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Nuclear Technology Volume 75, 1986 - Issue 3
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Technical Paper

A Dynamic Reliability Model for Damage Accumulation Processes

Dov IngmanTechnion-Israel Institute of TechnologyDepartment of Nuclear Engineering, Haifa 32000, Israel
&
Leib ReznikIsrael Electric Corp. Ltd.Department of Nuclear Engineering, Haifa, Israel
Pages 261-282 | Published online: 10 May 2017

References

  • M. H. WOOD, “Deformation and Rupture of Fast Reactor Fuel Pin Cladding,” Br. J. Nucl. Energy, 22, 3 (1983).
  • H. NICKEL, T. KONDO, and P. H. RITTEN-HOUSE, “Status of Metallic Materials Development for Application in Advanced High-Temperature Gas-Cooled Reactors,” J. Nucl. Technol., 66, 12 (July 1984).
  • “Class 1 Components in Elevated Temperature Service, Division 1,” ASME Code Case N-47-17, American Society of Mechanical Engineers (1979).
  • ASME Boiler and Pressure Vessel Code, Sec. III, Part NB and Appendix 6, American Society of Mechanical Engineers (1977).
  • P. T. HUGHES and D. C. ALLEN, “High-Temperature Structural Engineering Data Needs,” J. Nucl. Technol., 66, 661 (Sep. 1984).
  • F. SHUBERT et al., “Creep Rupture Behaviour of Candidate Materials for Nuclear Process Heat Applications,” J. Nucl. Technol., 66, 227 (Aug. 1984).
  • S. S. MANSON and C. R. ENSIGN, “A Quarter-Century of Progress in the Development of Correlation and Extrapolation Methods for Creep-Rupture Data,” J. Eng. Mater. Technol., 101, 317 (1979).
  • F. R. LARSON and J. MILLER, “A Time-Temperature Relationship for Rupture and Creep Stress,” Trans. ASME, 74, 765 (1952).
  • L. R. ORR, O. W. SHERBY, and J. E. DORN, “Correlation of Rupture Data for Metals at Elevated Temperature,” Trans. ASME, 76, 113 (1954).
  • S. S. MANSON and A. M. HAFERD, “A Linear Time-Temperature Parameter Relation for Extrapolation of Creep and Stress Rupture Data,” NACA TN-2890, National Advisory Committee for Aeronautics (1959).
  • R. M. GOLDHOFF, Time-Temperature Parameters in Metals Handbook, 9th ed., Vol. 3, p. 237, American Society for Metals (1980).
  • W. E. WHITE and I. LE MAY, “On the Minimum Commitment Method for Correlation of Creep Rupture Data,” J. Eng. Mater. Technol., 100, 333 (1978).
  • S. S. MANSON and C. R. ENSIGN, “A Specialized Model Analysis of Creep Rupture Data by the Minimum-Commitment, Station-Function Approach,” NACA TMX-52999, National Advisory Committee for Aeronautics (Mar. 1971).
  • H. J. PENKALLA et al., “Design Values of Inconel 617 for High Temperature Reactors Operating at Temperatures Above 800°C,” J. Nucl. Eng. Design, 83, 397 (1984).
  • J. M. CORUM et al., “Interim Guidelines for Details of Inelastic Analysis of High Temperature Reactor System Components,” ORNL-5014, Oak Ridge National Laboratory (1974).
  • B. BOOKER et al., “New Constitutive Equations to Describe Infinitesimal Elastic-Plastic Deformation,” ASME 82 TVP-71, American Society of Mechanical Engineers (1982).
  • D. KUJAWSKI and Z. MROZ, “A Viscoplastic Model and Its Application to Cyclic Loading,” Acta Mechanica, 36 (1980).
  • E. KREMPL and E. P. CERNOCKY, “A Theory of Viscoplasticity Based on Infinitesimal Total Strain,” Acta Mechanica, 36 (1980).
  • F. K. G. ODQUIST, Mathematical Theory of Creep and Creep Rupture, Oxford Mathematical Monograph (1965).
  • H. J. PENKALLA, “Constitutive Equations for the Description of Creep and Creep Behavior of Metallic Materials at Temperatures Above 800°C,” J. Nucl. Technol., 66, 685 (Sep. 1984).
  • D. R. OLANDER, “Fundamental Aspects of Nuclear Reactor Fuel Elements,” Technical Information Center, Office of Public Affairs, Energy Research and Development Administration (1976).
  • M. F. ASHBY, “First Report on Deformation-Mechanism Maps,” Acta Metall., 20, 887 (1972).
  • C. GANDHI and M. F. ASHBY, “Fracture-Mechanism Maps for Materials Which Cleave: FCC, BCC and HCP Metals and Ceramics,” Acta Metall., 27, 1565 (1979).
  • R. J. FIELDS et al., “Fracture Mechanisms in Pure Iron, Two Austentic Steels and One Ferritic Steel,” Metall. Trans. A, 11a, 333 (1980).
  • R. BULLOUGH and M. H. WOOD, “Mechanisms of Radiation-Induced Creep and Growth,” J. Nucl. Mater., 90, 1 (1980).
  • L. K. MANSUR, “Irradiation Creep by Climb-Enabled Glide of Dislocations Resulting from Preferred Absorption of Point Defects,” Philos. Mag., A39, 497 (1979).
  • S. TAKEUCHI and A. S. ARGON, “Steady-State Creep of Single-Phase Crystalline Matter at High Temperature,” J. Mater. Sci., 11, 1542 (1976).
  • I. W. CHEN, “Mechanisms of Cavity Growth in Creep,” Scr. Metallica, 17, 17 (1983).
  • J. R. MATTHEWS, Proc. Int. Conf. Irradiation Behaviour of Metallic Materials for Fast Reactor Core Components, Ajaccio, France, June 4, 1979, p. 273.
  • F. H. MORTON, Creep of Steel at High Temperature, McGraw-Hill Book Company, Inc., New York (1938).
  • L. PRANDTL, “Ein Gedankenmodell zur Kinetischen Theorie der Festen Körper,” Zamm, 8, 85 (1928).
  • L. M. KACHANOV, “Time of the Rupture Process Under Creep Conditions,” Izv. Akad. Nauk SSSR, Otd. Tekh. Nauk, 8, 26 (1958).
  • J. LEMAITRE, “Damage Modelling for Prediction of Plastic or Creep Fatigue Failure in Structures,” Proc. 5th Int. Conf. Structural Mechanics in Reactor Technology, Berlin, March 20, 1979, CONF-790370, paper L5/lb, North-Holland, Amsterdam (1979).
  • Y. N. RABOTNOV, “Creep Rupture,” Proc. 12th Int. Congress Applied Mechanics, Stanford, California, August 26-31, 1968.
  • A. PLUMTREE, “Application of Damage Concepts to Predict Creep-Fatigue Failures,” Proc. Conf. Engineering Aspects of Creep, Sheffield, U.K., September 15-19, 1980, Vol. 1, p. 103, Institute of Mechanical Engineers.
  • F. DOBES and K. MILICKA, “Correlation Between Minimum Creep Rate and Time to Fracture,” Met. Sci., 10, 382 (1976).
  • E. L. ROBINSON, “Effect of Temperature Variation on the Long Time Rupture Strength of Steels,” Trans. ASME, 74, 777 (1952).
  • T. BUI-QUOC et al., “Cumulative Damage Under Stress Controlled Conditions,” ASME J. Basic Eng., 93, 691 (1971).
  • T. BUI-QUOC and A. BIRON, “Predictions of Creep Behaviour of Some Stainless Steels on the Basis of Short-Term Tensile Properties,” Proc. 5th Int. Conf. Structural Mechanics in Reactor Technology, Berlin, March 20, 1979, CONF-790370 paper L5/1, North-Holland, Amsterdam (1979).
  • T. BUI-QUOC, “An Engineering Approach for Cumulative Damage in Metals Under Creep Loading,” ASME J. Eng. Mater. Technol., 101, 337 (1979).
  • T. BUI-QUOC, “Evaluation of Creep-Rupture Data Using a New Approach,” Proc. 6th Int. Conf. Structural Mechanics in Reactor Technology, Paris, August 17-21, 1981, paper L7/4.
  • J. L. CHABOCHE, “Description thermodynamique et phenomenologique de la viscoplasticité cyclique avec endommagement,” Thesis, Université P. et M. Curie, Paris (June 1978).
  • M. CHRZANOWSKI, “Use of the Damage Concept in Describing Creep-Fatigue Interaction Under Prescribed Stress,” Int. J. Mec. Soc., 18, 69 (1976).
  • J. HULT, CDM-Capabilities, Limitations and Promises, Mechanics of Deformation and Fracture, p. 233, Pergamon Press, Oxford (1979).
  • J. LEMAITRE and J.-L. CHABOCHE, “Aspect phenomenologique de la rupture par endommagement,” J. Mechan. Appl., 2, 3, 317 (1978).
  • J.-L. CHABOCHE, “The Continuous Damage Mechanics: A Tool to Describe Phenomena Before Crack Initiation,” Proc. 2nd Int. Seminar Inelastic Analysis and Life Prediction in High Temperature Environments, Berlin, August 20-21, 1979, paper C-9.
  • S. MURAKAMI, “Continuum Damage Mechanics in High Temperature Structures: Elaboration of Classical Damage Theory,” Proc. 3rd Int. Seminar Inelastic Analysis and Life Prediction in High Temperature Environment (Post Conference Seminar of SMIRT-6), paper B2.2, Paris, August 17-21, 1981.
  • S. MURAKAMI, “Notion of Continuum Damage Mechanics and Its Application to Anisotropic Creep Damage Theory,” ASME J. Eng. Mater. Technol., 105, 99 (Apr. 1983).
  • J.-L. CHABOCHE, “Anisotropic Creep Damage in the Framework of Continuum Damage Mechanics,” Proc. 7th Int. Conf. Structural Mechanics in Reactor Technology, Chicago, Illinois, August 22-26, 1983, paper L1/1.
  • S. MURAKAMI and N. OHNO, “A Continuum Theory of Creep and Creep-Damage,” Proc. 3rd IUTAM Symp. Creep in Structures, Leicester, U.K. (1980).
  • J. W. DOUGILL, “Some Remarks on Path Independence in the Small in Plasticity,” Quart. Appl. Math., 33, 233 (1975).
  • D. KRAJCINOVIC, “Continuous Damage Mechanics: Theory and Application,” Proc. 7th Int. Conf. Structural Mechanics in Reactor Technology, Chicago, Illinois, August 22-26, 1983, paper Ll/2.
  • D. KRAJCINOVIC and M. A. G. SILVA, “Statistical Aspects of the Continuum Damage Theory,” Int. J. Solids Struct., 18, 551 (1982).
  • E. TREFFTZ, Mechanik der Elastischen Körper, im Handbuch der Physik, Band VI, Redigiert von R. Cram-mel, Berlin (1928).
  • H. B. CALLEN and T. A. WELTON, “Irreversibility and Generalized Noise,” Phys. Rev., 83, 34 (1951).
  • J. MATHEWS and R. L. WALKER, Mathematical Methods of Physics, Benjamin Press, New York (1964).
  • D. INGMAN and L. REZNIK, “A Dynamic Model for Element Reliability,” J. Nucl. Eng. Design, 70, 209 (1982).
  • V. K. SIKKA et al., “Relationships Between Short and Long Term Mechanical Properties of Several Austentic Stainless Steels,” Characterization of Materials for Service at Elevated Temperatures, p. 51, American Society of Mechanical Engineers (1978).
  • M. M. PAXTON, “Mechanical Properties of Prototype FTR Cladding-20% C.W. Type 316 Stainless Steel Tubing,” HEDL-TME 71-59, Hanford Engineering Development Laboratory (1971).
  • J. L. STRAALSUND et al., “Correlation of Transient-Test Data with Conventional Mechanical Properties Data,” J. Nucl. Technol., 25, 531 (Mar. 1975).
  • K. V. MOORE et al., “RETRAN-A Program for One-Dimensional Transient Thermal-Hydraulic Analysis of Complex Fluid Flow Systems,” EPRI CCM-5, Vols. 1-4, Electric Power Research Institute (Dec. 1978).

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