참고문헌 (21)

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2. 間野 日出男, 近藤 覚, 井村 徹, 松室 昭仁. ショットピーニングによって生成したナノ結晶相の疲労強度に及ぼす影響. 日本金屬學會誌 = Journal of the Japan Institute of Metals and Materials, vol.69, no.2, 213-216.

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4. Takahashi, Koji, Amano, Toshihiko, Ando, Kotoji, Takahashi, Fumio. Improvement of fatigue limit by shot peening for high‐strength steel containing a crack‐like surface defect. International journal of structural integrity, vol.2, no.3, 281-292.

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5. TAKAHASHI, Koji, HAYASHI, Takumi, ANDO, Kotoji, TAKAHASHI, Fumio. Evaluation of Acceptable Defect Size by Shot Peening Based on Fracture Mechanics. バネ論文集 = Transactions of Japan Society of Spring Engineers, vol.2010, no.55, 25-30.

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6. HOUJOU, Keiji, TAKAHASHI, Koji, ANDO, Kotoji, FUEKI, Ryutaro, OKADA, Hideki. Effect of Material Hardness on Crack Size Rendered Harmless by Shot Peening. 材料 = Journal of the Society of Materials Science, Japan, vol.64, no.11, 859-864.

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7. FUKUDA, Shinsaku, AMANO, Toshihiko, TAKAHASHI, Koji, MATSUI, Katsuyuki, ISHIGAMI, Hideyuki, ANDO, Kotoji. Increase in Fatigue Limit and Acceptable Size of Defect for Smooth and Notched Specimen by Cavitation Peening. バネ論文集 = Transactions of Japan Society of Spring Engineers, vol.2009, no.54, 1-6.

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8. 10.1111/ffe.13460 K. W. Nam, K. Ando, M. H. Kim and K. Takahashi, 2021, "Improving reliability of high-strength steel designed against fatigue limit using surface crack nondamaging technology by shot peening", Fatigue & Fracture of Engineering Materials & Structures, Online Version. 

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9. Y. Sano, M. Kimura, K. Sato, M. Obata, A. Sudo, Y. Hamamoto, S. Shima, Y. Ichikawa, H. Yamazaki, M. Naruse, S. Hida, T. Watanabe and Y. Oono, 2000, "Development and application of laser peening system to prevent stress corrosion cracking of reactor core shroud", Proc. of 8th Int. Conf. on Nuclear Engineering (ICONES), ICONE-8441, Baltimore. 

10. Kattoura, Micheal, Mannava, Seetha Ramaiah, Qian, Dong, Vasudevan, Vijay K.. Effect of laser shock peening on residual stress, microstructure and fatigue behavior of ATI 718Plus alloy. International journal of fatigue, vol.102, 121-134.

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11. Zhang, X.C., Zhang, Y.K., Lu, J.Z., Xuan, F.Z., Wang, Z.D., Tu, S.T.. Improvement of fatigue life of Ti–6Al–4V alloy by laser shock peening. Materials science & engineering. properties, microstructure and processing. A, Structural materials, vol.527, no.15, 3411-3415.

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12. Y. Sano, M. Kimura, M. Yoda, N. Mukai, K. Sato, T. Uehara, T. Ito, M. Shimamura, A. Sudo and N. Suezono, 2001, "Development of fiberdelivered laser peening system to prevent stress corrosion cracking of reactor components", International Conference on Nuclear Engineering (INIS-FR-647), Nice, France, pp. 8-12. 

13. Ohta, A., Suzuki, N., Maeda, Y.. Shift of S-N Curves with Stress Ratio. Welding in the world = Soudage dans le monde, vol.47, no.1, 19-24.

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14. Hasegawa, Kunio, Usami, Saburo. Effect of Stress Ratio on Fatigue Crack Growth Threshold for Austenitic Stainless Steels in Air Environment. Key engineering materials, vol.741, 88-93.

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15. ANDO, Kotoji, FUEKI, Ryutaro, NAM, Ki Woo, MATSUI, Katsuyuki, TAKAHASHI, Koji. A Study on the Unification of the Threshold Stress Intensity Factor for Micro Crack Growth. バネ論文集 = Transactions of Japan Society of Spring Engineers, vol.2019, no.64, 39-44.

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16. Hyun, Jae-Yong, Kim, Min-Heon, Nam, Ki-Woo. Crack Length Dependence of Threshold Stress Intensity Factor of Finite Plates with Semi-Elliptical Crack. 한국동력기계공학회지 = Journal of the korean society for power system engineering, vol.23, no.4, 14-21.

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17. Hyun, Jae-Yong, Kim, Min-Heon, Nam, Ki-Woo. Study of Threshold Stress Intensity Factor and Fatigue Limit for Short Crack Growth of HV470 Steel. 한국동력기계공학회지 = Journal of the korean society for power system engineering, vol.23, no.5, 5-12.

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18. Newman, J.C., Raju, I.S.. An empirical stress-intensity factor equation for the surface crack. Engineering fracture mechanics, vol.15, no.1, 185-192.

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19. TANGE, Akira, AKUTU, Tadayoshi, TAKAMURA, Noritoshi. Relation between shot-peening residual stress distribution and fatigue crack propagation life in spring steel. バネ論文集 = Transactions of Japan Society of Spring Engineers, vol.1991, no.36, 47-53.

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20. El Haddad, M.H., Topper, T.H., Smith, K.N.. Prediction of non propagating cracks. Engineering fracture mechanics, vol.11, no.3, 573-584.

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21. American Petroleum Institute. Recommended practice 579, Fitness for service, American Petroleum Institute, 2000: C3-C10.