References
- C. EDELEANU, Ed., Materials Technology in Steam Reforming Process, Pergamon Press Ltd. (1966).
- Stahl-Eisen-Werkstoffblatt, No. 595, “Stahlguß für Erdöl- und Erdgasanlagen,” 2. Auslage (1976); see also Stahl-Eisen-Werkstoffblatt, No. 670, “Hochwarmfeste Stähle,” 1. Ausgabe (1969); see also Stahl-Eisen-Werkstoffblatt, No. 675, “Nahtlose Rohre aus hochwarmfesten Stählen,” 1. Ausgabe (1969).
- W. F. SIMMONS, “Compilation of Chemical Compositions and Creep Rupture Strength of Superalloys,” ASTM Data Series Publication No. DS 9 D, American Society for Testing and Materials (1968).
- K. E. VOLZ, Nickel und Nickellegierungen, Springer Verlag, Heidelberg (1970).
- C. T. SIMS and W. C. HAGEL, Ed., The Superalloys, John Wiley & Sons, New York (1972).
- F. SCHUBERT, U. BRUCH, R. COOK, H. DIEHL, H. teHEESEN, G. ULLRICH and H. WEBER, Schriftenreihe “Energiepolitik in Nordrhein-Westfalen,” Chap. 14, p. 134, “Zietstandverhalten” in “Metallische Werkstoffe für die wärmetauschenden Komponenten und hochbelasteten Einbauten von Hochtemperaturreaktoren zur Erzeugung nuklearer Prozeßwärme,” Der Minister für Wirtschaft, Mittelstand und Verkehr des Landes Nordrhein-Westfalen (Jan. 1982).
- T. KONDO, “Development and Testing of Alloys for Primary Circuit Structures of a VHTR,” Proc. IAEA Specialists’ Mtg. High Temperature Metallic Materials for Application in Gas-Cooled Reactors, Vienna, May 4–6, 1981, OEFZS Report 4086, International Atomic Energy Agency (1981).
- D. I. ROBERTS, “Current Status of Studies of Materials for the HTGR at General Atomic Company,” Proc. IAEA Specialists’ Mtg. High Temperature Metallic Materials for Application in Gas-Cooled Reactors, Vienna, May 4–6, 1981, OEFZS Report 4086, International Atomic Energy Agency (1981).
- F. SCHUBERT, H. J. PENKALLA and G. ULLRICH, “Creep-Rupture Behaviour, A Criterion for the Design of Metallic HTR Components with High Application Temperatures,” Proc. IAEA Specialists’ Mtg. High Temperature Metallic Materials for Application in Gas-Cooled Reactors, Vienna, May 4–6, 1981, OEFZS Report 4086, International Atomic Energy Agency (1981).
- J. GRANACHER, “Zeitstandverhalten von hitzebeständigen Werkstoffen für Ofeneinbauten der Erdölchemie,” Arch. Eisenhüttenwesen, 47, 745 (1976).
- W. THIESSEN and B. POWELEIT, “Der Einfluß von Niob auf die Zeitstandfestigkeit von Schleudergußlegierungen mit 25% Chrom und 20% Nickel,” Z. f. Werkstofftechnik, p. 155 (1974).
- “Alloy IN-519 Cast Chromium-Nickel-Niobium Heat-Resisting Steel: Engineering Properties,” Inco Ltd. Publication No. 4383, 1976; see also “Pyrotherm; Hochhitz-beständige Legierungen für den Industrie-Ofenbau,” Posé-Marré Publication (May 1975); see also “Advanced Gas-Cooled Nuclear Reactor Materials Evaluation and Development Program,” Progress Report, COO-2975-28, General Electric Company (1979).
- “Manaurite 36X File,” Acièries du Manoir Pompey (Mar. 1975).
- “HASTELLOY Alloy S,” F-30, 489B, Cabot Stellite Division (1972).
- M. KIYOSHIGE, H. MURASE, J. FUJIOKA, S. SHIMIZU and K. SATOH, “Creep Properties of HASTELLOY X and Their Application to the Structural Design,” Trans. Iron and Steel Institute of Japan, 18, 397 (1978).
- S. SHIMIZU, K. SATOH, S. HAYASHI, M. KIYOSHIGE, H. MURASE and J. FUJIOKA, “Effects of High Temperature Environment on Creep,” Proc. 2nd U.S.-Japan Seminar on HTGR Safety Technology, Brookhaven National Laboratory, September 15–17, 1977, BNL-NUREG-50689, Brookhaven National Laboratory (1978).
- T. UDOGUCHI, Y. ASADA and K. KOBATAKE, “Steady and Cyclic Internal Pressure Creep of HASTELLOY X Tubular Specimens at 800°C to 1000°C,” Proc. 6th Int. Symp. Structural Mechanics in Reactor Technology, Paris, August 17–21, 1981, North Holland Publishing Company, Amsterdam (1981).
- “HASTELLOY Alloy X,” F-30, 037 G, Cabot Stellite Division (1974); see also Aerospace Structural Materials Handbook (1967); see also S. YOKOI, Y. MONMA, T. KONDO, Y. OGAWA and Y. KURATA, “Study of Creep and Rupture Behavior for HASTELLOY Alloy XR,” JAERI-M 83-138, Japan Atomic Energy Research Institute (Sep. 1983).
- KITAGAWAgroup> et al., “Some Problems in Development of the HT Design Code,” Proc. Symp. Elevated Temperature Design, Mexico City, September 1976, American Society of Mechanical Engineers (1976).
- “INCONEL Alloy 617,” GE Progress Report COO-2975-28, General Electric Company (1979); see also T-2406, Huntington Alloys (1978) and (1979).
- “NIMONIC Alloy 86,” Publication No. 3687, Henry Wiggin and Co. Ltd. (1976).
- “Alloy 800,” Proc. Petten Int. Conf. Alloy 800, March 14–16, 1978, W. BETTERIDGE, R. KREFELD, H. KRÖ-KEL, S. J. LLOYD, M. Van der VOORDE and C. VIVANTE, Eds., North-Holland Publishing Company, Amsterdam (1979).
- R. H. MOELLER, “INCOLOY Alloy 800, Data for Use in Design of Gas Cooled and Liquid Metals Fast Breeder Reactors,” Huntington Alloys (1975).
- ASME Boiler and Pressure Vessel Code, Section III, Case N 47-17, American Society of Mechanical Engineers (1980).
- “ISO Recommendation for Determining the 100 000 h Stress Rupture Life,” ISO/TC 17/WG 10/ETP-SG (Sekre-tariat-51) ffl58, International Organization for Standardization, Geneva (1971).
- J. R. KING, H. E. McCOY and P. L. RITTENHOUSE, “Weldability Evaluation and Weldments Properties of HASTELLOY X,” Proc. Specialists’ Mtg. High Temperature Metallic Materials for Application in Gas-Cooled Reactors, Vienna, May 4–6, 1981, OEFZS Report 4086, International Atomic Energy Agency (1981).
- F. R. LARSON and J. MILLER, “A Time-Temperature Relationship for Rupture and Creep Stress,” Trans. ASME, 74, 765 (1952).
- L. R. ORR, O. D. SHERBY and J. E. DORN, “Correlations of Rupture Data for Metals at Elevated Temperatures,” Trans. ASME, 76, 113 (1954).
- S. S. MANSON and A. M. HAFERD, “A Linear Time-Temperature Relation for Extrapolation of Creep and Stress-Rupture Data,” NACA TN 2890, National Advisory Committee for Aeronautics (1959).
- R. M. GOLDHOFF, “Towards the Standardization of Time-Temperature Parameter Usage in Elevated Temperature Data Analysis,” J. Test. Eval., 2, 387 (1974).