cr-4 Nb alloy for reusable launch vehicle combustion chamber liners.” Insights in R & T presentation, NASA–Glenn Research Center, Cleveland.
Esposito, J. J., and Zabora, R. F. (1975). “Thrust chamber life prediction. Volume I—Mechanical and physical properties of high performance rocket nozzle materials.” NASA Contractor Rep. No. 134806, Washington, D.C.
Hannum, N. P., and Price, H. G., Jr. (1981). “Some effects of thermal-cycle-induced deformation in rocket thrust chambers.” NASA Technical Paper 1834, Washington, D.C.
Lewis, J. R. (1970). “Creep behavior of NARloy-Z.” Rep. No. MA-SSE-70-902, Rockwell International, Rocketdyne Division, Canoga Park, Calif.
Pindera, M.-J., and Aboudi, J. (2000). “HOTCFGM-2D: A coupled higher-order theory for cylindrical structural components with bi-directionally graded microstructures.” NASA Contractor Rep. No. 2000-210350, Washington, D.C.
Quentmeyer, R. J. (1977). “Experimental fatigue life investigation of cylindrical thrust chambers.” NASA Technical Memorandum X-73665, Washington, D.C.
Quentmeyer, R. J., Kapser, H. J., and Kazaroff, J. M. (1978). “Investigation of the effect of ceramic coatings on rocket thrust chamber life.” NASA Technical Memorandum 78892, Washington, D.C.
Robinson, D. N., and Swindeman, R. W. (1982). “Unified creep-plasticity constitutive equations for 2 Cr-1Mo steel at elevated temperature.” Rep. No. ORNL/TM-8444, Oak Ridge National Laboratory, Oak Ridge, Tenn.
Information & Authors
Information
Published In
Journal of Aerospace Engineering
Volume 18 • Issue 1 • January 2005
Pages: 28 - 41
Copyright
© 2005 ASCE.
History
Received: Sep 18, 2003
Accepted: Apr 20, 2004
Published online: Jan 1, 2005
Published in print: Jan 2005
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