13th International Conference on Fracture June 16–21, 2013, Beijing, China -12- 13. R6, Assessment of the integrity of structures containing defects, Revision 3, British Energy Generation, 2000. 14. API RP 579, ‘Standardized fitness-for-service assessment techniques for pressurized equipment used in the petroleum industry’, API, 2004. 15. AFCEN, “Design and construction rules for mechanical components of FBR nuclear islands,” RCC-MR, Appendix A16, AFCEN, Paris.,1985 16. Webster, G.A. and Ainsworth R.A., ‘High temperature components life assessment’ Chapman and Hall, London, 1994. 17. Saxena, A. ‘Non-linear fracture mechanics for engineers’ CRC Press, Boca Raton, USA, 1998. 18. Nikbin, K.M., Smith, D.J. and Webster, G.A., 'Prediction of creep crack growth from uni-axial creep data', Proc. Roy. Soc. A.396, 1984, 183-197. 19. Nikbin, K.M., Smith, D.J. and Webster, G.A., 'An engineering approach to the prediction of creep crack growth', J. Eng. Mat. and Tech., Trans ASME, 108, 1986, 186-191. 20. Nikbin, K., ‘A unified European approach to high temperature defect assessment code and its incorporation in a knowledge base system’, Int. J. PVP, (2001) pp. 929-935. 21. Webster, G. A, Nikbin, K. M., Chorlton, M. R., Célard, N. J. C. and Ober, M. ‘Comparison of High Temperature Defect Assessments Methods’; Material at High Temperature; Vol. 15: pp. 337-346, 1998. 22. Davies, C. M., Kourmpetis, M., O'Dowd, N. P. and Nikbin, K. M., ‘Experimental Evaluation of the J or C* Parameter for a Range of Cracked Geometries’ published in ASTM STP 1480, 2006. 23. Davies, C. M., Mueller, F., Nikbin, K. M., O'Dowd, N. P. and Webster, G. A., ‘Analysis of Creep Crack Initiation and Growth in Different Geometries for 316H and Carbon Manganese Steels’, to be published in ASTM STP 1480, 2006. 24. Tan, M., Célard, N. J. C., Nikbin, K. M and Webster, G. A., ‘Comparison of Creep Crack Initiation and Growth in Four Steels Tested in HIDA’, International Journal of Pressure Vessels and Piping, 2001, 78(12), pp. 737-747. 25. ASTM E647-99, ‘Standard test method for measurement of fatigue crack growth rates’, ASTM 2000, 03-01, 591-630. 26. Winstone, M.R., Nikbin, K.M. and Webster, G.A., ‘Modes of failure under creep/fatigue loading of a nickel-based superalloy’, J. Mat. Sci., 20, 1985, 2471-2476. 27. Raju, I. S. and Newman, J. C. ‘Stress-Intensity Factors for Internal and External Surface Cracks in Cylindrical Vessels’; Journal of Pressure Vessel Technology; Vol. 104: pp. 293-298, 1982. 28. Wasmer, K., Nikbin, K. M., Webster, G. A., “Sensitivity of Creep Crack Initiation and Growth in Plates to Material Properties Variations”, Fatigue and Fracture Mechanics, ASTM STP 1461, Vol: 34, S. R. Daniewicz, J. C. Newman and K.-H. Schwalbe, Eds., ASTM International, West Conshohocken, PA, 2004. 29. ASTM E 2670-10, 20110 “Standard Test Method for Measurement of Creep/fatigue Crack Growth Rates in Metals”, ASTM Standards 03.01.
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