高温プラント機器の構造健全性評価に関する最近の動向

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Published in日本機械学会論文集A編 Vol. 77; no. 780; pp. 1156 - 1168
Main Author 高橋, 由紀夫
Format Journal Article
LanguageJapanese
Published 一般社団法人 日本機械学会 2011
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ISSN1884-8338
DOI10.1299/kikaia.77.1156

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Author 高橋, 由紀夫
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References (8) Takahashi, Y. and Tabuchi, M., “Evaluation of creep strength reduction factors for welded joints of Grade 122 steel”, Journal of Pressure Vessel Technology, Vol. 133 (2011), paper No. 21401.
(9) Tabuchi, M and Takahashi, Y., “Evaluation of creep strength reduction factors for welded joints of modified 9Cr-1Mo steel”, Proc. PVP2006, (2006), ASME Paper No. PVP2006-ICPVT11-93350.
(18) 日本機械学会, “発電用原子力設備規格 設計・建設規格 第II編: 高速炉規格”, (2009) JSME S NC2-2009.
(19) Manson, S. S., “A challenge to unify treatment of high temperature fatigue - a patisan proposal based on strain range partitioning in fatigue at elevated temperatures”, Fatigue at Elevated Temperatures, ASTM STP 520, (1973), pp. 744-775.
(15) 高橋由紀夫, “環状切欠き試験片による耐熱鋼の多軸クリープ破壊挙動の評価”, 電力中央研究所研究報告:Q09031 (2011).
(25) Takahashi, Y., Dogan, B. Gandy, D., “Systematic evaluation of creep-fatigue life prediction methods for various alloys“, Proceedings of PVP2009, (2009), PVP2009-77990.
(6) American Society of Mechanical Engineers, Boiler and Pressure Vessel Code, Section I -Rules for Construction of Power Boilers (2010).
(30) Takahashi, Y., “Study on creep-fatigue evaluation procedures for high-chromium steels— Part II: Sensitivity to calculated deformation”, International Journal of Pressure Vessels and Piping, Vol. 85 (2008), pp. 423-440.
(11) Hayhurst, D.R., “Creep rupture under multiaxial states of stress”, Journal of Mechanics and Physics of Solids, Vol. 20 (1972), pp. 381-390.
(7) American Society of Mechanical Engineers, B31.1 - 2010 Power Piping (2010).
(27) Spindler, M.W., Payton, W.M., “Advanced Ductility Exhaustion Methods for the Calculation of Creep Damage During Creep-Fatigue Cycling”, ASTM STP, (2011) to appear.
(24) Takahashi, Y., “Study on creep-fatigue evaluation procedures for high-chromium steels-Part I: Test results and life prediction based on measured stress relaxation”, International Journal of Pressure Vessels and Piping, Vol. 85 (2008), pp. 406-422.
(1) Maruyama, K. and Yoshimi, K., “Methodology of creep data analysis for advanced high Cr ferritic steels”, Proc. 8th International Conference on Creep and Fatigue at Elevated Temperatures, CREEP2007-26150, (2007), pp. 631-636
(5) Bendick, W., Cipolla, L., Gabrel, J. and Hald, J., “New ECCC assessment of creep rupture strength for steel Grade X10CrMoVNb9-1 (Grade 91)”, Proc. ECCC Creep Conference, (2009), pp. 56-67.
(22) Hales, R., 1983, “A Method of Creep Damage Summation Based on Accumulated Strain for the Assessment of Creep-Fatigue Endurance,” Fatigue of Engineering Materials and Structures, Vol. 6, No. 2 (1083), pp. 121 -135.
(26) 高橋由紀夫, “クリープ特性に対する繰返し変形の影響とこれを考慮したクリープ疲労寿命予測”, 電力中央研究所研究報告:Q08017 (2008).
(21) Priest, R. H., and Ellison, E. G., 1980, “A Combined Deformation Map- Ductility Exhaustion Approach to Creep-Fatigue Analysis,” Material Science and Engineering, Vol. 49 (1980), pp. 7-15.
(12) Rice, J.R. and Tracey, D.M., “On the ductile enlargement of voids in triaxial stress fields”, Journal of Mechanics and Physics of Solids, Vol. 17 (1969), pp.201-217.
(4) Holdsworth, S.R., “Advances in the assessment of creep data”, Proceedings of 9th Liege Conference : Materials for Advanced Power Engineering 2010, (2010), pp. 946-947.
(29) 高橋由紀夫, “クリープ疲労相互作用下での改良9Cr-1Mo鋼に対する非弾性解析と寿命予測の高度化”, 電力中央研究所研究報告:Q09031 (2010).
(10) Goodall, I.W., Skelton, R.P., “The importance of multi-axial stress in creep deformation and rupture”, Fatigue and Fracture of Engineering Materials and Structures, Vol. 27 (2004), pp. 267-272.
(17) afcen, RCC-MR, (2007).
(16) American Society of Mechanical Engineers, Boiler and Pressure Vessel Code, Section III, subsection-NH (2010).
(13) Cocks, A.C.F. and Ashby, M.F., “Intergranular fracture during power-law creep under multiaxial stress”, Metal Science, Vol. 14 (1980), pp.395-402.
(20) British Energy, “Assessment procedure for the high temperature response of structures”, R5 Issue 3 (2003).
(28) Takahashi, Y. and Tabuchi, M., “Creep and creep-fatigue behavior of high chromium steel weldment”, Acta Metallurgica. Sinica (English Letter), Vol.24, No.3 (2011) to appear.
(23) Takahashi, Y., Shibamoto, H. and Inoue, K. “Study on Creep-Fatigue Life Prediction Methods for Low-Carbon Nitrogen-Controlled 316 Stainless Steel (316FR)”, Nuclear Engineering and Design, Vol. 238 (2008), pp. 322-335.
(2) 木村一弘,九島秀昭,阿部富士雄,”応力―破断時間曲線の領域分割法による高Crフェライト耐熱鋼のクリープ寿命予測の高度化”,材料,Vol. 52, No. 1 (2003), pp. 57-62.
(3) Kimura, K., “Assessment of long-term creep strength and review of allowable stress of high Cr Ferritic creep resistant steels”, Proceedings of PVP2005, CREEP2005-71039 (2007).
(14) Spindler, M.W., “The multiaxial creep ductility of austenitic stainless steels”, Fatigue and Fracture of Engineering Materials and Structures, Vol. 27 (2004), pp. 273-281.
References_xml – reference: (17) afcen, RCC-MR, (2007).
– reference: (13) Cocks, A.C.F. and Ashby, M.F., “Intergranular fracture during power-law creep under multiaxial stress”, Metal Science, Vol. 14 (1980), pp.395-402.
– reference: (21) Priest, R. H., and Ellison, E. G., 1980, “A Combined Deformation Map- Ductility Exhaustion Approach to Creep-Fatigue Analysis,” Material Science and Engineering, Vol. 49 (1980), pp. 7-15.
– reference: (19) Manson, S. S., “A challenge to unify treatment of high temperature fatigue - a patisan proposal based on strain range partitioning in fatigue at elevated temperatures”, Fatigue at Elevated Temperatures, ASTM STP 520, (1973), pp. 744-775.
– reference: (10) Goodall, I.W., Skelton, R.P., “The importance of multi-axial stress in creep deformation and rupture”, Fatigue and Fracture of Engineering Materials and Structures, Vol. 27 (2004), pp. 267-272.
– reference: (2) 木村一弘,九島秀昭,阿部富士雄,”応力―破断時間曲線の領域分割法による高Crフェライト耐熱鋼のクリープ寿命予測の高度化”,材料,Vol. 52, No. 1 (2003), pp. 57-62.
– reference: (11) Hayhurst, D.R., “Creep rupture under multiaxial states of stress”, Journal of Mechanics and Physics of Solids, Vol. 20 (1972), pp. 381-390.
– reference: (4) Holdsworth, S.R., “Advances in the assessment of creep data”, Proceedings of 9th Liege Conference : Materials for Advanced Power Engineering 2010, (2010), pp. 946-947.
– reference: (24) Takahashi, Y., “Study on creep-fatigue evaluation procedures for high-chromium steels-Part I: Test results and life prediction based on measured stress relaxation”, International Journal of Pressure Vessels and Piping, Vol. 85 (2008), pp. 406-422.
– reference: (7) American Society of Mechanical Engineers, B31.1 - 2010 Power Piping (2010).
– reference: (28) Takahashi, Y. and Tabuchi, M., “Creep and creep-fatigue behavior of high chromium steel weldment”, Acta Metallurgica. Sinica (English Letter), Vol.24, No.3 (2011) to appear.
– reference: (9) Tabuchi, M and Takahashi, Y., “Evaluation of creep strength reduction factors for welded joints of modified 9Cr-1Mo steel”, Proc. PVP2006, (2006), ASME Paper No. PVP2006-ICPVT11-93350.
– reference: (14) Spindler, M.W., “The multiaxial creep ductility of austenitic stainless steels”, Fatigue and Fracture of Engineering Materials and Structures, Vol. 27 (2004), pp. 273-281.
– reference: (12) Rice, J.R. and Tracey, D.M., “On the ductile enlargement of voids in triaxial stress fields”, Journal of Mechanics and Physics of Solids, Vol. 17 (1969), pp.201-217.
– reference: (20) British Energy, “Assessment procedure for the high temperature response of structures”, R5 Issue 3 (2003).
– reference: (16) American Society of Mechanical Engineers, Boiler and Pressure Vessel Code, Section III, subsection-NH (2010).
– reference: (30) Takahashi, Y., “Study on creep-fatigue evaluation procedures for high-chromium steels— Part II: Sensitivity to calculated deformation”, International Journal of Pressure Vessels and Piping, Vol. 85 (2008), pp. 423-440.
– reference: (27) Spindler, M.W., Payton, W.M., “Advanced Ductility Exhaustion Methods for the Calculation of Creep Damage During Creep-Fatigue Cycling”, ASTM STP, (2011) to appear.
– reference: (25) Takahashi, Y., Dogan, B. Gandy, D., “Systematic evaluation of creep-fatigue life prediction methods for various alloys“, Proceedings of PVP2009, (2009), PVP2009-77990.
– reference: (18) 日本機械学会, “発電用原子力設備規格 設計・建設規格 第II編: 高速炉規格”, (2009) JSME S NC2-2009.
– reference: (29) 高橋由紀夫, “クリープ疲労相互作用下での改良9Cr-1Mo鋼に対する非弾性解析と寿命予測の高度化”, 電力中央研究所研究報告:Q09031 (2010).
– reference: (6) American Society of Mechanical Engineers, Boiler and Pressure Vessel Code, Section I -Rules for Construction of Power Boilers (2010).
– reference: (3) Kimura, K., “Assessment of long-term creep strength and review of allowable stress of high Cr Ferritic creep resistant steels”, Proceedings of PVP2005, CREEP2005-71039 (2007).
– reference: (1) Maruyama, K. and Yoshimi, K., “Methodology of creep data analysis for advanced high Cr ferritic steels”, Proc. 8th International Conference on Creep and Fatigue at Elevated Temperatures, CREEP2007-26150, (2007), pp. 631-636
– reference: (8) Takahashi, Y. and Tabuchi, M., “Evaluation of creep strength reduction factors for welded joints of Grade 122 steel”, Journal of Pressure Vessel Technology, Vol. 133 (2011), paper No. 21401.
– reference: (23) Takahashi, Y., Shibamoto, H. and Inoue, K. “Study on Creep-Fatigue Life Prediction Methods for Low-Carbon Nitrogen-Controlled 316 Stainless Steel (316FR)”, Nuclear Engineering and Design, Vol. 238 (2008), pp. 322-335.
– reference: (15) 高橋由紀夫, “環状切欠き試験片による耐熱鋼の多軸クリープ破壊挙動の評価”, 電力中央研究所研究報告:Q09031 (2011).
– reference: (26) 高橋由紀夫, “クリープ特性に対する繰返し変形の影響とこれを考慮したクリープ疲労寿命予測”, 電力中央研究所研究報告:Q08017 (2008).
– reference: (5) Bendick, W., Cipolla, L., Gabrel, J. and Hald, J., “New ECCC assessment of creep rupture strength for steel Grade X10CrMoVNb9-1 (Grade 91)”, Proc. ECCC Creep Conference, (2009), pp. 56-67.
– reference: (22) Hales, R., 1983, “A Method of Creep Damage Summation Based on Accumulated Strain for the Assessment of Creep-Fatigue Endurance,” Fatigue of Engineering Materials and Structures, Vol. 6, No. 2 (1083), pp. 121 -135.
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