References
- Y. MISHIMA et al., “Thermal Deformation of UO2 Pellets in a Thin-Walled, Narrow-Gap Fuel Pin,” Trans. Am. Nucl. Soc., 20, 222 (1975).
- J. VEEDER, “Thermo-Elastic Expansion of Finite Cylinders,” AECL-2660, Atomic Energy of Canada, Ltd. (1967).
- S. HARRIAGUE and J. E. MEYER, “A Study of Friction and Axial Effects in Pellet-Clad Mechanical Interaction,” in Water Reactor Fuel Element Performance Computer Modelling, JOHN GITTUS, Ed., Applied Science Publishers (1983).
- M. UCHIDA and M. ICHIKAWA, “In-Pile Diameter Measurement of Light Water Reactor Test Fuel Rods for Assessment of Pellet/Cladding Mechanical Interaction,” Nucl. Technol., 51, 33 (1980).
- R. E. WILLIFORD, D. D. LANNING and C. L. MOHR, “A Model for the Effective Thermal and Mechanical Properties of Cracked UO2 Pellets,” Nucl. Technol., 56, 340 (1982).
- R. E. WILLIFORD et al., “The Analysis of Fuel Relocation for the NRC/PNL Halden Assemblies IFA-431, IFA-432, and IFA-513,” NUREG/CR-0588, PNL-2709, Pacific Northwest Laboratory (1980).
- D. CUBICCIOTTI et al., “Stress Corrosion Cracking of Zircaloys,” EPRI NP-1329, p. 5.16, Electric Power Research Institute (1980).
- R. E. WILLIFORD and D. D. LANNING, “Cracked Fuel Mechanics,” in Water Reactor Fuel Element Performance Computer Modelling, JOHN GITTUS, Ed., Applied Science Publishers (1983).
- R. E. WILLIFORD, “Experimental Verification of a Cracked Fuel Mechanical Model,” NUREG/CR-2872, PNL-4377, Pacific Northwest Laboratory (1982).
- K. ITO et al., “Pellet Compliance Model Based on Out-of-Pile Simulation,” Nucl. Eng. Des., 56, 117 (1980).
- B. B. MIKIC, “Thermal Contact Conductance: Theoretical Considerations,” Int. J. Heat Mass Transfer, 17, 205 (1974).
- D. R. OLANDER, “Fundamental Aspects of Nuclear Reactor Fuel Elements,” TID-26711-P1, pp. 336–338, U.S. Atomic Energy Commission (1976).
- S. P. TIMOSHENKO and J. N. GOODIER, Theory of Elasticity, 3rd ed., pp. 284–288 and 433–438, McGraw-Hill Book Company (1970).
- M. NAKATSUKA, “Theoretical and Experimental Analyses of Cladding Strain Produced by Expansion of Cracked Fuel Pellets,” Nucl. Eng. Des., 65, 197 (1981).
- S. P. TIMOSHENKO and S. WOINOWSKY-KRIEGER, Theory of Plates and Shells, 2nd ed., pp. 471–481, McGraw-Hill Book Company (1959).
- R. BECKET and J. HURT, Numerical Calculations and Algorithms, pp. 57–62, McGraw-Hill Book Company (1967).
- L. A. WALTON and D. L. HUSSER, “Fuel Pellet Fracture and Relocation,” paper presented at the IAEA Fuel Modeler’s Conference, Preston, U.K., March 15–19, 1982.
- D. L. HAGRMAN et al., “MATPRO-Version 11 (Revision 2): A Handbook of Materials Properties for Use in the Analyses of Light Water Reactor Fuel Rod Behavior,” NUREG/CR-0497, EG&G Idaho, Inc. (1981).
- I. D. PEGGS and D. P. GODIN, “The Yield Strength-Hot Hardness Relationship of Zircaloy-4,” J. Nucl. Mater., 57, 246 (1975).
- C. NEALLEY et al., “Post-Irradiation Data Analysis for NRC/PNL Halden Assembly IFA-431,” NUREG/CR-0797, PNL-2975, Pacific Northwest Laboratory (1979).
- M. GARTNER and J. C. LaVAKE, “Power Ramp Testing and Nondestructive Postirradiation Examinations of High Burnup PWR Fuel Rods,” paper presented at the IAEA Specialists’ Meeting on Pellet/Cladding Interaction, Seattle, Washington, October 1–3, 1983.