Creep and Creep Fatigue Crack Behavior of 1Cr- and 9Cr-Steels
Karl Maile, Andreas Klenk, J. Granacher, G. Schellenberg, M. Tramer |
p85 |
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Creep Rupture Behavior of Advanced 9-12%Cr Steel Weldment
F. Masuyama, M. Matsui, N. Komai |
p99 |
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Creep Life Assessment of High Chromium Ferritic Steels by Recovery of Martensitic Lath Structure
K. Sawada, Kouichi Maruyama, Yuki Hasegawa, T. Muraki |
p109 |
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Creep Rupture Properties of Helium Implanted Low Activation Martensitic Steel for Nuclear Fusion Application
N. Yamamoto, J. Nagakawa, K. Shiba |
p115 |
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A Change in the Mechanism of Creep Crack Growth in a Dissimilar Metal Weld at 540 °C
B. Nath |
p121 |
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Mechanical Behavior and Strengthening Mechanism of W containing 9-12% Cr Steels under Creep Condition for a Cracked Specimen
A.Toshimitsu Yokobori, S. Takmori, T. Yokobori, Yuki Hasegawa, Kohei Kubota, K. Hidaka |
p131 |
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Creep Crack Growth in a High Strength Low Alloy Steel at 360 °C
R. Wu, F. Seitisleam, R. Sandström |
p139 |
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Creep Crack Growth in Nearly Fully-Lamellar Gamma TiAl Alloys
K.V. Jata, Yung Woo Kim |
p147 |
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Modelling of High Temperature Multi-Axial Creep Rupture Behaviour of γ-Titanium Aluminide
R. Dempers, Kamran M. Nikbin, G.A. Webster |
p153 |
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Effect of Fiber Orientation on Fatigue and Fracture Properties of Fiber Eutectic Al-Al3Ni Composite Alloy
Seishi Goto, S. Aso, Y. Komatsu |
p161 |
